Critical care medicine
Critical Care and CardiacMedicine
Current Clinical Strategies
Matthew Brenner, MD
Associate Professor of Medicine
Pulmonary and Critical Care Division
University of California, Irvine
Copyright 2007 Current Clinical Strategies Publishing. Allrights reserved. This book, or any parts thereof, may not bereproduced or stored in an information retrieval network orinternet without the written permission of the publisher. Thereader is advised to consult the drug package insert andother references before using any therapeutic agent. Noliability exists, expressed or implied, for errors or omissionsin this text.
ISBN 1-929622-72-4 Critical and Cardiac Care
Patient Management
T. Scott Gallacher, MD, MS Critical Care History and Physical
Examination
Chief complaint: Reason for admission to the ICU.
History of present illness: This section should included
pertinent chronological events leading up to the hospi-talization. It should include events during hospitalizationand eventual admission to the ICU. Prior cardiac history: Angina (stable, unstable, changes
in frequency), exacerbating factors (exertional, restangina). History of myocardial infarction, heart failure,coronary artery bypass graft surgery, angioplasty.
Previous exercise treadmill testing, ECHO, ejectionfraction. Request old ECG, ECHO, impedance cardiog-raphy, stress test results, and angiographic studies.
Chest pain characteristics:
A. Pain: Quality of pain, pressure, squeezing, tightness
B. Onset of pain: Exertional, awakening from sleep,
relationship to activities of daily living (ADLs), suchas eating, walking, bathing, and grooming.
C. Severity and quality: Pressure, tightness, sharp,
D. Radiation: Arm, jaw, shoulder
E. Associated symptoms: Diaphoresis, dyspnea,
back pain, GI symptoms.
F. Duration: Minutes, hours, days.
G. Relieving factors: Nitroclycerine, rest.
Cardiac risk factors: Age, male, diabetes,
hypercholesteremia, low HDL, hypertension, smoking,previous coronary artery disease, family history ofarteriosclerosis (eg, myocardial infarction in males lessthan 50 years old, stroke).
Congestive heart failure symptoms: Orthopnea (number
of pillows), paroxysmal nocturnal dyspnea, dyspnea onexertional, edema.
Peripheral vascular disease symptoms: Claudication,
transient ischemic attack, cerebral vascular accident.
COPD exacerbation symptoms: Shortness of breath,
fever, chills, wheezing, sputum production, hemoptysis(quantify), corticosteroid use, previous intubation.
Past medical history: Peptic ulcer disease, renal disease,
diabetes, COPD. Functional status prior to hospitaliza-tion.
Medications: Dose and frequency. Use of nitroglycerine,
Allergies: Penicillin, contrast dye, aspirin; describe the
specific reaction (eg, anaphylaxis, wheezing, rash,hypotension).
Social history: Tobacco use, alcohol consumption,
intravenous drug use.
Review of systems: Review symptoms related to each
organ system.
Critical Care Physical Examination
Vital signs:
Temperature, pulse, respiratory rate, BP (vital signs
should be given in ranges)
Input/Output: IV fluid volume/urine output.
Special parameters: Oxygen saturation, pulmonary
artery wedge pressure (PAWP), systemic vascular
resistance (SVR), ventilator settings, impedance cardi-
ography.
General: Mental status, Glasgow coma score, degree of
distress.
HEENT: PERRLA, EOMI, carotid pulse.
Lungs: Inspection, percussion, auscultation for wheezes,
crackles.
Cardiac: Lateral displacement of point of maximal impulse;
irregular rate,, irregular rhythm (atrial fibrillation); S3 gallop
(LV dilation), S4 (myocardial infarction), holosystolic apex
murmur (mitral regurgitation).
Cardiac murmurs: 1/6 = faint; 2/6 = clear; 3/6 - loud; 4/6 =
palpable; 5/6 = heard with stethoscope off the chest; 6/6 =
heard without stethoscope.
Abdomen: Bowel sounds normoactive, abdomen soft and
nontender.
Extremities: Cyanosis, clubbing, edema, peripheral pulses
2+.
Skin: Capillary refill, skin turgor.
Neuro
Deficits in strength, sensation.
Deep tendon reflexes: 0 = absent; 1 = diminished; 2 = normal; 3 = brisk; 4 = hyperactive clonus.
Motor Strength: 0 = no contractility; 1 = contractility but no joint motion; 2 = motion without gravity; 3 = motion against gravity; 4 = motion against someresistance; 5 = motion against full resistance (nor-mal).
Labs: CBC, INR/PTT; chem 7, chem 12, Mg, pH/pCO /pO .
CXR, ECG, impedance cardiography, other diagnosticstudies.
Impression/Problem list: Discuss diagnosis and plan for
each problem by system.
Neurologic Problems: List and discuss neurologic prob-
lems
Pulmonary Problems: Ventilator management.
Cardiac Problems: Arrhythmia, chest pain, angina.
GI Problems: H2 blockers, nasogastric tubes, nutrition.
Genitourinary Problems: Fluid status: IV fluids, electrolyte
therapy.
Renal Problems: Check BUN, creatinine. Monitor fluids
and electrolytes. Monitor inputs and outputs.
Hematologic Problems: Blood or blood products, DVT
prophylaxis, check hematocrit/hemoglobin.
Infectious Disease: Plans for antibiotic therapy; antibiotic
day number, culture results.
Endocrine/Nutrition: Serum glucose control, parenteral or
enteral nutrition, diet.
Admission Check List
1. Call and request old chart, ECG, and x-rays.
2. Stat labs: CBC, chem 7, cardiac enzymes (myoglobin,
troponin, CPK), INR, PTT, C&S, ABG, UA, cardiacenzymes (myoglobin, troponin, CPK).
3. Labs: Toxicology screens and drug levels.
4. Cultures: Blood culture x 2, urine and sputum culture
(before initiating antibiotics), sputum Gram stain, urinaly-sis. . . . . . . . .
5. CXR, ECG, diagnostic studies.
6. Discuss case with resident, attending, and family.
Critical Care Progress Note
ICU Day Number:
Antibiotic Day Number:
Subjective: Patient is awake and alert. Note any events
that occurred overnight.
Objective: Temperature, maximum temperature, pulse,
respiratory rate, BP, 24- hr input and output, pulmonary
artery pressure, pulmonary capillary wedge pressure,
cardiac output.
Lungs: Clear bilaterally
Cardiac: Regular rate and rhythm, no murmur, no rubs.
Abdomen: Bowel sounds normoactive, soft-nontender.
Neuro: No local deficits in strength, sensation.
Extremities: No cyanosis, clubbing, edema, peripheral
pulses 2+.
Labs: CBC, ABG, chem 7.
ECG:
Chest x-ray:
Impression and Plan: Give an overall impression, and
then discuss impression and plan by organ system:
A procedure note should be written in the chart when aprocedure is performed. Procedure notes are brief operativenotes.
Date and time:
Procedure:
Indications:
Patient Consent: Document that the indications,
risks and alternatives to the procedure were ex-
plained to the patient. Note that the patient was given
the opportunity to ask questions and that the patient
consented to the procedure in writing.
Lab tests: Relevant labs, such as the INR and CBC
Anesthesia: Local with 2% lidocaine
Description of Procedure: Briefly describe the pro-
cedure, including sterile prep, anesthesia method,
patient position, devices used, anatomic location of
procedure, and outcome.
Complications and Estimated Blood Loss (EBL):
Disposition: Describe how the patient tolerated the
Specimens: Describe any specimens obtained and
labs tests which were ordered.
Name of Physician: Name of person performing
procedure and supervising staff.
The discharge note should be written in the patient's chartprior to discharge.
Date/time:
Diagnoses:
Treatment: Briefly describe treatment provided dur-
ing hospitalization, including surgical procedures and
antibiotic therapy.
Studies Performed: Electrocardiograms, CT scans,
CXR.
Discharge Medications:
Follow-up Arrangements:
Fluids and Electrolytes
Maintenance Fluids Guidelines:
70 kg Adult: D5 1/4 NS with KCI 20 mEq/Liter at 125
mL/hr.
Specific Replacement Fluids for Specific Losses:
Gastric (nasogastric tube, emesis): D5 1/2 NS with
KCL 20 mEq/L.
Diarrhea: D5LR with KCI 15 mEq/liter. Provide 1 liter
of replacement for each 1 kg or 2.2 lb of body weight
lost.
Bile: D5LR with sodium bicarbonate 25 mEq/liter (1/2
amp).
Pancreatic: D5LR with sodium bicarbonate 50
mEq/liter (1 amp).
Blood Component Therapy
A. Packed red blood cells (PRBCs). Each unit pro-
vides 250-400 cc of volume, and each unit shouldraise hemoglobin by 1 gm/dL and hematocrit by 3%.
PRBCs are usually requested in two unit increments.
B. Type and screen. Blood is tested for A, B, Rh
antigens, and antibodies to donor erythrocytes. Ifblood products are required, the blood can be rapidlyprepared by the blood bank. O negative blood isused when type and screen information is not avail-able, but the need for transfusion is emergent.
C. Type and cross match sets aside specific units of
packed donor red blood cells. If blood is needed onan urgent basis, type and cross should be requested.
D. Platelets. Indicated for bleeding if there is
thrombocytopenia or platelet dysfunction in thesetting of uncontrolled bleeding. Each unit of plateletconcentrate should raise the platelet count by 5,000-10,000. Platelets are usually transfused 6-10 units ata time, which should increase the platelet count by40-60,000. Thrombocytopenia is defined as a plateletcount of less than 60,000. For surgery, the countshould be greater than 50,000.
E. Fresh Frozen Plasma (FFP) is used for active
bleeding secondary to liver disease, warfarin over- dose, dilutional coagulopathy secondary to multiple
blood transfusions, disseminated intravascular
coagulopathy, and vitamin K and coagulation factor
deficiencies. Administration of FFP requires ABO
typing, but not cross matching.
1. Each unit contains coagulation factors in normal
2. Two to four units are usually required for thera-
1. Indicated in patients with Hemophilia A, Von
Willebrand's disease, and any state ofhypofibrinogenemia requiring replacement (DIC),or reversal of thrombolytic therapy.
2. Cryoprecipitate contains factor VIII, fibrinogen,
and Von Willebrand factor. The goal of therapy isto maintain the fibrinogen level above 100 mL/dL,which is usually achieved with 10 units given over3-5 minutes.
Central Parenteral Nutrition
Infuse 40-50 mL/hr of amino acid dextrose solution in the
first 24 hr; increase daily by 40 mL/hr increments until
providing 1.3-2 x basal energy requirement and 1.2-1.7 gm
protein/kg/d (see formula, page 169)
Standard Solution per Liter
Amino acid solution (Aminosyn) 7-10% 500 mLDextrose 40-70% Multi-Trace Element Formula Regular insulin (if indicated) Multivitamin 12 (2 amp) Vitamin K (in solution, SQ, IM) -Intralipid 20% 500 mL/d IVPB infused in parallel with standard solution at 1 mL/min x 15 min; if no ad-verse reactions, increase to 20-50 mL/hr. Serumtriglyceride level should be checked 6h after end ofinfusion (maintain <250 mg/dL).
Cyclic Total Parenteral Nutrition
-12-hour night schedule; taper continuous infusion in morning by reducing rate to half original rate for 1hour. Further reduce rate by half for an additionalhour, then discontinue. Restart TPN in evening.
Taper at beginning and end of cycle. Final rateshould be 185 mL/hr for 9-10h with 2 hours of taperat each end, for total of 2000 mL.
Peripheral Parenteral Supplementation
-Amino acid solution (ProCalamine) 3% up to 3 L/d at -Combine 500 mL amino acid solution 7% or 10% (Aminosyn) and 500 mL 20% dextrose andelectrolyte additive. Infuse at up to 100 cc/hr inparallel with intralipid 10% or 20% at 1 mL/min for15 min (test dose); if no adverse reactions, infuse500 mL/d at 20 mL/hr.
-Famotidine (Pepcid) 20 mg IV q12h or 40 mg/day in -Ranitidine (Zantac) 50 mg IV q6-8h.
-Insulin sliding scale or continuous IV infusion.
Baseline: Draw labs below. Chest x-ray, plain film for
Daily Labs: Chem 7, osmolality, CBC, cholesterol,
triglyceride (6h after end of infusion), serumphosphate, magnesium, calcium, urine specificgravity.
Weekly Labs: Protein, iron, TIBC, INR/PTT, 24h urine
nitrogen and creatinine. Pre-albumin, transferrin,albumin, total protein, AST, ALT, GGT, alkalinephosphatase, LDH, amylase, total bilirubin.
General Measures: Daily weights, nasoduodenal feeding
tube. Head of bed at 30 degrees while enteral feeding and
2 hours after completion. Record bowel movements.
Continuous Enteral Infusion: Initial enteral solution
(Osmolite, Pulmocare, Jevity) 30 mL/hr. Measureresidual volume q1h x 12h, then tid; hold feeding for 1 hif residual is more than 100 mL of residual. Increase rateby 25-50 mL/hr at 24 hr intervals as tolerated until finalrate of 50-100 mL/hr (1 cal/mL) as tolerated. Three tablespoons of protein powder (Promix) may be addedto each 500 cc of solution. Flush tube with 100 cc waterq8h.
Enteral Bolus Feeding: Give 50-100 mL of enteral
solution (Osmolite, Pulmocare, Jevity) q3h initially.
Increase amount in 50 mL steps to max of 250-300 mLq3-4h; 30 kcal of nonprotein calories/d and 1.5 gmprotein/kg/d. Before each feeding measure residualvolume, and delay feeding by 1 h if >100 mL. Flush tubewith 100 cc of water after each bolus.
-Metoclopramide (Reglan) 10-20 mg PO, IM, IV, or in J -Famotidine (Pepcid) 20 mg J-tube q12h OR
-Ranitidine (Zantac) 150 mg in J-tube bid.
-Loperamide (Imodium) 24 mg PO or in J-tube q6h, max 16 mg/d prn OR
-Diphenoxylate/atropine (Lomotil) 5-10 mL (2.5 mg/5 mL) PO or in J-tube q4-6h, max 12 tabs/d OR
-Kaopectate 30 cc PO or in J-tube q6h.
Radiographic Evaluation of Common
Interventions
I. Central intravenous lines
A. Central venous catheters should be located well
above the right atrium, and not in a neck vein. Ruleout pneumothorax by checking that the lung mark-ings extend completely to the rib cages on bothsides. Examine for hydropericardium ("water bottle"sign, mediastinal widening).
B. Pulmonary artery catheter tips should be located
centrally and posteriorly, and not more than 3-5 cmfrom midline.
II. Endotracheal tubes. Verify that the tube is located 3
cm below the vocal cords and 2-4cm above the carina;the tip of tube should be at the level of aortic arch.
III. Tracheostomies. Verify by chest x-ray that the tube is
located halfway between the stoma and the carina; thetube should be parallel to the long axis of the trachea.
The tube should be approximately 2/3 of width of thetrachea; the cuff should not cause bulging of the tracheawalls. Check for subcutaneous air in the neck tissue andfor mediastinal widening secondary to air leakage.
IV. Nasogastric tubes and feeding tubes. Verify that the
tube is in the stomach and not coiled in the esophagusor trachea. The tip of the tube should not be near thegastroesophageal junction.
V. Chest tubes. A chest tube for pneumothorax drainage
should be near the level of the third intercostal space. Ifthe tube is intended to drain a free-flowing pleuraleffusion, it should be located inferior-posteriorly, at orabout the level of the eighth intercostal space. Verifythat the side port of the tube is within the thorax.
VI. Mechanical ventilation. Obtain a chest x-ray to rule out
pneumothorax, subcutaneous emphysema,pneumomediastinum, or subpleural air cysts. Lunginfiltrates or atelectasis may diminish or disappear afterinitiation of mechanical ventilation because of increasedaeration of the affected lung lobe.
Arterial Line Placement
Procedure
1. Obtain a 20-gauge 1 1/2-2 inch catheter over needle
assembly (Angiocath), arterial line setup (transducer,tubing and pressure bag containing heparinized saline),arm board, sterile dressing, lidocaine, 3 cc syringe, 25-gauge needle, and 3-O silk suture.
2. The radial artery is the most frequently used artery. Use the Allen test to verify the patency of the radial andulnar arteries. Place the extremity on an arm board witha gauze roll behind the wrist to maintainhyperextension.
3. Prep the skin with povidone-iodine and drape; infiltrate 1% lidocaine using a 25-gauge needle. Choose a sitewhere the artery is most superficial and distal.
4. Palpate the artery with the left hand, and advance the catheter-over-needle assembly into the artery at a 30-degree angle to the skin. When a flash of blood is seen,hold the needle in place and advance the catheter intothe artery. Occlude the artery with manual pressurewhile the pressure tubing is connected.
5. Advance the guide wire into the artery, and pass the catheter over the guide wire. Suture the catheter inplace with 3-0 silk and apply dressing.
Central Venous Catheterization
I. Indications for central venous catheter cannulation:
Monitoring of central venous pressures in shock or heartfailure; management of fluid status; insertion of atransvenous pacemaker; administration of totalparenteral nutrition; administration of vesicants(chemotherapeutic agents).
II. Location: The internal jugular approach is relatively
contraindicated in patients with a carotid bruit, stenosis,or an aneurysm. The subclavian approach has anincreased risk of pneumothorax in patients with emphy-sema or bullae. The external jugular or internal jugularapproach is preferable in patients with coagulopathy orthrombocytopenia because of the ease of externalcompression. In patients with unilateral lung pathologyor a chest tube already in place, the catheter should beplaced on the side of predominant pathology or on theside with the chest tube if present. III. Technique for insertion of external jugular vein
catheter
1. The external jugular vein extends from the angle of
the mandible to behind the middle of the clavicle,where it joins with the subclavian vein. Place thepatient in Trendelenburg's position. Cleanse skin withBetadine-iodine solution, and, using sterile tech-nique, inject 1% lidocaine to produce a skin weal.
Apply digital pressure to the external jugular veinabove the clavicle to distend the vein.
2. With a 16-gauge thin wall needle, advance the needle into the vein. Then pass a J-guide wirethrough the needle; the wire should advance withoutresistance. Remove the needle, maintaining controlover the guide wire at all times. Nick the skin with aNo. 11 scalpel blade.
3. With the guide wire in place, pass the central cathe- ter over the wire and remove the guide wire after thecatheter is in place. Cover the catheter hub with afinger to prevent air embolization.
4. Attach a syringe to the catheter hub and ensure that there is free back-flow of dark venous blood. Attachthe catheter to an intravenous infusion.
5. Secure the catheter in place with 2-0 silk suture and tape. The catheter should be replaced weekly or ifthere is any sign of infection.
6. Obtain a chest x-ray to confirm position and rule out IV.Internal jugular vein cannulation. The internal jugular
vein is positioned behind the stemocleidomastoidmuscle lateral to the carotid artery. The catheter shouldbe placed at a location at the upper confluence of thetwo bellies of the stemocleidomastoid, at the level of thecricoid cartilage.
1. Place the patient in Trendelenburg's position and turn the patient's head to the contralateral side.
2. Choose a location on the right or left. If lung function is symmetrical and no chest tubes are in place, theright side is preferred because of the direct path tothe superior vena cava. Prepare the skin withBetadine solution using sterile technique and placea drape. Infiltrate the skin and deeper tissues with 1%lidocaine.
3. Palpate the carotid artery. Using a 22-gauge scout needle and syringe, direct the needle lateral to thecarotid artery towards the ipsilateral nipple at a 30-degree angle to the neck. While aspirating, advancethe needle until the vein is located and blood flowsback into the syringe.
4. Remove the scout needle and advance a 16-gauge, thin wall catheter-over-needle with an attachedsyringe along the same path as the scout needle.
When back flow of blood is noted into the syringe,advance the catheter into the vein. Remove theneedle and confirm back flow of blood through thecatheter and into the syringe. Remove the syringe,and use a finger to cover the catheter hub to preventair embolization.
5. With the 16-gauge catheter in position, advance a 0.89 mm x 45 cm spring guide wire through thecatheter. The guidewire should advance easilywithout resistance.
6. With the guidewire in position, remove the catheter and use a No. 11 scalpel blade to nick the skin.
7. Place the central vein catheter over the wire, holding the wire secure at all times. Pass the catheter into thevein, remove the guidewire, and suture the catheterwith 0 silk suture, tape, and connect it to an IV infu-sion.
8. Obtain a chest x-ray to rule out pneumothorax and confirm position of the catheter.
V. Subclavian vein cannulation. The subclavian vein is
located in the angle formed by the medial a of theclavicle and the first rib.
1. Position the patient supine with a rolled towel located between the patient's scapulae, and turn the patient'shead towards the contralateral side. Prepare the areawith Betadine iodine solution, and, using sterile technique, drape the area and infiltrate 1% lidocaineinto the skin and tissues.
2. Advance the 16-gauge catheter-over-needle, with syringe attached, into a location inferior to the mid-point of the clavicle, until the clavicle bone andneedle come in contact.
3. Slowly probe down with the needle until the needle slips under the clavicle, and advance it slowly to-wards the vein until the catheter needle enters thevein and a back flow of venous blood enters thesyringe. Remove the syringe, and cover the catheterhub with a finger to prevent air embolization.
4. With the 16-gauge catheter in position, advance a 0.89 mm x 45 cm spring guide wire through thecatheter. The guide wire should advance easilywithout resistance.
5. With the guide wire in position, remove the catheter, and use a No. 11 scalpel blade to nick the skin.
6. Place the central line catheter over the wire, holding the wire secure at all times. Pass the catheter intothe vein, and suture the catheter with 2-0 silk suture,tape, and connect to an IV infusion.
7. Obtain a chest x-ray to confirm position and rule out VI.Pulmonary artery catheterization procedure
A. Using sterile technique, cannulate a vein using the
technique above. The subclavian vein or internaljugular vein is commonly used.
B. Advance a guide wire through the cannula, then
remove the cannula, but leave the guide wire inplace. Keep the guide wire under control at all times.
Nick the skin with a number 11 scalpel blade adja-cent to the guide wire, and pass a number 8 Frenchintroducer over the wire into the vein. Remove thewire and connect the introducer to an IV fluid infu-sion, and suture with 2-0 silk.
C. Pass the proximal end of the pulmonary artery
catheter (Swan Ganz) to an assistant for connectionto a continuous flush transducer system.
D. Flush the distal and proximal ports with heparin
solution, remove all bubbles, and check balloonintegrity by inflating 2 cc of air. Check the pressuretransducer by quickly moving the distal tip andwatching the monitor for response.
E. Pass the catheter through the introducer into the
vein, then inflate the balloon with 1.0 cc of air, andadvance the catheter until the balloon is in or nearthe right atrium.
F. The approximate distance to the entrance of the right
atrium is determined from the site of insertion: Right internal jugular vein: 10-15 cm.
Subclavian vein: 10 cm.
Femoral vein: 35.45 cm.
G. Advance the inflated balloon, while monitoring
pressures and wave forms as the PA catheter isadvanced. Advance the catheter through the rightventricle into the main pulmonary artery until thecatheter enters a distal branch of the pulmonaryartery and is stopped (as evidenced by a pulmonarywedge pressure waveform).
H. Do not advance the catheter while the balloon is
deflated, and do not withdraw the catheter with theballoon inflated. After placement, obtain a chest X-ray to ensure that the tip of catheter is no farther than3-5 cm from the mid-line, and no pneumothorax ispresent.
Normal Pulmonary Artery Catheter
Values
Right atrial pressure Pulmonary artery pressure Roham T. Zamanian, MDFarhad Mazdisnian, MDMichael Krutzik, MD Acute Coronary Syndromes (ST-
Segment Elevation MI, Non-ST-Seg-
ment Elevation MI, and Unstable
Angina)
Acute myocardial infarction (AMI) and unstable angina arepart of a spectrum known as the acute coronary syndromes(ACS), which have in common a ruptured atheromatousplaque. Plaque rupture results in platelet activation,adhesion, and aggregation, leading to partial or totalocclusion of the artery. These syndromes include ST-segment elevation MI, non-ST-segment elevation MI, and unstable angina. TheECG presentation of ACS includes ST-segment elevationinfarction, ST-segment depression (including non–Q-waveMI and unstable angina), and nondiagnostic ST-segmentand T-wave abnormalities. Patients with ST-segmentelevation MI require immediate reperfusion, mechanicallyor pharmacologically. The clinical presentation of myocar-dial ischemia is most often acute chest pain or discomfort.
I. Characteristics of chest pain and associated symp-
toms
A. Ischemic chest pain can be characterized by the the
OPQRST mnemonic. Symptoms associated with the
highest relative risk of myocardial infarction (MI)
include radiation to an upper extremity, particularly
when there is radiation to both arms, and pain associ-
ated with diaphoresis or with nausea and vomiting.
The patient should be asked if current pain is reminis-
cent of prior MI.
1. Onset. Ischemic pain is typically gradual in onset,
although the intensity of the discomfort may waxand wane.
2. Provocation and palliation. Ischemic pain is
generally provoked by an activity. Ischemic paindoes not change with respiration or position. It mayor may not respond to nitroglycerin.
3. Quality. Ischemic pain is often characterized more
as a discomfort than pain, and it may be difficult todescribe. The patient may describe the pain assqueezing, tightness, pressure, constriction, crush-ing, strangling, burning, heartburn, fullness in thechest, band-like sensation, knot in the center of thechest, lump in throat, ache, heavy weight on chest.
It is usually not described as sharp, fleeting, knife-like, stabbing, or pins and needles-like. The patientmay place his clenched fist in the center of thechest, which is known as the "Levine sign." 4. Radiation. Ischemic pain often radiates to other
parts of the body including the upper abdomen(epigastrium), shoulders, arms (upper and forearm),wrist, fingers, neck and throat, lower jaw and teeth(but not upper jaw), and not infrequently to the back(specifically the interscapular region). Pain radiatingto the upper extremities is highly suggestive ofischemic pain.
5. Site. Ischemic pain is not felt in one specific spot,
but rather it is a diffuse discomfort that may bedifficult to localize. The patient often indicates theentire chest, rather than localizing it to a specificarea by pointing a single finger.
6. Time course. Angina is usually brief (two to five
minutes) and is relieved by rest or with nitroglycerin.
In comparison, patients with an acute coronarysyndrome (ACS) may have chest pain at rest, andthe duration is variable but generally lasts longerthan 30 minutes. Classic anginal pain lasting morethan 20 minutes is particularly suggestive of anACS.
7. Associated symptoms. Ischemic pain is often
associated with is shortness of breath, which mayreflect pulmonary congestion. Other symptoms mayinclude belching, nausea, indigestion, vomiting,diaphoresis, dizziness, lightheadedness, clammi-ness, and fatigue. Elderly women and diabetics aremore likely to present with such "atypical" symp-toms in lieu of classic chest pain.
B. Characteristics of nonischemic chest discomfort:
1. Pleuritic pain, sharp or knife-like pain related to
respiratory movements or cough.
2. Primary or sole location in the mid or lower abdomi-
3. Any discomfort localized with one finger.
4. Any discomfort reproduced by movement or palpa-
5. Constant pain lasting for days.
6. Fleeting pains lasting for a few seconds or less.
7. Pain radiating into the lower extremities or above
the mandible.
C. Some patients with ACS present with atypical types of
chest pain. Acute ischemia is diagnosed in 22 percentof patients who present with sharp or stabbing painand 13 percent who presented with pleuritic-type pain.
D. Atypical symptoms. Some patients with acute
coronary syndrome (ACS) present with atypicalsymptoms rather than chest pain. One-third have nochest pain on presentation to the hospital. Thesepatients often present with symptoms such asdyspnea alone, nausea and/or vomiting, palpitations,syncope, or cardiac arrest. They are more likely to beolder, diabetic, and women.
E. Additional history and exam
1. Historical features increasing likelihood of ACS
a. Patients with a prior history of coronary heart
disease (CHD) have a significantly increased riskof recurrent ischemic events.
b. A prior history of other vascular disease is asso-
ciated with a risk of cardiac ischemic eventscomparable to that seen with a prior history ofCHD.
c. Risk factors for CHD, including especially age,
sex, diabetes, hypertension, hyperlipidemia, andcigarette smoking.
d. Recent cocaine use.
2. Focused physical exam
a. Responsiveness, airway, breathing and circula-
b. Evidence of systemic hypoperfusion
(hypotension; tachycardia; impaired cognition;cool, clammy, pale, ashen skin). Cardiogenicshock complicating acute MI requires aggressiveevaluation and management.
c. Ventricular arrhythmias. Sustained ventricular
tachyarrhythmias in the periinfarction periodmust be treated immediately because of theirdeleterious effect on cardiac output, possibleexacerbation of myocardial ischemia, and therisk of deterioration into VF.
d. Evidence of heart failure (jugular venous disten-
tion, rales, S3 gallop, hypotension, tachycardia).
e. A screening neurologic examination should be
performed to assess for focal lesions or cognitivedeficits that might preclude safe use of thrombo-lytic therapy.
Differential diagnosis of severe or prolonged
chest pain
Myocardial infarctionUnstable anginaAortic dissectionGastrointestinal disease (esophagitis, esophageal spasm,peptic ulcer disease, biliary colic, pancreatitis)PericarditisChest-wal pain (musculoskeletal or neurologic)Pulmonary disease (pulmonary embolism, pneumonia, pleu-risy, pneumothorax)Psychogenic hyperventilation syndrome f. Exam findings increasing likelihood of MI.
Findings on physical examination associatedwith significantly increased risk of myocardialinfarction are hypotension (systolic bloodpressure <80) and signs of pump failure (ie,new or worsening pulmonary crackles, new S3,new or worsening MR murmur).
A. During the initial assessment phase, the following
steps should be accomplished for any patient with
significant risk of ACS:
1. Airway, breathing, and circulation assessed
2. 12-lead ECG obtained
3. Resuscitation equipment brought nearby
4. Cardiac monitor attached
5. Oxygen given
6. IV access and blood work obtained
7. Aspirin 162 to 325 mg given
8. Nitrates and morphine given (unless contraindi-
B. Twelve-lead ECG should be obtained in all patients
with possible coronary ischemia. The 12-lead ECGprovides the basis for initial diagnosis and manage-ment. The initial ECG is often not diagnostic inpatients with ACS. The ECG should be repeated at 5to 10 minute intervals, if the initial ECG is not diag-nostic but the patient remains symptomatic and thereis a high clinical suspicion for MI.
C. Cardiac monitoring should be initiated with emer-
gency resuscitation equipment (including adefibrillator and airway equipment) nearby.
D. Supplemental oxygen should be initiated to main-
tain oxygen saturation above 90 percent.
E. Intravenous access should be established, with
blood drawn for initial laboratory work, includingcardiac biomarkers.
F. Aspirin should be given to all patients at a dose of
162 to 325 mg to chew and swallow, unless there isa compelling contraindication (eg, history ofanaphylactic reaction) or it has been taken prior topresentation.
G. Sublingual nitroglycerin should be administered at
a dose of 0.4 mg every five minutes for a total of
three doses, after which an assessment should be
made about the need for intravenous nitroglycerin.
Before this is done, all men should be questioned
about the use of sildenafil (Viagra), vardenafil
(Levitra), or tadalafil (Cialis); nitrates are contraindi-
cated if these drugs have been used in the last 24
hours (36 hours with tadalafil) because of the risk of
severe hypotension.
1. Extreme care should also be taken before giving
nitrates in the setting of an inferior myocardialinfarction with possible involvement of the rightventricle. Nitrate use can cause severehypotension in this setting.
H. Intravenous morphine sulfate at an initial dose of
2 to 4 mg, with increments of 2 to 8 mg, repeated at5 to 15 minute intervals, should be given for the reliefof chest pain and anxiety.
ECG-based management of the Four major
ischemic syndromes
A. ST elevation (Q wave) MI is manifested by Q waves
that are usually preceded by hyperacute T wavesand ST elevations, and followed by T wave inver-sions. Clinically significant ST segment elevation isconsidered to be present if it is greater than 1 mm(0.1 mV) in at least two anatomically contiguousleads.
B. Non-ST elevation (Non-Q wave) MI is manifested by
ST depressions or T-wave inversions without Qwaves.
C. Noninfarction subendocardial ischemia (classic
angina), manifested by transient ST segment depres-sions.
D. Noninfarction transmural ischemia (Prinzmetal's
variant angina) is manifested by transient ST seg-ment elevations or paradoxical T wave normalization.
E. Localization of ischemia. The anatomic location of
a transmural infarct is determined by which ECG
leads show ST elevation and/or increased T wave
positivity:
1. Acute transmural anterior wall ischemia - one or
more of the precordial leads (V1-V6) 2. Anteroseptal ischemia - leads V1 to V3
3. Apical or lateral ischemia - leads aVL and I, and
4. Inferior wall ischemia - leads II, III, and aVF
5. Right ventricular ischemia - right-sided precordial
F. The right-sided leads V4R, V5R, and V6R should be
obtained if there is evidence of inferior wall ischemia,demonstrated by ST elevation in leads II, III, andaVF. The posterior leads V7, V8, and V9 may also behelpful if there is evidence of posterior wall ischemia,as suggested by prominent R waves and ST depres-sions in leads V1 and V2.
G. Serial ECGs. The initial ECG is often not diagnostic
in patients with ACS. Therefore, if the initial ECG isnot diagnostic, but the patient remains symptomaticand there is a high clinical suspicion for MI, it isrecommended that the ECG be repeated at 5 to 10minute intervals.
H. LBBB or pacing. Both LBBB, which is present in 7
percent of patients with an acute MI, and pacing caninterfere with the electrocardiographic diagnosis ofcoronary ischemia. Careful evaluation of the ECGmay show some evidence of ACS in patients withthese abnormalities. The clinical history and cardiacenzymes are of primary importance in diagnosing anACS in this setting.
ST elevation. Regardless of the presence or ab-
sence of Q waves, an ST elevation MI (STEMI) is
diagnosed in the following circumstances:
1. ST segment elevation >1 mm is present in two or
more anatomically contiguous leads.
2. The elevations are considered to represent
ischemia and not pericarditis or left ventricularaneurysm.
J. The patient should also be presumed to have an
acute STEMI if the ECG shows a left bundle branchblock that is not known to be old and the clinicalsuspicion for an ACS is high.
K. Reperfusion therapy. A patient with an acute STEMI
should undergo reperfusion therapy with eitherprimary percutaneous intervention (PCI) orthrombolysis, if less than 12 hours has elapsed fromthe onset of symptoms. Benefit from thrombolysis issignificantly greater when given within four hours ofthe onset of symptoms. Primary PCI is preferred tothrombolysis when readily available.
L. Antiplatelet therapy is indicated in all patients with
STEMI, regardless of whether they undergo
reperfusion therapy, unless an absolute contraindica-
tion exists.
1. Aspirin is the preferred antiplatelet agent and
should be given in a dose of 162 to 325 mg tochew and swallow as soon as possible to anypatient with STEMI.
2. Clopidogrel (Plavix) is recommended in all pa-
tients treated with primary PCI and stenting. A 600mg loading dose should begin in these patients,and primary PCI should be done within 90 min-utes. Benefit from the use of clopidogrel in addi-tion to aspirin has also been demonstrated inpatients under 75 years of age undergoingthrombolysis. Patients over 75 years of age gener-ally receive 75 mg because of the increased riskof hemorrhage.
3. Clopidogrel (300 mg loading dose followed by 75
mg once daily) is given to patients who are man-aged without reperfusion therapy in this settingbased upon the benefit demonstrated innonrevascularized patients with non-ST elevationsyndromes.
4. Clopidogrel can also be given in the rare case
where aspirin is contraindicated.
M. Glycoprotein IIb/IIIa inhibitors. Treatment with
abciximab should be started as early as possibleprior to PCI, with or without stent, in patients withSTEMI.
N. Beta blockers should be administered to all patients
with ST elevation MI without contraindications. Early
intravenous use of a cardioselective agent, such as
metoprolol or atenolol, is recommended:
1. Intravenous metoprolol can be given in 5 mg
increments by slow intravenous administration (5mg over one to two minutes), repeated every fiveminutes for a total initial dose of 15 mg. Patientswho tolerate this regimen should then receive oraltherapy beginning 15 minutes after the last intra-venous dose (25 to 50 mg every six hours for 48hours) followed by a maintenance dose of 100 mgtwice daily.
2. Intravenous atenolol can be given in a 5 mg dose,
followed by another 5 mg, five minutes later.
Patients who tolerate this regimen should thenreceive oral therapy beginning one to two hoursafter the last intravenous dose (50 to 100 mg/day).
3. Esmolol (Brevibloc) (50 mcg/kg per min increasing
to a maximum of 200 to 300 mcg/kg per min) canbe used if an ultrashort acting beta blocker isrequired.
O. Intravenous nitroglycerin can be given for treat-
ment of persistent pain, congestive heart failure, orhypertension, provided there are no contraindications(eg, use of drugs for erectile dysfunction or rightventricular infarction). The goal of therapy is a 10percent reduction in the systolic blood pressure or a30 percent reduction in hypertensive patients.
Therapy for Non-ST Segment Myocardial Infarc-
tion and Unstable Angina
Aspirin, 325 mg (chewable) Sublingual nitroglycerin (Nitrostat), onetablet every 5 min for total of threetablets initially, fol owed by IVform (Nitro-BidIV, Tridil) ifneeded C IV therapy recommended for prompt response, fol owed by oral therapy.
C Metoprolol (Lopressor), 5 mg IV every 5 min for three doses C Atenolol (Tenormin) 5 mg IV q5min x 2 C Esmolol (Brevibloc), initial IV dose of 50 micrograms/kg/min and adjust up to200-300 micrograms/kg/min 80 U/kg IVP, fol owed by 15 U/kg/hr. Goal: 1 mg/kg IV, fol owed by 1 mg/kg subcuta- Eptifibatide (Integrilin) or tirofiban (Aggrastat) for patients with high-risk fea- tures in whom an early invasive approach Consider clopidogrel (Plavix) therapy, 300 mg x 1, then 75 mg qd.
Consideration of early invasive approach intermediate to high risk and those in whom conservative management hasfailed P. Potassium. The ACC/AHA guidelines recommend
maintaining the serum potassium concentration above4.0 meq/L in an acute MI. Maintaining a serum mag-nesium concentration above 2.0 meq/L is recom-mended.
Q. Unfractionated heparin (UFH) is given to patients
with with STEMI undergoing percutaneous or surgicalrevascularization, and to patients undergoingthrombolysis with selective fibrinolytic agents. Lowmolecular weight heparin (LMWH) is an alternative toUFH in patients receiving thrombolysis provided theyare younger than 75 years of age and have no renaldysfunction.
Treatment Recommendations for ST-Segment
Myocardial Infarction
Supportive Care for Chest Pain
• Al patients should receive supplemental oxygen, 2 L/min by
nasal canula, for a minimum of three hours • Two large-bore IVs should be placed Clinical symptoms or suspicion of AMI Aspirin allergy, active GI bleeding Chew and swallow one dose of160-325 mg, All patients with ischemic pain and ST-seg-ment elevation (>1 mm in >2 contiguousleads) within 6 hours of onset of persistentpain, age <75 years.
All patients with a new bundle branch blockand history suggesting acute MI.
Active internal bleeding; history ofcerebrovascular accident; recent intracranialor intraspinal surgery or trauma; intracranialneoplasm, arteriovenous malformation, oraneurysm; known bleeding diathesis; severeuncontrolled hypertension Reteplase (Retavase) 10 U IVP over 2 min
x 2. Give second dose of 10 U 30 min after
first dose OR
Tenecteplase (TNKase): <60 kg: 30 mg
IVP; 60-69 kg: 35 mg IVP; 70-79 kg: 40 mg
IVP; 80-89 kg: 45 mg IVP; >90 kg: 50 mg
IVP OR
t-PA (Alteplase, Activase) 15 mg IV over 2
minutes, then 0.75 mg/kg (max 50 mg) IV
over 30 min, fol owed by 0.5 mg/kg (max 35
mg) IV over 30 min.
Active internal or CNS bleeding Heparin 60 U/kg (max 4000 U) IVP, fol owed by 12 U/kg/hr (max 1000 U/h) continuous IVinfusion x 48 hours. Maintain aPTT 50-70seconds All patients with the diagnosis of AMI. Beginwithin 12 hours of diagnosis of AMI Severe COPD, hypotension, bradycardia,AV block, pulmonary edema, cardiogenicshock Metoprolol (Lopressor), 5 mg IV push every 5 minutes for three doses; fol owed by 25 mg
PO bid. Titrate up to 100 mg PO bid OR
Atenolol (Tenormin), 5 mg IV, repeated in 5
minutes, fol owed by 50-100 mg PO qd.
All patients with ischemic-type chest pain Hypotension; caution in right ventricular in-farction 0.4 mg NTG initial y q 5 minutes, up to 3 doses or nitroglycerine aerosol, 1 spraysublingually every 5 minutes. IV infusion ofNTG at 10-20 mcg/min, titrating upward by5-10 mcg/min q 5-10 minutes (max 3mcg/kg/min). Slow or stop infusion if systolicBP <90 mm Hg ACE-Inhibitors or Angiotensin Receptor Blockers:
All patients with the diagnosis of AMI. Initiatetreatment within 24 hours after AMI Bilateral renal artery stenosis, angioedemacaused by previous treatment Lisinopril (Prinivil) 2.5-5 mg qd, titrate to 10- 20 mg qd. Maintain systolic BP >100 mmHgorValsartan (Diovan) 40 mg bid, titrate to 160mg bid IV. Non-ST elevation. Patients with coronary ischemia but
who do not manifest ST elevations on ECG are consid-ered to have unstable angina (UA) or a non-ST eleva-tion myocardial infarction (NSTEMI). UA and NSTEMIcomprise part of the spectrum of ACS.
A. Angina is considered unstable if it presents in any of
the following three ways: 1.Rest angina, generally lasting longer than 20 minutes
2.New onset angina that markedly limits physical
3.Increasing angina that is more frequent, lasts longer,
or occurs with less exertion than previous angina B. NSTEMI is distinguished from UA by the presence of
elevated serum biomarkers. ST segment elevationsand Q waves are absent in both UA and NSTEMI.
Unstable angina and NSTEMI are frequently indistin-guishable initially because an elevation in serumbiomarkers is usually not detectable for four to sixhours after an MI, and at least 12 hours are requiredto detect elevations in all patients.
C. Risk stratification
1.The TIMI investigators developed a 7-point risk
stratification tool that predicted the risk of death,
reinfarction, or urgent revascularization at 14 days
after presentation. This scoring system includes the
following elements:
a. Age >65.
b. Three or more cardiac risk factors.
c. Aspirin use in the preceding seven days.
d. Two or more anginal events in the preceding 24
e. ST-segment deviation on presenting ECG.
f. Increased cardiac biomarkers.
g. Prior coronary artery stenosis >50 percent.
2.Patients are considered to be high risk if they have a
TIMI risk score of 5 or greater (one point is given foreach element) and low risk if the score is 2 or below.
3.Additional factors associated with death and
reinfarction at 30 days after presentation include:
a. Bradycardia or tachycardia
b. Hypotension
c. Signs of heart failure (new or worsening rales,
MR murmur, S3 gallop) d. Sustained ventricular tachycardia
D. Reperfusion. Thrombolytic therapy should not be
administered to patients with UA or NSTEMI unlesssubsequent ECG monitoring documents ST segmentelevations that persist. An aggressive approach toreperfusion using PCI is best suited for patients witha TIMI risk score >5 or possibly other high-riskfeatures.
E. Antiplatelet therapy is a cornerstone of treatment in
UA and NSTEMI.
1.Aspirin is the preferred antiplatelet agent and should
be given to all patients with suspected ACS.
2.Clopidogrel (300-600 mg) is indicted in patients
undergoing PCI. A class IIa recommendation wasgiven to their use in patients with high-risk features inwhom PCI is not planned.
F. Beta-blocker, nitroglycerin, morphine. The use of
these agents in NSTEMI is similar to that in STEMI.
G. Electrolyte repletion. Low electrolytes, particularly
potassium and magnesium, which are associatedwith an increased risk of ventricular fibrillation in thesetting of ACS, should be replaced.
H. Heparin. The ACC/AHA guidelines recommend the
use of enoxaparin in preference to unfractionatedheparin in patients with UA/NSTEMI, provided thereis no evidence of renal failure and CABG is notplanned within 24 hours.
I. Disposition of NSTEMI
1.High-risk patients have a high-risk ACS if ST
segment depression (>0.05 mV [0.5 mm]) is present
in two or more contiguous leads and/or the TIMI risk
score is >5. This patient is admitted to an intensive
care unit, coronary care unit, or monitored cardiac
unit depending upon the persistence of symptoms
and evidence of hemodynamic compromise. Those
with persistent pain or hemodynamic compromise
generally undergo urgent angiography and
revascularization. Others with resolution of symp-
toms and stable hemodynamics are typically referred
for early elective angiography and revascularization
if appropriate.
a. If there is no ST segment elevation or depression
or new LBBB, regardless of the presence orabsence of Q waves, the patient with definite orprobable ACS should still be admitted to a moni-tored care unit for further evaluation. Thosepatients manifesting high-risk features either onpresentation or during their emergency roomcourse should be considered for early PCI.
2.Moderate-risk patient. Patients who have no ECG
changes and are at moderate risk for ACS can beadmitted to a chest pain observation unit, if available,for further evaluation because a small percentage (2to 4 percent) will have an ACS.
3.Low-risk patient. Patients with no ECG changes, a
TIMI risk score below 3, and no other concerningfeatures in their presentation can be considered forearly provocative testing or possible discharge withoutpatient follow-up. Patients at very low risk inwhom there is clear objective evidence for a non-ischemic cause of their chest pain can be dischargedwith outpatient follow-up.
V. Cardiac biomarkers (enzymes). Serial serum
biomarkers (also called cardiac enzymes) of acute
myocardial damage, such as troponin T and I, creatine
kinase (CK)-MB, and myoglobin, are essential for
confirming the diagnosis of infarction. The most com-
monly used are troponin T or I and CK-MB, which can
be measured by rapid bedside assay.
A. Sensitivity and specificity. An elevation in the
serum concentration of one or more of the abovemarkers is seen in virtually all patients with an acuteMI. However, the sensitivity of these tests is relativelylow until four to six hours after symptom onset. Thus,a negative test in this time period does not excludeinfarction. Furthermore, some patients do not showa biomarker elevation for as long as 12 hours.
B. Therefore, in patients who have an acute STEMI,
reperfusion therapy should not await the results ofcardiac biomarkers. In patients without diagnostic STsegment elevation, serial biomarker testing is per-formed after four or more hours if the initial valuesare indeterminate, the ECG remains nondiagnostic,and clinical suspicion remains high.
Common Markers for Acute Myocardial Infarction
Return to
Peak Ele-
CTnI, CTnT = troponins of cardiac myofibrils; CPK-MB, MM =tissue isoforms of creatine kinase.
C. Unstable angina. Patients with cardiac biomarker
elevations and unstable angina are considered tohave an NSTEMI and should be treated appropri-ately.
D. Treadmill stress testing and echocardiography is
recommended for patients with a suspicion of coro-nary ischemia.
Heart Failure Caused by Systolic
Left Ventricular Dysfunction
Over four million persons have HF in the United States.
The mortality rate is 50 percent at two years and 60 to 70percent at three years. Heart failure (HF) can result fromany structural or functional cardiac disorder that impairs the ability of the ventricle to fill with or eject blood. It is charac-terized by dyspnea and fatigue, and signs of fluid retention.
I. Classification of severity
A. The classification system that is most commonly used
to quantify the degree of functional limitation imposedby heart failure is the New York Heart Association(NYHA) classification.
Classification of Patients with Heart Failure
Caused by Left Ventricular Dysfunction
Corresponding NYHA class
tion based on
symptoms
NYHA class II/III recent history ofdyspnea at rest B. Etiology. There are two mechanisms by which
reduced cardiac output and heart failure occur:systolic dysfunction and diastolic dysfunction.
C. Systolic dysfunction. The most common causes of
systolic dysfunction are coronary (ischemic) heartdisease, idiopathic dilated cardiomyopathy, hyperten-sion, and valvular disease. Coronary disease andhypertension account for 62 and 10 percent of cases,respectively.
D. Diastolic dysfunction can be induced by many of the
same conditions that lead to systolic dysfunction. Themost common causes are hypertension, ischemicheart disease, hypertrophic obstructivecardiomyopathy, and restrictive cardiomyopathy.
A. There are two major classes of symptoms in HF:
those due to excess fluid accumulation (dyspnea,edema, hepatic congestion, and ascites) and thosedue to a reduction in cardiac output (fatigue, weak-ness) that is most pronounced with exertion.
B. Acute and subacute presentations (days to weeks) are
characterized primarily by shortness of breath, at restand/or with exertion. Also common are orthopnea,paroxysmal nocturnal dyspnea, and, with right heartfailure, right upper quadrant discomfort due to acutehepatic congestion, which can be confused with acutecholecystitis. Patients with atrial and/or ventriculartachyarrhythmias may complain of palpitations with orwithout lightheadedness.
C. Chronic presentations (months) differ in that fatigue,
anorexia, bowel distension, and peripheral edemamay be more pronounced than dyspnea.
D. Classic exertional angina usually indicates ischemic
heart disease.
E. Acute heart failure after an antecedent flu-like illness
suggests viral myocarditis.
F. Long-standing hypertension or alcohol use suggests
hypertensive or alcoholic cardiomyopathy.
G. Amyloidosis should be excluded in patients who also
have a history of heavy proteinuria.
H. Primary valvular dysfunction should be considered in
a patient with significant murmurs.
I. Heart failure may be provoked or worsened by drugs,
including antiarrhythmic agents such as disopyramideand flecainide; calcium channel blockers, particularlyverapamil; beta-blockers; and nonsteroidal anti-inflammatory drugs (NSAIDs).
Factors Associated with Worsening Heart Failure
Superimposed ischemia or infarctionUncontrolled hypertensionUnrecognized primary valvular diseaseWorsening secondary mitral regurgitationNew onset or unctontrolled atrial fibrillationExcessive tachycardiaPulmonary embolism Inappropriate medicationsSuperimposed infectionAnemiaUncontrolled diabetesThyroid dysfunctionElectrolyte disordersPregnancy Medication noncomplianceDietary indiscretionAlcohol consumptionSubstance abuse A. Patients compensate for a fall in cardiac output by
increasing sympathetic outflow. This results in shunt-ing of the cardiac output to vital organs, leading tosinus tachycardia, diaphoresis, and peripheralvasoconstriction, manifested as cool, pale, andsometimes cyanotic extremities.
B. Volume overload. There are three major manifesta-
tions of volume overload in patients with HF arepulmonary congestion, peripheral edema, and ele-vated jugular venous pressure.
C. Ventricular enlargement. Ventricular chamber size
can be estimated by precordial palpation. An apicalimpulse that is laterally displaced past themidclavicular line is usually indicative of left ventricularenlargement. Left ventricular dysfunction can alsolead to sustained apical impulse which may be ac-companied by a parasternal heave.
D. Pulmonary hypertension. Patients with chronic heart
failure often develop secondary pulmonary hyperten-sion, which can contribute to dyspnea. These patientsmay also complain of substernal chest pressure,typical of angina. Physical signs of pulmonary hyper-tension can include increased intensity of P2, amurmur of pulmonary insufficiency, and a palpablepulmonic tap.
IV. Blood tests
A. Recommended initial blood tests for patients with
signs or symptoms of HF include:
1. A complete blood count since anemia can exacer-
bate pre-existing HF.
2. Serum electrolytes and creatinine as a baseline to
follow when initiating therapy with diuretics and/orangiotensin converting enzyme inhibitors.
3. Liver function tests, which may be affected by
hepatic congestion.
4. Fasting blood glucose to detect underlying diabetes
mellitus. (See "Heart failure in diabetes mellitus").
Laboratory Workup for Suspected Heart Failure
Blood urea nitrogen Thyroid-stimulating hormone Cardiac enzymes (CK-MB, Complete blood cell count Impedance cardiography Atrial natriuretic peptide Liver function tests Brain natriuretic peptide(BNP) B. In addition, if it is determined that dilated
cardiomyopathy is responsible for HF and the cause
is not apparent, several other blood tests may be
warranted.
1. Thyroid function tests, particularly in patients over
the age of 65 or in patients with atrial fibrillation.
Thyrotoxicosis is associated with atrial fibrillationand hypothyroidism may present as HF.
2. Iron studies (ferritin and TIBC) to screen for heredi-
tary hemochromatosis (HH).
C. Other studies that may be undertaken depending
upon the potential findings identified in the history and
physical examination include:
1. ANA and other serologic tests for lupus.
2. Viral serologies and antimyosin antibody if
myocarditis is suspected.
3. Evaluation for pheochromocytoma.
4. Thiamine, carnitine, and selenium levels.
5. Genetic testing and counseling (eg, in patients
suspected of familial cardiomyopathy after obtain-ing a detailed family history).
D. Plasma BNP. With chronic HF, atrial myocytes
secrete increased amounts of atrial natriuretic peptide(ANP) and ventricular myocytes secrete both ANP andbrain natriuretic peptide (BNP) in response to the highatrial and ventricular filling pressures. The plasmaconcentrations of both hormones are increased inasymptomatic and symptomatic left ventricular dys- function, permitting their use in diagnosis. A valueBNP >100 pg/mL diagnoses HF with a sensitivity,specificity, and predictive accuracy of 90, 76, and 83percent, respectively.
E. Plasma N-pro-BNP. The active BNP hormone is
cleaved from the C-terminal end of its prohormone,pro-BNP. The N-terminal fragment, N-pro-BNP, is alsoreleased into the circulation. In normal subjects, theplasma concentrations of BNP and N-pro-BNP aresimilar (approximately 10 pmol/L). However, in pa-tients with LV dysfunction, plasma N-pro-BNP concen-trations are approximately four-fold higher than BNPconcentrations.
Chest x-ray. The chest x-ray is a useful first diagnos-
tic test, particularly in the evaluation of patients who
present with dyspnea, to differentiate heart failure
from primary pulmonary disease. Findings suggestive
of heart failure include cardiomegaly (cardiac-to-
thoracic width ratio above 50 percent), cephalization
of the pulmonary vessels, Kerley B-lines, and pleural
effusions. The cardiac size and silhouette may also
reveal cardiomegaly.
A. The electrocardiogram may show findings that favor
the presence of a specific cause of heart failure andcan also detect arrhythmias such as asymptomaticventricular premature beats, runs of nonsustainedventricular tachycardia, or atrial fibrillation, which maybe the cause of or exacerbate HF.
B. Patients with dilated cardiomyopathy frequently have
first degree AV block, left bundle branch block, left
anterior fascicular block, or a nonspecific
intraventricular conduction abnormality. Among the
potentially diagnostic findings on ECG are:
1. Evidence of ischemic heart disease.
2. Left ventricular hypertrophy due to hypertension; a
pseudo-infarct pattern may also be present.
3. Low-limb lead voltage on the surface ECG with a
pseudo-infarction pattern (loss of precordial R-wave progression in leads V1-V6) can suggest aninfiltrative process such as amyloidosis.
4. Low-limb lead voltage with precordial criteria for left
ventricular hypertrophy is most suggestive ofidiopathic dilated cardiomyopathy. A widened QRScomplex and/or a left bundle branch block patternis also consistent with this diagnosis.
5. Heart block, that may be complete, and various
types of intraventricular conduction defects areobserved in patients with cardiac sarcoidosis.
6. Persistent tachycardia such as atrial fibrillation with
a rapid ventricular response may lead to ac a r d i o m yo p a t h y ( t a c h yc a r d i a - m e d i a te dcardiomyopathy).
C. Most patients with HF due to systolic dysfunction have
a significant abnormality on ECG. A normal ECGmakes systolic dysfunction extremely unlikely (98percent negative predictive value).
VII. Laboratory testing
A. Echocardiography. Echocardiography should be
performed in all patients with new onset heart failureand can provide important information about ventricu-lar size and function. The sensitivity and specificityechocardiography for the diagnosis of HF are as highas 80 and 100 percent, respectively.
B. Detection of coronary heart disease. Most patients
with HF due to ischemic cardiomyopathy have known
coronary heart disease. However, occult disease is a
not uncommon cause of dilated cardiomyopathy,
accounting for as many as 7 percent of initially unex-
plained cases. Heart failure resulting from coronary
disease is usually irreversible due to myocardial
infarction and subsequent ventricular remodeling.
However, revascularization may be of benefit in
patients in whom hibernating myocardium is in part
responsible for the decline in myocardial function.
1. Exercise testing should be part of the initial
evaluation of any patient with HF. In addition todetection of ischemic heart disease, assessment ofexercise capacity can be used for risk stratificationand determining prognosis. With severe heartfailure, measurement of the maximal oxygenuptake (VO max) provides an objective estimate of the functional severity of the myocardial dysfunc-tion.
2. Cardiac catheterization. Coronary catheterization
with angiography is indicated in virtually all patientswith new onset heart failure of uncertain cause,even in patients with no history of anginal symp-toms and a normal exercise test. Some exceptionsinclude patients with comorbid conditions thateither render catheterization too risky or that wouldpreclude invasive therapy.
VIII. Treatment of heart failure due to systolic dysfunc-
A. Treatment of the underlying cardiac disease
1. Hypertension is the primary cause of HF in 13
percent of patients.
2. Angiotensin converting enzyme (ACE) inhibitors,
beta-blockers, and angiotensin II receptor blockers(ARBs) are the preferred antihypertensive agentsbecause they improve survival in patients with HF.
Beta-blockers can also provide anginal relief inpatients with ischemic heart disease and ratecontrol in atrial fibrillation. Beta-blocker therapyshould always be initiated at very low doses.
3. Renovascular disease testing is indicated in
patients in whom the history is suggestive (severeor refractory hypertension, a sudden rise in bloodpressure, or repeated episodes of flash pulmonaryedema).
4. Ischemic heart disease. Coronary atherosclerosis
is the most common cause of cardiomyopathy,comprising 50 to 75 percent of patients with HF. Allpatients with ischemic heart disease should betreated medically for relief of angina and with risk-factor reduction. Myocardial revascularization withangioplasty or bypass surgery may improve symp-tom status, exercise capacity. Revascularizationshould also be considered in patients with a historyof repeated episodes of acute left ventriculardysfunction and flash pulmonary edema.
5. Valvular disease is the primary cause of HF in 10
to 12 percent of patients. Surgical correction ofvalvular disease can lead to improvement in car-diac function.
6. Other factors that can cause, or worsen, HF
include alcohol abuse, cocaine abuse, obstructivesleep apnea, nutritional deficiencies, myocarditis,hemochromatosis, sarcoidosis, and rheumatologicdisorders, such as systemic lupus erythematosus.
Treatment Classification of Patients with Heart
Failure Caused by Left Ventricular Systolic Dys-
function
Symptoms Pharmacology
Beta blockerDiuretic If symptoms persist: digoxin(Lanoxin) Symptomatic with recent history of dyspnea at rest Spironolactone (Aldactone) Beta blocker Digoxin Symptomatic with dyspnea Spironolactone (Aldactone) Digoxin Dosages of Primary Drugs Used in the Treatment
of Heart Failure
Drugs that decrease mortality and improve symptoms
three times daily (one-half tablet) 2.5 mg twice daily 10 mg twice daily 10 to 20 mg daily Ramipril (Altace) Angiotensin-Receptor Blockers (ARBs)
Valsartan (Diovan) (one-fourth tablet) Carvedilol (Coreg) 25 to 50 mg twice Metoprolol tartrate 50 to 75 mg twice daily (one-fourth (one-half tablet) Drugs that treat symptoms
25 to 100 mg daily zide (Esidrex) Metolazone 2.5 to 10 mg daily 1 to 10 mg once to three times daily 25 to 200 mg once 40 to 400 mg once to three timesdaily 20 to 200 mg once Digoxin (Lanoxin) 0.125 to 0.375 mgdaily B. Pharmacologic therapy of heart failure
1. ACE inhibitors improve survival in patients with all
severities of myocardial disease, ranging fromasymptomatic left ventricular dysfunction to moder-ate or severe HF. All patients with asymptomatic orsymptomatic left ventricular dysfunction should bestarted on an ACE inhibitor. Beginning therapy withlow doses (eg, 2.5 mg of enalapril (Vasotec) BID or6.25 mg of captopril (Capoten) TID) will reduce thelikelihood of hypotension and azotemia. The doseis then gradually increased to a maintenance doseof 10 mg BID of enalapril, 50 mg TID of captopril, orup to 40 mg/day of lisinopril or quinapril.
2. Angiotensin II receptor blockers for the treat-
ment of HF appear to be as effective as, or possiblyslightly less effective than, ACE inhibitors. Theaddition of an ARB, if tolerated, to HF therapy inpatients who are stable on ACE inhibitors and beta-blockers is recommended. ARB therapy should notbe added to an ACE inhibitor in the immediatepost-MI setting.
3. Beta-blockers carvedilol, metoprolol, and
bisoprolol improve overall and event-free survival
in patients with New York Heart Association
(NYHA) class II to III HF and probably in class IV
HF. Beta-blockers with intrinsic sympathomimetic
activity (such as pindolol and acebutolol) should be
avoided
a. Carvedilol, metoprolol, or bisoprolol is recom-
mended for all patients with symptomatic HF,unless contraindicated.
b. Relative contraindications in HF include:
(1) Heart rate <60 bpm.
(2) Systolic arterial pressure <100 mm Hg.
(3) Signs of peripheral hypoperfusion.
(4) PR interval >0.24 sec.
(5) Second- or third-degree atrioventricular
(6) Severe chronic obstructive pulmonary dis-
(7) History of asthma.
(8) Severe peripheral vascular disease.
c. Prior to initiation of therapy, the patient should
be stable on an ACE inhibitor and (if necessaryfor symptom control) digoxin and diuretics,should have no or minimal evidence of fluidretention, and should not have required recentintravenous inotropic therapy.
d. Therapy should be begun at very low doses and
the dose doubled at regular intervals every twoto three weeks until the target dose is reachedor symptoms become limiting. Initial and targetdoses are: (1) Carvedilol (Coreg), 3.125 mg BID and 25 to
50 mg BID (the higher dose being used insubjects over 85 kg).
(2) Metoprolol (Toprol), 6.25 mg BID and 50 to
75 mg BID, and for extended-releasemetoprolol, 12.5 or 25 mg daily and 200mg/day.
(3) Bisoprolol (Ziac), 1.25 mg QD and 5 to 10
(4) The patient should weigh himself daily and
call the physician if there has been a 1 to 1.5kg weight gain. Weight gain may be treatedwith diuretics, but resistant edema or moresevere decompensation may require dosereduction or cessation of the beta-blocker.
4. Digoxin is given to patients with HF and systolic
dysfunction to control symptoms (fatigue, dyspnea,and exercise intolerance) and, in atrial fibrillation, tocontrol the ventricular rate. Digoxin should bestarted in left ventricular systolic dysfunction (leftventricular ejection fraction [LVEF] <40 percent)who continue to have symptoms despite appropri-ate therapy including an ACE inhibitor, beta-blocker, and, if necessary for fluid control, a di-uretic. The usual daily dose is 0.125 to 0.25 mg,based upon renal function. The serum digoxinconcentration should be maintained between 0.5and 0.8 ng/mL.
5. Diuretics. Sodium and water retention lead to
pulmonary and peripheral edema.
a. A loop diuretic should be given to control pulmo-
nary and/or peripheral edema. The most com-monly used loop diuretic is furosemide (Lasix),but some patients respond better to bumetanide(Bumex) or torsemide (Demadex) because ofsuperior and more predictable absorption.
b. The usual starting dose in outpatients with HF is
20 to 40 mg of furosemide. In patients who arevolume overloaded, a reasonable goal is weightreduction of 0.5 to 1.0 kg/day. If a patient doesnot respond, the diuretic dose should initially beincreased.
c. In patients with HF and a normal glomerular
filtration rate, the maximum doses are 40 to 80mg of furosemide, 2 to 3 mg of bumetanide, or20 to 50 mg of torsemide. In patients with renalinsufficiency, a higher maximum dose of 160 to200 mg of furosemide or its equivalent can begiven.
d. Intravenous diuretics (either as a bolus or a
continuous infusion) are more potent than theirequivalent oral doses and may be required forunstable or severe disease. Thiazide diureticscan be added for a synergistic effect.
e. A continuous infusion of a loop diuretic may
improve diuresis and reduce toxicity whencompared to intermittent bolus injections. Urineoutput is significantly greater.
6. Aldosterone antagonists. Spironolactone and
eplerenone, which compete with aldosterone for
the mineralocorticoid receptor, prolong survival in
selected patients with HF. Eplerenone has greater
specificity for the mineralocorticoid receptor and a
lower incidence of endocrine side effects.
a. Therapy should be initiated with spironolactone,
and switch to eplerenone (25 to 50 mg/day) ifendocrine side effects occur. The serum potas-sium should be monitored.
C. Drugs that are contraindicated in HF
1. Nonsteroidal anti-inflammatory drugs (NSAIDs)
can cause a worsening of pre-existing HF becauseof systemic vasoconstriction. NSAID may blunt therenal effects of diuretics and may reverse the effectof angiotensin converting enzyme (ACE) inhibitors.
2. Thiazolidinediones are oral hypoglycemic agents
that increase insulin sensitivity. Drugs in this classcause fluid retention, which may precipitate HF.
Patients with HF who are currently takingthiazolidinediones should be carefully followed forsigns and symptoms of HF, and the agent shouldbe stopped if signs of fluid retention develop.
Thiazolidinediones should not be used in patientswith New York Heart Association class III or IV HF.
3. Metformin (Glucophage). Patients with HF who
take metformin are at increased risk of potentiallylethal lactic acidosis. Metformin is contraindicatedin patients with HF.
4. Cilostazol suppresses platelet aggregation and is
a direct arterial vasodilator. In patients with HF, oralphosphodiesterase inhibitors has been associatedwith increased mortality. HF of any severity is acontraindication to the use of cilostazol.
5. Sildenafil (Viagra) is a phosphodiesterase inhibitor
that is used in the treatment of impotence. Thedrug is a vasodilator that can lower systemic blood pressure. Sildenafil may be potentially hazardousin HF.
6. Antiarrhythmic agents. Most antiarrhythmic drugs
have some negative inotropic activity and canprecipitate HF. The further reduction in LV functioncan also impair the elimination of these drugs,resulting in drug toxicity. In addition, someantiarrhythmic drugs have a proarrhythmic effect.
Amiodarone is safe and is the preferred drug totreat ventricular arrhythmias in HF D. Lifestyle modification
1. Cessation of smoking.
2. Restriction of alcohol consumption.
3. Salt restriction to 2 to 3 g of sodium per day to
minimize fluid accumulation.
4. Water restriction in patients who are hyponatremic
may minimize pulmonary congestion.
5. Daily weight monitoring to detect fluid accumulation
before it becomes symptomatic.
6. Weight reduction in obese subjects with a goal of
being within 10 percent of ideal body weight.
7. A cardiac rehabilitation program for stable patients.
IX. Management of refractory HF
A. Intravenous inotropes and vasodilators. Patients
with decompensated HF are often hospitalized and anintravenous infusion of a positive inotropic agentand/or a vasodilator is initiated. Inotropic drugs, suchas dobutamine, dopamine, milrinone, and amrinone,and vasodilators, such as nitroprusside, nitroglycerin,and nesiritide, can acutely improve hemodynamicsand relieve symptoms.
B. Symptomatic improvement has been demonstrated in
patients after treatment with a continuous infusion ofdobutamine (5 to 7.5 µg/kg per min) for three to fivedays. The benefit can last for 30 days or more. Thereis no evidence for a survival benefit, and intermittent,dobutamine may increase mortality. Use of intrave-nous dobutamine or milrinone is limited to the in-patient management of severe decompensated heartfailure.
Treatment of Acute Heart Failure/Pulmonary
Edema
• Oxygen therapy, 2 L/min by nasal canula• Furosemide (Lasix) 20-80 mg IV• Nitroglycerine start at 10-20 mcg/min and titrate to BP (use with caution if inferior/right ventricular infarction suspected) • Sublingual nitroglycerin 0.4 mg• Morphine sulfate 2-4 mg IV. Avoid if inferior wal MI sus- pected or if hypotensive or presence of tenuous airway • Potassium supplementation prn Atrial fibrillation (AF) is more prevalent in men and withincreasing age. AF can have adverse consequencesrelated to a reduction in cardiac output and to atrial throm-bus formation that can lead to systemic embolization.
A. Atrial fibrillation occurs in the normal heart and in the
presence of organic heart disease. Classification of
Atrial fibrillation:
1. Paroxysmal (ie, self-terminating) AF in which the
episodes of AF generally last less than seven days(usually less than 24 hours) and may be recurrent.
2. Persistent AF fails to self-terminate and lasts for
longer than seven days. Persistent AF may also beparoxysmal if it recurs after reversion. AF is consid-ered recurrent when the patient experiences two ormore episodes.
3. Permanent AF is considered to be present if the
arrhythmia lasts for more than one year and cardio-version either has not been attempted or has failed.
4. "Lone" AF describes paroxysmal, persistent, or
permanent AF in individuals without structural heartdisease.
B. If the AF is secondary to cardiac surgery, pericarditis,
myocardial infarction (MI), hyperthyroidism, pulmonaryembolism, pulmonary disease, or other reversiblecauses, therapy is directed toward the underlyingdisease as well as the AF.
A. History and physical examination. Associated
symptoms with AF should be sought; the clinical typeor "pattern" should be defined; the onset or date ofdiscovery of the AF; the frequency and duration of AFepisodes; any precipitating causes and modes oftermination of AF; the response to drug therapy; andthe presence of heart disease or potentially reversiblecauses (eg, hyperthyroidism).
B. The frequency and duration of AF episodes are
determined from the history. Symptoms include palpitations, weakness, dizziness, and dyspnea.
However, among patients with paroxysmal AF, up to90% of episodes are not recognized by the patient.
C. Electrocardiogram is used to verify the presence of
AF; identify left ventricular hypertrophy, pre-excitation,bundle branch block, or prior MI; define P-waveduration and morphology as well as other atrialarrhythmias on earlier ECGs.
D. Chest x-ray may be useful in assessing the lungs,
vasculature, and cardiac outline.
echocardiography is required to evaluate the size ofthe right and left atria and the size and function of theright and left ventricles; to detect possible valvularheart disease, left ventricular hypertrophy, andpericardial disease; and to assess peak right ventricu-lar pressure. It may also identify a left atrial thrombus,although the sensitivity is low. Transesophagealechocardiography is much more sensitive for atrialthrombi and can be used to determine the need forthree to four weeks of anticoagulation prior to cardio-version.
F. Assessment for hyperthyroidism. A low-serum
thyroid-stimulating hormone (TSH) value is found in5.4% of patients with AF; only 1% have clinicalhyperthyroidism. Measurement of serum TSH and freeT4 is indicated in all patients with a first episode of AF,when the ventricular response to AF is difficult tocontrol, or when AF recurs unexpectedly after cardio-version. Patients with low values (<0.5 mU/L) andnormal serum free T4 probably have subclinicalhyperthyroidism.
G. Additional testing
1. Exercise testing is often used to assess the ade-
quacy of rate control in permanent AF, to repro-duce exercise-induced AF, and to evaluate forischemic heart disease.
2. Holter monitoring or event recorders are used to
identify the arrhythmia if it is intermittent and notcaptured on routine electrocardiography.
3. Electrophysiologic studies may be required with
wide QRS complex tachycardia or a possiblepredisposing arrhythmia, such as atrial flutter or aparoxysmal supraventricular tachycardia.
General treatment issues
Risk-based Approach to Antithrombotic Therapy
in Atrial Fibrillation
Aspirin (325 mg per day) No heart disease (line Aspirin (325 mg per day) Hear disease by no riskfactors* Aspirin (325 mg per day) Oral anticoagulation With diabetes mellitus Addition of aspirin, 81 to162 mg/day is optional Age >75 years, espe- Oral anticoagulation Heart failure (HF) Oral anticoagulation Rheumatic heart dis- Oral anticoagulation ease (mitral stenosis) (INR 2.5 to 3.5 or higher Prosthetic heart valves may be apropriate) Prior thromboembolismPersistent atrial throm-bus on TEE *Risk factors for thromboembolism include heartfailure, left ventricular ejection fraction (LVEF) lessthan 0.35, and hypertension.
A. Rate control with chronic anticoagulation is recom-
mended for the majority of patients with AF.
B. Beta-blockers (eg, atenolol or metoprolol), diltiazem,
and verapamil are recommended for rate control atboth rest and exercise; digoxin is not effective duringexercise and should be used in patients with heartfailure or as a second-line agent.
C. Anticoagulation should be achieved with adjusted-
dose warfarin unless the patient is considered at lowembolic risk or has a contraindication. Aspirin may beused in such patients.
D. When rhythm control is chosen, both DC and pharma-
cologic cardioversion are appropriate options. Toprevent dislodgment of pre-existing thrombi, warfarintherapy should be given for three to four weeks priorto cardioversion unless transesophagealechocardiography demonstrates no left atrial thrombi.
Anticoagulation is continued for at least one monthafter cardioversion to prevent de novo thrombusformation.
E. After cardioversion, antiarrhythmic drugs to maintain
sinus rhythm are not recommended, since the risksoutweigh the benefits, except for patients with persis-tent symptoms during rate control that interfere withthe patient's quality of life. Recommended drugs areamiodarone, disopyramide, propafenone, and sotalol.
IV. Rhythm control
A. Reversion to NSR. Patients with AF of more than 48
hours duration or unknown duration may have atrial
thrombi that can embolize. In such patients, cardiover-
sion should be delayed until the patient has been
anticoagulated at appropriate levels for three to four
weeks or transesophageal echocardiography has
excluded atrial thrombi.
1. DC cardioversion is indicated in patients who are
hemodynamically unstable. In stable patients inwhom spontaneous reversion due to correction ofan underlying disease is not likely, either DC orpharmacologic cardioversion can be performed.
Electrical cardioversion is usually preferred be-cause of greater efficacy and a low risk ofproarrhythmia. The overall success rate of electri-cal cardioversion for AF is 75 to 93 percent and isrelated inversely both to the duration of AF and toleft atrial size.
2. A number of antiarrhythmic drugs are more effec-
tive than placebo, converting 30 to 60 percent ofpatients. Evidence of efficacy is best establishedfor dofetilide, flecainide, ibutilide, propafenone,amiodarone, and quinidine.
3. Rate control with an atrioventricular (AV) nodal
blocker (beta-blocker, diltiazem, or verapamil), or (ifthe patient has heart failure or hypotension) digoxinshould be attained before instituting a class IAdrug.
B. Maintenance of NSR. Only 20 to 30 percent of
patients who are successfully cardioverted maintain
NSR for more than one year without chronic
antiarrhythmic therapy. This is more likely to occur in
patients with AF for less than one year, no enlarge-
ment of the left atrium (ie, <4.0 cm), and a reversible
cause of AF such as hyperthyroidism, pericarditis,
pulmonary embolism, or cardiac surgery.
1. Prophylactic antiarrhythmic drug therapy is indi-
cated only in patients who have a moderate-to-highrisk for recurrence because the risks generallyoutweigh the benefits of maintenanceantiarrhythmic drug therapy except in patients withpersistent symptoms on a rate control regimen.
2. Evidence of efficacy is best for amiodarone,
propafenone, disopyramide, sotalol, flecainide, andquinidine. Flecainide may be preferred in patientswith no or minimal heart disease, while amiodaroneis preferred in patients with a reduced left ventricu-lar (LV) ejection fraction or heart failure and sotalolin patients with coronary heart disease. Concurrentadministration of an AV nodal blocker is indicatedin patients who have demonstrated a moderate-to-rapid ventricular response to AF.
3. Amiodarone is significantly more effective for
maintenance of sinus rhythm than otherantiarrhythmic drugs. Amiodarone should be usedas first-line therapy in patients without heart failure.
Rate control in chronic AF. Rapid ventricular rate in
patients with AF should be prevented because of
hemodynamic instability and/or symptoms.
A. Rate control in AF is usually achieved by slowing AV
nodal conduction with a beta-blocker, diltiazem,verapamil, or, in patients with heart failure orhypotension, digoxin. Amiodarone is also effective inpatients who are not cardioverted to NSR.
B. Heart rate control include:
1. Rest heart rate <80 beats/min.
2. 24-hour Holter average <100 beats/min and no
heart rate >110% of the age-predicted maximum.
3. Heart rate <110 beats/min in six minute walk.
C. Nonpharmacologic approaches. The medical
approaches to either rate or rhythm control described
above are not always effective.
1. Rhythm control. Alternative methods to maintain
NSR in patients who are refractory to conventionaltherapy include surgery, radiofrequency catheterablation, and pacemakers.
2. Rate control. Radio-frequency AV nodal-His
bundle ablation with permanent pacemaker place-ment or AV nodal conduction modification arenonpharmacologic therapies for achieving ratecontrol in patients who do not respond to pharma-cologic therapy.
Intravenous Agents for Heart Rate Control in
Atrial Fibrillation
Major Side
Oral Agents for Heart Rate Control
Major Side Ef-
Digitalis toxicity, heart block, brady- heart block,bradycardia,asthma, HF ity, skin discolor- corneal deposits, optic neuropathy, warfarin interac- tion, proarrhyth- mia (QT prolonga-tion) VI. Prevention of systemic embolization
A. Anticoagulation during restoration of NSR
1. AF for more than 48 hours or unknown dura-
tion. Outpatients without a contraindication to
warfarin who have been in AF for more than 48
hours should receive three to four weeks of warfa-
rin prior to and after cardioversion. This approach
is also recommended for patients with AF who
have valvular disease, evidence of left ventricular
dysfunction, recent thromboembolism, or when AF
is of unknown duration, as in an asymptomatic
patient.
a. The recommended target INR is 2.5 (range 2.0
to 3.0). The INR should be >2.0 in the weeksbefore cardioversion.
b. An alternative approach that eliminates the need
for prolonged anticoagulation prior to cardiover-sion is the use of transesophagealechocardiography-guided cardioversion.
c. Thus, the long-term recommendations for pa-
tients who have been cardioverted to NSR butare at high risk for thromboembolism are similarto those in patients with chronic AF, even thoughthe patients are in sinus rhythm.
2. AF for less than 48 hours. A different approach
with respect to anticoagulation can be used in low-risk patients (no mitral valve disease, severe leftventricular dysfunction, or history of recentthromboembolism) in whom there is reasonablecertainty that AF has been present for less than 48hours. Such patients have a low risk of clinicalthromboembolism if converted early (0.8%), evenwithout screening TEE.
3. Long-term anticoagulation prior to cardioversion is
not recommended in such patients, but heparin useis recommended at presentation and during thepericardioversion period.
Antithrombotic Therapy in Cardioversion for
Atrial Fibrillation
Timing of cardiover-
sion
Early cardioversion in pa- Heparin during cardiover- tients with atrial fibrillation sion period to achieve PTT for less than 48 hours of 50-70 seconds. Heparin70 U/kg load, 15 U/kg/hrdrip.
Early cardioversion in pa- Heparin during cardiover- tients with atrial fibrillation sion period to achieve PTT for more than 48 hours or an of 50-70 seconds. unknown duration, but with Warfarin (Coumadin) for 4 documented absence of weeks after cardioversion to achieve target INR of 2.0 to3.0.
Elective cardioversion in Warfarin for 3 weeks before patients with atrial fibrillation and 4 weeks after cardiover- for more than 48 hours or an sion to achieve target INR of of 2.0 to 3.0.
Weight-based nomogram for intravenous heparin
infusion
80 U/kg bolus, then 18 U/kg per hour 80 U/kg bolus, then increase infusion (<1.2 x control) rate by 4 U/kg per hour 40 U/kg per hour, then increase infu-sion by 2 U/kg per hour Decrease infusion rate by 2q U/kg perhour Hold infusion 1 hour, then decreaseinfusion rate by 3 U/kg per hour *aPTT = activated partial thromboplastin time 4. Current practice is to administer aspirin for a first
episode of AF that converts spontaneously andwarfarin for at least four weeks to all other patients.
5. Aspirin should not be considered in patients with
AF of less than 48 hours duration if there is associ-ated rheumatic mitral valve disease, severe leftv e n t r i c u l a r d y s f u n c t i o n , o r r e c e n tthromboembolism. Such patients should be treatedthe same as patients with AF of longer duration:one month of oral anticoagulation with warfarin orshorter-term anticoagulation with screening TEEprior to elective electrical or pharmacologic cardio-version followed by prolonged warfarin therapyafter cardioversion.
B. Anticoagulation in chronic AF
1. The incidence of stroke associated with AF is 3 to
5 percent per year in the absence ofanticoagulation; compared with the general popula-tion, AF significantly increases the risk of stroke(relative risk 2.4 in men and 3.0 in women).
2. The incidence of stroke is relatively low in patients
with AF who are under age 65 and have no risk factors. The prevalence of stroke associated withAF increases strikingly with age and with other riskfactors including diabetes, hypertension, previousstroke as clinical risk factors, and left ventriculardysfunction. The risk appears to be equivalent inchronic and paroxysmal AF.
3. Choice of antiembolism therapy.
a. Patients with a CHADS2 score of 0 are at low
risk of embolization (0.5% per year) and can bemanaged with aspirin.
b. Patients with a CHADS2 score >3 are at high
risk (5.3 to 6.9 percent per year) and should, inthe absence of a contraindication, be treatedwith warfarin.
c. Patients with a CHADS2 score of 1 or 2 are at
intermediate risk of embolization (1.5 to 2.5percent per year). In this group, the choicebetween warfarin therapy and aspirin will de-pend upon many factors, including patientpreference.
4. An INR between 2.0 and 3.0 is recommended for
most patients with AF who receive warfarin ther-apy. A higher goal (INR between 2.5 and 3.5) isreasonable for patients at particularly high risk forembolization (eg, prior thromboembolism, rheu-matic heart disease, prosthetic heart valves). Anexception to the latter recommendation occurs inpatients over the age of 75 who are at increasedrisk for major bleeding. A target INR of 1.8 to 2.5 isrecommended for this age group.
C. Anticoagulation in paroxysmal AF. The stroke risk
appears to be equivalent in paroxysmal and chronicAF. The factors governing the choice between warfa-rin and aspirin therapy and the intensity of warfarintherapy are similar to patients with chronic AF. Amongpatients with very infrequent and short episodes of AF,any protective effect from anticoagulation may bemore than offset by bleeding risk.
VII. Presentation and management of recent onset AF
A. Most patients with recent onset AF present with
palpitations, a sense of the heart racing, fatigue,lightheadedness, increased urination, or mild short-ness of breath. More severe symptoms and signsinclude dyspnea, angina, hypotension, presyncope, orinfrequently syncope. In addition, some patientspresent with an embolic event or the insidious onsetof right-sided heart failure (peripheral edema, weightgain, and ascites).
B. Indications for hospitalization
1. For the treatment of an associated medical prob-
lem, which is often the reason for the arrhythmia.
2. For elderly patients who are more safely treated for
AF in hospital.
3. For patients with underlying heart disease who
have hemodynamic consequences from the AF orwho are at risk for a complication resulting fromtherapy of the arrhythmia.
C. Search for an underlying cause, such as heart
failure (HF), pulmonary problems, hypertension, orhyperthyroidism, and for the urgency for heart rateslowing.
D. Serum should be obtained for measurement of thyroid
stimulating hormone (TSH) and free T4. This shouldbe done even if there are no symptoms suggestive ofhyperthyroidism, since the risk of AF is increased upto threefold in patients with subclinicalhyperthyroidism. The latter disorder is characterizedby low serum TSH (<0.5 mU/L) and normal serum freeT4.
E. If AF appears to have been precipitated by a revers-
ible medical problem, cardioversion should be post-poned until the condition has been successfullytreated, which will often lead to spontaneous rever-sion. If this treatment is to be initiated as an outpa-tient, anticoagulation with warfarin should be begunwith cardioversion performed, if necessary, after threeto four weeks of adequate anticoagulation. If thepatient is to be admitted to the hospital for treatmentof the underlying disease, it is prudent to beginheparin therapy and then institute oral warfarin.
Cardioversion is again performed after three to fourweeks of adequate anticoagulation if the patient doesnot revert to NSR. In either case, three to four weeksof adequate anticoagulation are not necessary if TEEis performed and shows no left atrial thrombus.
F. Indications for urgent cardioversion
1. Active ischemia.
2. Significant hypotension, to which poor LV systolic
function, diastolic dysfunction, or associated mitralor aortic valve disease may contribute.
3. Severe manifestations of HF.
4. The presence of a pre-excitation syndrome, which
may lead to an extremely rapid ventricular rate.
5. In a patient who has truly urgent indications for
cardioversion, the need for restoration of NSRtakes precedence over the need for protection from thromboembolic risk. If feasible, the patient shouldstill be heparinized for the cardioversion procedure.
G. Initial rate control with mild-to-moderate symp-
toms. Most patients with acute AF do not require
immediate reversion. Initial treatment directed at
slowing the ventricular rate will usually result in
improvement of the associated symptoms. This can
be achieved with beta-blockers, calcium channel
blockers (verapamil and diltiazem), or digoxin. The
drug selected and the route of administration (oral
versus intravenous) are dictated by the clinical pre-
sentation.
1. Digoxin is the preferred drug only in patients with
AF due to HF. Digoxin can also be used in patientswho cannot take or who respond inadequately tobeta-blockers or calcium channel blockers. Theeffect of digoxin is additive to both of these drugs.
2. A beta-blocker, diltiazem, or verapamil is the
preferred drug in the absence of HF. Beta-blockersare particularly useful when the ventricular re-sponse increases to inappropriately high ratesduring exercise, after an acute MI, and whenexercise-induced angina pectoris is also present. Acalcium channel blocker is preferred in patientswith chronic lung disease. The use of both a beta-blocker and calcium channel blocker should beavoided.
H. Elective cardioversion.
In some patients, antiarrhythmic drugs are administered prior to cardio-version to increase the chance of successful reversionand to prevent recurrence. Patients who are success-fully cardioverted generally require antiarrhythmicdrugs to increase the likelihood of maintaining sinusrhythm.
I. Immediate cardioversion. There is a low risk of
systemic embolization if the duration of the arrhythmiais 48 hours or less and there are no associatedcardiac abnormalities (mitral valve disease or LVenlargement). In such patients, electrical or pharma-cologic cardioversion can be attempted after systemicheparinization. Aspirin should be administered for afirst episode of AF that converts spontaneously andwarfarin for at least four weeks to all other patients.
J. Delayed cardioversion. It is preferable to
anticoagulate with warfarin for three to four weeks
before attempted cardioversion to allow any left atrial
thrombi to resolve if:
1. The duration of AF is more than 48 hours or of
unknown duration.
2. There is associated mitral valve disease or signifi-
cant cardiomyopathy or HF.
3. The patient has a prior history of a thromboembolic
4. During this time, rate control should be maintained
with an oral AV nodal blocker. The recommendedtarget INR is 2.5 (range 2.0 to 3.0). The INR shouldbe consistently >2.0 in the weeks before cardiover-sion.
K. Role of TEE. TEE immediately prior to elective
cardioversion should be considered for those patientsat increased risk for left atrial thrombi (eg, rheumaticmitral valve disease, recent thromboembolism, severeLV systolic dysfunction). Among patients with AF ofrecent onset (but more than 48 hours) who are notbeing anticoagulated, an alternative approach to threeto four weeks of warfarin therapy before cardioversionis TEE-based screening with cardioversion performedif no thrombi are seen.
Severe hypertension is defined as an elevation in diastolicblood pressure (BP) higher than 130 mm Hg.
I. Clinical evaluation of severe hypertension
A. Hypertensive emergencies is defined by a diastolic
blood pressure >120 mm Hg associated with ongoing
vascular damage. Symptoms or signs of neurologic,
cardiac, renal, or retinal dysfunction are present.
Adequate blood pressure reduction is required within
a few hours. Hypertensive emergencies include
severe hypertension in the following settings:
1. Aortic dissection
2. Acute left ventricular failure and pulmonary edema
3. Acute renal failure or worsening of chronic renal
4. Hypertensive encephalopathy
5. Focal neurologic damage indicating thrombotic or
hemorrhagic stroke 6. Pheochromocytoma, cocaine overdose, or other
hyperadrenergic states 7. Unstable angina or myocardial infarction
8. Eclampsia
B. Hypertensive urgency is defined as diastolic blood
pressure >130 mm Hg without evidence of vasculardamage; the disorder is asymptomatic and no retinallesions are present.
C. Secondary hypertension includes renovascular
hypertension, pheochromocytoma, cocaine use,withdrawal from alpha-2 stimulants, clonidine, beta-blockers or alcohol, and noncompliance withantihypertensive medications.
II. Initial assessment of severe hypertension
A. When severe hypertension is noted, the measure-
ment should be repeated in both arms to detect anysignificant differences. Peripheral pulses should beassessed for absence or delay, which suggestsdissecting aortic dissection. Evidence of pulmonaryedema should be sought.
B. Target organ damage is suggested by chest pain,
neurologic signs, altered mental status, profoundheadache, dyspnea, abdominal pain, hematuria, focalneurologic signs (paralysis or paresthesia), or hyper-tensive retinopathy.
C. Prescription drug use should be assessed, including
missed doses of antihypertensives. History of recentcocaine or amphetamine use should be sought.
D. If focal neurologic signs are present, a CT scan may
be required to differentiate hypertensiveencephalopathy from a stroke syndrome.
Laboratory evaluation
A. Complete blood cell count, urinalysis for protein,
glucose, and blood; urine sediment examination;chemistry panel (SMA-18).
B. If chest pain is present, cardiac enzymes are ob-
C. If the history suggests a hyperadrenergic state, the
possibility of a pheochromocytoma should be ex-cluded with a 24-hour urine for catecholamines. Aurine drug screen may be necessary to exclude illicitdrug use.
D. Electrocardiogram should be completed.
E. Suspected primary aldosteronism can be excluded
with a 24-hour urine potassium and an assessment ofplasma renin activity. Renal artery stenosis can beexcluded with captopril renography and intravenouspyelography.
Management of hypertensive emergencies
A. The patient should be hospitalized for intravenous
access, continuous intra-arterial blood pressuremonitoring, and electrocardiographic monitoring.
Volume status and urinary output should be moni-tored. Rapid, uncontrolled reductions in blood pres-sure should be avoided because coma, stroke,myocardial infarction, acute renal failure, or deathmay result.
B. The goal of initial therapy is to terminate ongoing
target organ damage. The mean arterial pressureshould be lowered not more than 20-25%, or to adiastolic blood pressure of 100 mm Hg over 15 to 30minutes. Blood pressure should be controlled over afew hours.
V. Management of hypertensive urgencies
A. The initial goal in patients with severe asymptomatic
hypertension should be a reduction in blood pressureto 160/110 over several hours with conventional oraltherapy. B. If the patient is not volume depleted, furosemide
(Lasix) is given in a dosage of 20 mg if renal functionis normal, and higher if renal insufficiency is present.
A calcium channel blocker (isradipine ([DynaCirc], 5mg or felodipine [Plendil], 5 mg) should be added. Adose of captopril (Capoten)(12.5 mg) can be added ifthe response is not adequate. This regimen shouldlower the blood pressure to a safe level over three tosix hours and the patient can be discharged on aregimen of once-a-day medications.
Parenteral antihypertensive agents
A. Nitroprusside (Nipride)
1. Nitroprusside is the drug of choice in almost all
hypertensive emergencies (except myocardialischemia or renal impairment). It dilates both ar-teries and veins, and it reduces afterload andpreload. Onset of action is nearly instantaneous,and the effects disappear 1-2 minutes after discon-tinuation.
2. The starting dosage is 0.25-0.5 mcg/kg/min by
continuous infusion with a range of 0.25-8.0mcg/kg/min. Titrate dose to gradually reduce bloodpressure over minutes to hours.
3. When treatment is prolonged or when renal insuffi-
ciency is present, the risk of cyanide andthiocyanate toxicity is increased. Signs ofthiocyanate toxicity include disorientation, fatigue,hallucinations, nausea, toxic psychosis, and sei-zures.
1. Nitroglycerin is the drug of choice for hypertensive
emergencies with coronary ischemia. It should notbe used with hypertensive encephalopathy be-cause it increases intracranial pressure.
2. Nitroglycerin increases venous capacitance,
decreases venous return and left ventricular fillingpressure. It has a rapid onset of action of 2-5minutes. Tolerance may occur within 24-48 hours.
3. The starting dose is 15 mcg IV bolus, then 5-10
mcg/min (50 mg in 250 mL D5W). Titrate by in-creasing the dose at 3- to 5-minute intervals.
Generally doses >1.0 mcg/kg/min are required forafterload reduction (max 2.0 mcg/kg/hr). Monitorfor methemoglobinemia. C. Labetalol IV (Normodyne)
1. Labetalol is a good choice if BP elevation is associ-
ated with hyperadrenergic activity, aortic dissec-tion, an aneurysm, or postoperative hypertension.
2. Labetalol is administered as 20 mg slow IV over 2
min. Additional doses of 20-80 mg may be adminis-tered q5-10min, then q3-4h prn or 0.5-2.0 mg/minIV infusion. Labetalol is contraindicated in obstruc-tive pulmonary disease, CHF, or heart blockgreater than first degree.
D. Enalaprilat IV (Vasotec)
1. Enalaprilat is an ACE-inhibitor with a rapid onset of
action (15 min) and long duration of action (11hours). It is ideal for patients with heart failure oraccelerated-malignant hypertension.
2. Initial dose, 1.25 mg IVP (over 2-5 min) q6h, then
increase up to 5 mg q6h. Reduce dose in azotemicpatients. Contraindicated in bilateral renal arterystenosis.
E. Esmolol (Brevibloc) is a non-selective beta-blocker
with a 1-2 min onset of action and short duration of 10min. The dose is 500 mcg/kg/min x 1 min, then 50mcg/kg/min; max 300 mcg/kg/min IV infusion.
F. Hydralazine is a preload and afterload reducing
agent. It is ideal in hypertension due to eclampsia.
Reflex tachycardia is common. The dose is 20 mgIV/IM q4-6h.
G. Nicardipine (Cardene IV) is a calcium channel
blocker. It is contraindicated in presence of CHF.
Tachycardia and headache are common. The onsetof action is 10 min, and the duration is 2-4 hours. Thedose is 5 mg/hr continuous infusion, up to 15 mg/hr.
H. Fenoldopam (Corlopam) is a vasodilator. It may
cause reflex tachycardia and headaches. The onsetof action is 2-3 min, and the duration is 30 min. Thedose is 0.01 mcg/kg/min IV infusion titrated, up to 0.3mcg/kg/min.
I. Phentolamine (Regitine) is an intravenous alpha-
adrenergic antagonist used in excess catecholaminestates, such as pheochromocytomas, rebound hyper-tension due to withdrawal of clonidine, and drugingestions. The dose is 2-5 mg IV every 5 to 10minutes.
J. Trimethaphan (Arfonad) is a ganglionic-blocking
agent. It is useful in dissecting aortic aneurysm whenbeta-blockers are contraindicated; however, it israrely used because most physicians are morefamiliar with nitroprusside. The dosage oftrimethoprim is 0.3-3 mg/min IV infusion.
Pericarditis is the most common disease of thepericardium. The most common cause of pericarditis isviral infection. This disorder is characterized by chest pain,a pericardial friction rub, electrocardiographic changes, andpericardial effusion.
I. Clinical features
A. Chest pain of acute infectious (viral) pericarditis
typically develops in younger adults 1 to 2 weeksafter a "viral illness." The chest pain is of sudden andsevere onset, with retrosternal and/or left precordialpain and referral to the back and trapezius ridge.
Pain may be preceded by low-grade fever. Radiationto the arms may also occur. The pain is oftenpleuritic (eg, accentuated by inspiration or coughing)and may also be relieved by changes in posture(upright posture).
B. A pericardial friction rub is the most important physi-
cal sign. It is often described as triphasic, withsystolic and both early (passive ventricular filling)and late (atrial systole) diastolic components, ormore commonly a biphasic (systole and diastole). C. Resting tachycardia (rarely atrial fibrillation) and a
low-grade fever may be present.
Causes of Pericarditis
Hypersensitivity: drug Infectious: Viral, bacte- Postmyocardial injury rial, tuberculous, para- Dissecting aneurysm Connective tissue dis- eases Metabolic: ure-mia, hypothyroidismNeoplasm, radiation II. Diagnostic testing
A. ECG changes. During the initial few days, diffuse
(limb leads and precordial leads) ST segment eleva-tions are common in the absence of reciprocal STsegment depression. PR segment depression is alsocommon and reflects atrial involvement.
B. The chest radiograph is often unrevealing, although
a small left pleural effusion may be seen. An elevatederythrocyte sedimentation rate and C-reactive protein(CRP) and mild elevations of the white blood cellcount are also common.
C. Labs: CBC, SMA 12, albumin, viral serologies:
Coxsackie A & B, measles, mumps, influenza, ASOtiter, hepatitis surface antigen, ANA, rheumatoidfactor, anti-myocardial antibody, PPD with candida,mumps. Cardiac enzymes q8h x 4, ESR, blood C&SX 2.
D. Pericardiocentesis: Gram stain, C&S, cell count &
differential, cytology, glucose, protein, LDH, amylase,triglyceride, AFB, specific gravity, pH.
E. Echocardiography is the most sensitive test for
detecting pericardial effusion, which may occur withpericarditis.
III. Treatment of acute pericarditis (nonpurulent)
A. If effusion present on echocardiography,
pericardiocentesis should be performed and thecatheter should be left in place for drainage.
B. Treatment of pain starts with nonsteroidal anti-
inflammatory drugs, meperidine, or morphine. Insome instances, corticosteroids may be required tosuppress inflammation and pain.
C. Anti-inflammatory treatment with NSAIDs is first-
line therapy.
1. Indomethacin (Indocin) 25 mg tid or 75 mg SR qd,
2. Ketorolac (Toradol) 15-30 mg IV q6h, OR
3. Ibuprofen (Motrin) 600 mg q8h.
D. Morphine sulfate 5-15 mg intramuscularly every 4-6
hours. Meperidine (Demerol) may also be used, 50-100 mg IM/IV q4-6h prn pain and promethazine(Phenergan) 25-75 mg IV q4h.
E. Prednisone, 60 mg daily, to be reduced every few
days to 40, 20, 10, and 5 mg daily.
F. Purulent pericarditis
1. Nafcillin or oxacillin 2 gm IV q4h AND EITHER
2. Gentamicin or tobramycin 100-120 mg IV (1.5-2
mg/kg); then 80 mg (1.0-1.5 mg/kg) IV q8h (adjust
in renal failure) OR
3. Ceftizoxime (Cefizox) 1-2 gm IV q8h.
4. Vancomycin, 1 gm IV q12h, may be used in place
of nafcillin or oxacillin.
Indications for implantation of a permanent pacemaker arebased on symptoms, the presence of heart disease and thepresence of symptomatic bradyarrhythmias. Pacemakersare categorized by a three- to five-letter code according tothe site of the pacing electrode and the mode of pacing.
I. Indications for pacemakers
A. First-degree atrioventricular (AV) block can be
associated with severe symptoms. Pacing maybenefit patients with a PR interval greater than 0.3seconds. Type I second-degree AV block does notusually require permanent pacing because progres-sion to a higher degree AV block is not common.
Permanent pacing improves survival in patients withcomplete heart block.
B. Permanent pacing is not needed in reversible causes
of AV block, such as electrolyte disturbances or Lymedisease. Implantation is easier and of lower cost withsingle-chamber ventricular demand (VVI) pacemak-ers, but use of these devices is becoming less com-mon with the advent of dual-chamber demand (DDD)pacemakers.
Generic Pacemaker Codes
grammability ofrate, out-put, sen-sitivity,etc.
C. Sick sinus syndrome (or sinus node dysfunction) is
the most common reason for permanent pacing.
Symptoms are related to the bradyarrhythmias ofsick sinus syndrome. VVI mode is typically used inpatients with sick sinus syndrome, but recent studieshave shown that DDD pacing improves morbidity,mortality and quality of life.
II. Temporary pacemakers
A. Temporary pacemaker leads generally are inserted
percutaneously, then positioned in the right ventricu-lar apex and attached to an external generator.
Temporary pacing is used to stabilize patientsawaiting permanent pacemaker implantation, tocorrect a transient symptomatic bradycardia due todrug toxicity or to suppress Torsades de Pointes bymaintaining a rate of 85-100 beats per minute untilthe cause has been eliminated.
B. Temporary pacing may also be used in a prophylac-
tic fashion in patients at risk of symptomaticbradycardia during a surgical procedure or high-degree AV block in the setting of an acute myocar-dial infarction.
C. In emergent situations, ventricular pacing can be
instituted immediately by transcutaneous pacingusing electrode pads applied to the chest wall.
References: See page 168.
T. Scott Gallacher, MDRyan Klein, MDMichael Krutzik, MDThomas Vovan, MD Endotracheal Tube Size (interior diameter):
Women 7.0-9.0 mmMen 8.0-10.0 mm 1. Prepare suction apparatus. Have Ambu bag and mask apparatus setup with 100% oxygen; and ensure thatpatient can be adequately bag ventilated and suctionapparatus is available.
2. If sedation and/or paralysis is required, consider rapid sequence induction as follows:
A. Fentanyl (Sublimaze) 50 mcg increments IV (1
B. Midazolam (Versed) 1 mg IV q2-3 min. max 0.1-0.15
mg/kg followed by: C. Succinylcholine (Anectine) 0.6-1.0 mg/kg, at appro-
priate intervals; or vecuronium (Norcuron) 0.1 mg/kgIV x 1.
D. Propofol (Diprivan): 0.5 mg/kg IV bolus.
E. Etomidate (Amidate): 0.3-0.4 mg/kg IV.
3. Position the patient's head in the sniffing position with head flexed at neck and extended. If necessary, elevatethe head with a small pillow.
4. Ventilate the patient with bag mask apparatus and hyperoxygenate with 100% oxygen.
5. Hold laryngoscope handle with left hand, and use right hand to open the patient's mouth. Insert blade along theright side of mouth to the base of tongue, and push thetongue to the left. If using curved blade, advance it tothe vallecula (superior to epiglottis), and lift anteriorly,being careful not to exert pressure on the teeth. If usinga straight blade, place beneath the epiglottis and liftanteriorly.
6. Place endotracheal tube (ETT) into right corner of mouth and pass it through the vocal cords; stop just after thecuff disappears behind vocal cords. If unsuccessful after30 seconds, stop and resume bag and mask ventilationbefore re-attempting. A stilette to maintain the shape ofthe ETT in a hockey stick shape may be used. Removestilette after intubation.
7. Inflate cuff with syringe keeping cuff pressure <20 cm H O, and attach the tube to an Ambu bag or ventilator.
Confirm bilateral, equal expansion of the chest andequal bilateral breath sounds. Auscultate the abdomento confirm that the ETT is not in the esophagus. If thereis any question about proper ETT location, repeatlaryngoscopy with tube in place to be sure it isendotracheal. Remove the tube immediately if there isany doubt about proper location. Secure the tube withtape and note centimeter mark at the mouth. Suction theoropharynx and trachea.
8. Confirm proper tube placement with a chest x-ray (tip of ETT should be between the carina and thoracic inlet, orlevel with the top of the aortic notch).
Nasotracheal intubation is the preferred method ofintubation if prolonged intubation is anticipated (increasedpatient comfort). Intubation will be facilitated if the patientis awake and spontaneously breathing. There is anincreased incidence of sinusitis with nasotrachealintubation.
1. Spray the nasal passage with a vasoconstrictor such as cocaine 4% or phenylephrine 0.25% (Neo-Synephrine). If sedation is required beforenasotracheal intubation, administer midazolam(Versed) 0.05-0.1 mg/kg IV push. Lubricate the nasalairway with lidocaine ointment.
Tube Size: Women 7.0 mm tube Men 8.0, 9.0 mm tube 2. Place the nasotracheal tube into the nasal passage, and guide it into nasopharynx along a U-shaped path.
Monitor breath sounds by listening and feeling theend of tube. As the tube enters the oropharynx,gradually guide the tube downward. If the breathsounds stop, withdraw the tube 1-2 cm until breathsounds are heard again. Reposition the tube, and, ifnecessary, extend the head and advance. If difficultyis encountered, perform direct laryngoscopy andinsert tube under direct visualization.
3. Successful intubation occurs when the tube passes through the cords; a cough may occur and breathsounds will reach maximum intensity if the tube is correctly positioned. Confirm correct placement bychecking for bilateral breath sounds and expansion ofthe chest.
4. Confirm proper tube placement with chest x-ray.
Respiratory Failure and Ventilator
Management
I. Indications for ventilatory support. Respirations >35,
vital capacity <15 mL/kg, negative inspiratory force <-25,pO <60 on 50% 0 . pH <7.2, pCO >55, severe, pro- gressive, symptomatic hypercapnia and/or hypoxia,severe metabolic acidosis.
II. Initiation of ventilator support
A. Noninvasive positive pressure ventilation may be
safely utilized in acute hypercapnic respiratory failure,avoiding the need for invasive ventilation and accom-panying complications. It is not useful in normocapnicor hypoxemic respiratory failure.
1. Prepare suction apparatus, laryngoscope,
endotracheal tube (No. 8); clear airway and placeoral airway, hyperventilate with bag and maskattached to high-flow oxygen.
2. Midazolam (Versed) 1-2 mg IV boluses until
3. Intubate, inflate cuff, ventilate with bag, auscultate
chest, and suction trachea.
C. Initial orders
1. Assist control (AC) 8-14 breaths/min, tidal vol-
ume = 750 mL (6 cc/kg ideal body weight), FiO = 100%, PEEP = 3-5 cm H O, Set rate so that minute ventilation (VE) is approximately 10 L/min. Alterna-tively, use intermittent mandatory ventilation (IMV)mode with same tidal volume and rate to achievenear-total ventilatory support. Pressure support at5-15 cm H O in addition to IMV may be added.
2. ABG should be obtained. Check ABG for adequate
ventilation and oxygenation. If PO is adequate and pulse oximetry is >98%, then titrate FiO to a safe level (FIO <60%) by observing the saturation via pulse oximetry. Repeat ABG when target FiO2 3. Chest x-ray for tube placement, measure cuff
pressure q8h (maintain <20 mm Hg), pulseoximeter, arterial line, and/or monitor end tidalCO . Maintain oxygen saturation >90-95%.
A. Decreased minute ventilation. Evaluate patient and
rule out complications (endotracheal tubemalposition, cuff leak, excessive secretions,bronchospasms, pneumothorax, worsening pulmo-nary disease, sedative drugs, pulmonary infection).
Readjust ventilator rate to maintain mechanicallyassisted minute ventilation of 10 L/min. If peak airwaypressure (AWP) is >45 cm H O, decrease tidal volume to 7-8 L/kg (with increase in rate if neces-sary), or decrease ventilator flow rate.
B. Arterial saturation >94% and pO >100, reduce
FIO (each 1% decrease in FIO reduces pO by 7 mm Hg); once FIO is <60%, PEEP may be reduced by increments of 2 cm H O until PEEP is 3-5cm H O.
Maintain O saturation of >90% (pO >60).
C. Arterial saturation <90% and pO <60, increase
FIO up to 60-100%, then consider increasing PEEP by increments of 3-5 cm H O (PEEP >10 requires a PA catheter). Add additional PEEP until oxygenationis adequate with an FIO of <60%.
D. Excessively low pH, (pH <7.33 because of respira-
tory acidosis/hypercapnia): Increase rate and/or tidalvolume. Keep peak airway pressure <40-50 cm H O if possible.
E. Excessively high pH (>7.48 because of respiratory
alkalosis/hypocapnia): Reduce rate and/or tidalvolume. If the patient is breathing rapidly aboveventilator rate, consider sedation.
F. Patient "fighting ventilator": Consider IMV or SIMV
mode, or add sedation with or without paralysis.
Paralytic agents should not be used without concur-rent amnesia and/or sedation.
G. Sedation
1. Midazolam (Versed) 0.05 mg/kg IVP x1, then
0.02-0.1 mg/kg/hr IV infusion. Titrate in incrementsof 25-50%.
2. Lorazepam (Ativan) 1-2 mg IV ql-2h pm sedation
or 0.05 mg/kg IVP x1, then 0.025-0.2 mg/kg/hr IVinfusion. Titrate in increments of 25-50%.
3. Morphine sulfate 2-5 mg IV q1h or 0.03-0.05
mg/kg/h IV infusion (100 mg in 250 mL D5W)titrated.
4. Propofol (Diprivan): 50 mcg/kg bolus over 5 min,
then 5-50 mcg/kg/min. Titrate in increments of 5mcg/kg/min.
H. Paralysis (with simultaneous amnesia)
1. Vecuronium (Norcuron) 0.1 mg/kg IV, then 0.06
mg/kg/h IV infusion; intermediate acting, maximum
neuromuscular blockade within 3-5 min. Half-life
60 min, OR
2. Cisatracurium (Nimbex) 0.15 mg/kg IV, then 0.3
mcg/kg/min IV infusion, titrate between 0.5-10
mcg/kg/min. Intermediate acting with half-life of 25
minutes. Drug of choice for patients with renal or
liver impairment, OR
3. Pancuronium (Pavulon) 0.08 mg/kg IV, then 0.03
mg/kg/h infusion. Long acting, half-life 110 min-
utes; may cause tachycardia and/or hypertension,
OR
4. Atracurium (Tracrium) 0.5 mg/kg IV, then 0.3-0.6
mg/kg/h infusion, short acting; half-life 20 minutes.
Histamine releasing properties may causebronchospasm and/or hypotension.
5. Monitor level of paralysis with a peripheral nerve
stimulator. Adjust neuromuscular blocker dosageto achieve a "train-of-four" (TOF) of 90-95%; ifinverse ratio ventilation is being used, maintainTOF at 100%.
I. Loss at tidal volume: If a difference between the
tidal volume setting and the delivered volume occurs,check for a leak in the ventilator or inspiratory line.
Check for a poor seal between the endotracheal tubecuff or malposition of the cuff in the subglottic area. Ifa chest tube is present, check for air leak.
J. High peak pressure: If peak pressure is >40-50,
consider bronchospasm, secretion, pneumothorax,ARDS, agitation. Suction the patient and auscultatelungs. Obtain chest radiograph if pneumothorax,pneumonia or ARDS is suspected. Check "plateaupressure" to differentiate airway resistance fromcompliance causes.
Inverse Ratio Ventilation
1. Indications: ARDS physiology, pAO <60 mm Hg, FIO >0.6, peak airway pressure >45 cm H 0, or PEEP > 15 cm H 0. This type of ventilatory support requires heavy sedation and respiratory muscle relaxation.
2. Set oxygen concentration (FIO ) at 1.0; inspiratory pressure at 1/2 to 1/3 of the peak airway pressure onstandard ventilation. Set the inspiration: expiration ratioat 1: 1; set rate at <15 breaths/min. Maintain tidalvolume by adjusting inspiratory pressures.
3. Monitor PaO , oxygen saturation (by pulse oximetry), PaCO , end tidal PCO , PEEP, mean airway pressure, heart rate, blood pressure, SVO , and cardiac output.
4. It SaO remains <0.9, consider increasing I:E ratio (2:1, 3:1), but attempt to keep I:E ratio <2:1. If SaO remains <0.9, increase PEEP or return to conventional mode. Ifhypotension develops, rule out tension pneumothorax,administer intravascular volume or pressor agents,decrease I:E ratio, or return to conventional ventilationmode.
I. Ventilator weaning parameters
A. Patient alert and rested
B. PaO >70 mm Hg on FiO <50%
C. PaCO <50 mm Hg; pH >7.25
D. Negative Inspiratory Force (NIF) less than -40 cm
E. Vital Capacity >10-15 mL/kg (800-1000 mL)
F. Minute Ventilation (VE) <10 L/min; respirations <24
G. Maximal voluntary minute (MVV) ventilation doubles
that of resting minute ventilation (VE).
H. PEEP <5 cm H O
Tidal volume 5-8 mL/kg J. Respiratory rate to tidal volume ratio <105
K. No chest wall or cardiovascular instability or exces-
II. Weaning protocols
A. Weaning is considered when patient medical condi-
tion (ie, cardiac, pulmonary) status has stabilized.
B. Indications for termination of weaning trial
1. PaO falls below 55 mm Hg
2. Acute hypercapnia
3. Deterioration of vital signs or clinical status (ar-
C. Rapid T-tube weaning method for short-term (<7
days) ventilator patients without COPD
1. Obtain baseline respiratory rate, pulse, blood
pressure and arterial blood gases or oximetry.
Discontinue sedation, have the well-rested patient
sit in bed or chair. Provide bronchodilators andsuctioning if needed.
2. Attach endotracheal tube to a T-tube with FiO2
>10% greater than previous level. Set T-tubeflow-by rate to exceed peak inspiratory flow.
3. Patients who are tried on T-tube trial should be
observed closely for signs of deterioration. Afterinitial 15-minute interval of spontaneous ventila-tion, resume mechanical ventilation and checkoxygen saturation or draw an arterial blood gassample.
4. If the 30-minute blood gas is acceptable, a 60-
minute interval may be attempted. After eachinterval, the patient is placed back on the ventila-tor for an equal amount of time.
5. If the 60-minute interval blood gas is accept-
able and the patient is without dyspnea, and if
blood gases are acceptable, extubation may be
considered.
D. Pressure support ventilation weaning method
1. Pressure support ventilation is initiated at 5-25
cm H O. Set level to maintain the spontaneous
tidal volume at 7-15 mL/kg.
2. Gradually decrease the level of pressure
support ventilation in increments of 3-5 cm H O
according to the ability of the patient to maintainsatisfactory minute ventilation.
3. Extubation can be considered at a pressure
support ventilation level of 5 cm H O provided that the patient can maintain stable respiratory statusand blood gasses.
E. Intermittent mandatory ventilation (IMV) weaning
method
1. Obtain baseline vital signs and draw baseline
arterial blood gases or pulse oximetry. Discon-
tinue sedation; consider adding pressure support
of 10-15 cm H O.
2. Change the ventilator from assist control to
IMV mode; or if already on IMV mode, decrease
the rate as follows:
a. Patients with no underlying lung disease
and on ventilator for a brief period (<1 week).
(1) Decrease IMV rate at 30 min intervals by
1-3 breath per min at each step, starting atrate of 8-10 until a rate for zero is reached.
(2) If each step is tolerated and ABG is ade-
quate (pH >7.3-7.35), extubation may beconsidered.
(3) Alternatively: The patient may be watched
on minimal support (ie, pressure supportwith CPAP) after IMV rate of zero isreached. If no deterioration is noted,extubation may be accomplished.
b. Patients with COPD or prolonged ventilator
support (>1 week)
(1) Begin with IMV at frequency of 8
breath/minute, with tidal volume of 10mL/kg, with an FiO 10% greater than previous setting. Check end-tidal CO .
(2) ABG should be drawn at 30- and 60-min-
ute intervals to check for adequate ventila-tion and oxygenation. If the patient and/orblood gas deteriorate during weaning trial,then return to previous stable setting.
(3) Decrease IMV rate in increments of 1-2
breath per hour if the patient is clinicalstatus and blood gases remain stable.
Check ABG and saturation one-half hourafter a new rate is set.
(4) If the patient tolerates an IMV rate of zero,
decrease the pressure to support in incre-ments of 2-5 cm H O per hour until a pres- sure support of 5 cm H O is reached.
(5) Observe the patient for an additional 24
hours on minimal support beforeextubation.
3. Causes of inability to wean patients from
ventilators: Bronchospasm, active pulmonary
infection, secretions, small endotracheal tube,
weakness of respiratory muscle, low cardiac
output.
More than 500,000 patients are diagnosed with pulmonaryemboli annually, resulting in 200,000 deaths. Pulmonaryembolism is associated with a mortality rate of 30 percentif untreated. Accurate diagnosis with ventilation/perfusionlung scanning or pulmonary angiography followed bytherapy with anticoagulants significantly decreases themortality rate to 2 to 8 percent.
A. Pulmonary emboli usually arise from thrombi in the
deep venous system of the lower extremities; how-ever, they may also originate in the pelvic, renal, orupper extremity veins and in the right heart B. Risk factors. Patients with pulmonary emboli usually
have risk factors for the development of venous
thrombosis.
1. Immobilization.
2. Surgery within the last three months.
3. History of venous thromboembolism.
4. Malignancy is an increased risk associated with
obesity (relative risk 2.9), heavy cigarette smoking25 to 34 cigarettes per day, and hypertension.
C. Patients with pulmonary emboli without identifiable
risk factors (idiopathic or primary venousthromboembolism) may have unsuspected underlyingabnormalities that favor the development ofthromboembolic disease. Factor V Leiden mutationshould be particularly suspected in this setting, beingseen in up to 40 percent of cases. High concentrationsof factor VIII are present in 11 percent and confer asixfold risk for venous thromboembolism.
D. When idiopathic venous thromboembolism recurs,
occult malignancy should also be suspected, beingpresent in 17 percent of such patients. Venousthromboembolism may be the presenting sign ofpancreatic or prostate cancers, breast, lung, uterine,or brain malignancies.
II.Clinical manifestations. Sixty-five to 90 percent of
pulmonary emboli arise from the lower extremities.
However, the majority of patients with pulmonary embo-
lism have no leg symptoms.
A. The most common symptoms are dyspnea (73 per-
cent), pleuritic pain (66 percent), cough (37 percent)and hemoptysis (13 percent).
B. The most common signs are tachypnea (70 percent),
rales (51 percent), tachycardia (30 percent), a fourthheart sound (24 percent), and an accentuated pul-monic component of the second heart sound (23percent).
C. The syndrome of pleuritic pain or hemoptysis without
cardiovascular collapse is the most commonly recog-nized syndrome (65 percent); isolated dyspnea isobserved in 22 percent. Circulatory collapse is uncom-mon (8 percent).
D. Fever, usually with a temperature <102.0ºF, occurs in
14 percent of patients with pulmonary embolism.
Frequency of Symptoms and Signs in Pulmonary
Embolism
DiaphoresisS3 or S4 gal opThrombophlebitis Laboratory abnormalities are nonspecific and
include leukocytosis, an increase in the erythrocyte
sedimentation rate (ESR), and an elevated serum
LDH or AST (SGOT) with a normal serum bilirubin.
Arterial blood gases usually reveal hypoxemia,
hypocapnia, and respiratory alkalosis.
A. Massive pulmonary embolus with hypotension and
respiratory collapse can lead to hypercapnia and acombined respiratory and metabolic acidosis. Addi-tionally, the PaO is between 85 and 105 mm Hg in 18 percent of patients with pulmonary embolism, and upto 6 percent may have a normal alveolar-arterialgradient for oxygen. Arterial blood gas measurementsdo not play a major role in excluding or establishingthe diagnosis of pulmonary embolism.
B. Serum troponin I and troponin T are elevated in 30
to 50 percent of patients with a moderate to largepulmonary embolism because of acute right heartoverload. Although not useful for diagnosis, elevatedtroponins are predictive of an adverse prognosis,being associated with marked increases in the inci-dence of prolonged hypotension and in-hospitalmortality.
C. Electrocardiography is often abnormal (70 percent);
however, the findings are insensitive and nonspecific.
The most common abnormalities are nonspecific STsegment and T wave changes (49 percent). The presence of T-wave inversion in the precordial leadsmay correlate with more severe right ventriculardysfunction.
D. Chest radiography. The most frequent radiographic
abnormalities are atelectasis, observed in 69 percentof pulmonary emboli. Pleural effusion is noted in 47percent.
IV. Diagnostic evaluation
A. Ventilation/perfusion lung scanning is the most
frequently used test to aid in the diagnosis of PE inpatients in whom a careful physical examination androutine diagnostic tests have failed to reveal a specificdiagnosis to explain the pulmonary symptoms.
B. A high probability lung scan indicates a high likelihood
of emboli, particularly in patients with a high pretestprobability of pulmonary emboli (95 percent). Highprobability lung scans, however, are not very sensitivefor PE (42 percent sensitivity). The majority of pulmo-nary emboli produce lung scan defects that areintermediate (41 percent of emboli) or low probability(16 percent).
C. Noninvasive lower extremity tests. Noninvasive
assessment for deep venous thrombosis may behelpful in the evaluation of patients with intermediateclinical and scan probabilities for pulmonary emboli.
Color-flow Doppler with compression ultrasound hashigh sensitivity (89 to 100 percent) and specificity (89to 100 percent) for the detection of a first episode ofproximal venous thrombosis.
D. D-dimers are detectable at levels greater than 500
ng/mL in nearly all patients with PE. However, anelevated D-dimer concentration is insufficient toestablish the diagnosis of PE because such valuesare nonspecific and are commonly present in hospital-ized patients, particularly those with malignancy orrecent surgery.
E. Pulmonary angiography. Many patients require
angiography to confirm or exclude PE with certainty.
Angiography is the definitive diagnostic technique. Anegative pulmonary angiogram with magnificationexcludes clinically relevant pulmonary embolism.
F. Helical CT scanning. Initial reports suggested that
the technique had a very high sensitivity, but subse-quent studies found sensitivities ranging from 53 to 87percent.
Pretest Probability of Pulmonary Embolism
High probability - 90 percent
Presence of at least one of three symptoms (sud-den onset dyspnea, chest pain, fainting) not other-wise explained and associated with: (1) any two ofthe following abnormalities: electrocardiographicsigns of right ventricular overload, radiographicsigns of oligemia, amputation of a hilar artery, orpulmonary consolidation compatible with infarction;(2) any one of the above three radiographic abnor-malities.
Intermediate probability - 50 percent
Presence of at least one of the above symptoms,not explained otherwise, but not associated withthe above electrocardiographic and radiographicabnormalities, or associated withelectrocardiographic signs of right ventricular over-load only.
Low probability - 10 percent
Absence of the above three symptoms, or identifi-cation of an alternative diagnosis that may accountfor their presence (eg, exacerbation of COPD,pneumonia, lung edema, myocardial infarction,pneumothorax, and others) V. Recommendations. The combination of clinical as-
sessment, lung scanning, D-dimer testing, and venous
ultrasound will confirm or exclude acute pulmonary
emboli in many patients.
A. In patients with suspected pulmonary embolism and
leg symptoms, initial testing with venousultrasonography should be considered.
B. Anticoagulation can be safely withheld from patients
with a low pretest clinical probability and a negativeD-dimer.
C. Anticoagulation also can be safely withheld from
patients with low or moderate pretest clinical proba-bility, a non-high probability lung scan, and eithernegative serial venous ultrasounds or a negative D-dimer.
Weight-based nomogram for intravenous heparin
infusion
80 U/kg bolus, then 18 U/kg perhour 80 U/kg bolus, then increase infu- (<1.2 x control) sion rate by 4 U/kg per hour 40 U/kg per hour, then increaseinfusion by 2 U/kg per hour Decrease infusion rate by 2q U/kgper hour Hold infusion 1 hour, then de-crease infusion rate by 3 U/kg perhour *aPTT = activated partial thromboplastin time Asthma is the most common chronic disease amongchildren. Asthma triggers include viral infections; environ-mental pollutants, such as tobacco smoke; aspirin,nonsteroidal anti-inflammatory drugs, and sustainedexercise, particularly in cold environments.
I. Diagnosis
A. Symptoms of asthma may include episodic com-
plaints of breathing difficulties, seasonal or nighttimecough, prolonged shortness of breath after a respira-tory infection, or difficulty sustaining exercise.
B. Wheezing does not always represent asthma.
Wheezing may persist for weeks after an acutebronchitis episode. Patients with chronic obstructivepulmonary disease may have a reversible componentsuperimposed on their fixed obstruction. Etiologicclues include a personal history of allergic disease,such as rhinitis or atopic dermatitis, and a familyhistory of allergic disease. C. The frequency of daytime and nighttime symptoms,
duration of exacerbations and asthma triggers shouldbe assessed.
D. Physical examination. Hyperventilation, use of
accessory muscles of respiration, audible wheezing,and a prolonged expiratory phase are common.
Increased nasal secretions or congestion, polyps, andeczema may be present.
E. Measurement of lung function. An increase in the
forced expiratory volume in one second (FEV ) of 12% after treatment with an inhaled beta agonist is sufficient to make the diagnosis of asthma. A 12%change in peak expiratory flow rate (PEFR) measuredon a peak-flow meter is also diagnostic.
II. Treatment of asthma
A. Beta agonists
1. Inhaled short-acting beta -adrenergic agonists are
the most effective drugs available for treatment ofacute bronchospasm and for prevention ofexercise-induced asthma. Levalbuterol (Xopenex),the R-isomer of racemic albuterol, offers no signifi-cant advantage over racemic albuterol.
2. Salmeterol (Serevent), a long-acting beta agonist,
has a relatively slow onset of action and a pro-
longed effect.
a. Salmeterol should not be used in the treatment
of acute bronchospasm. Patients takingsalmeterol should use a short-acting beta2 agonist as needed to control acute symptoms.
Twice-daily inhalation of salmeterol has beeneffective for maintenance treatment in combina-tion with inhaled corticosteroids. b. Fluticasone/Salmeterol (Advair Diskus) is a
long-acting beta agonist and corticosteroidcombination; dry-powder inhaler [100, 250 or500 g/puff],1 puff q12h.
3. Formoterol (Foradil) is a long-acting beta2 agonist
like salmeterol. It should only be used in patientswho already take an inhaled corticosteroid. Patientstaking formoterol should use a short-acting beta2 agonist as needed to control acute symptoms. Formaintenance treatment of asthma in adults andchildren at least 5 years old, the recommendeddosage is 1 puff bid. 4. Adverse effects of beta agonists. Tachycardia,
palpitations, tremor and paradoxical bronchospasmcan occur. High doses can cause hypokalemia.
Drugs for Asthma
Inhaled beta -adrenergic agonists, short-acting
Ventolin NebulesVentolin Inhaled beta2-adrenergic agonist, long-acting
1 inhalation q12h dry-powder in-haler (50μg/inhalation) haler (100, 250 or haler (50, 100 or250 μg/inhalation) 2 puffs tid-qid or 4 Mast Cell Stabilizers
2-4 puffs tid-qid inhaler (800μg/puff) 2-4 puffs bid-qid inhaler (1.75mg/puff) Theophylline
Slo-Bid Gyrocaps,
capsules or tab-lets B. Inhaled corticosteroids
1. Regular use of an inhaled corticosteroid can
suppress inflammation, decrease bronchialhyperresponsiveness and decrease symptoms.
Inhaled corticosteroids are recommended formost patients.
2. Adverse effects. Inhaled corticosteroids are
usually free of toxicity. Dose-dependent slowingof linear growth may occur within 6-12 weeks insome children. Decreased bone density, glau- coma and cataract formation have been re-ported. Churg-Strauss vasculitis has been re-ported rarely. Dysphonia and oral candidiasiscan occur. The use of a spacer device andrinsing the mouth after inhalation decreases theincidence of candidiasis.
C. Leukotriene modifiers
1. Leukotrienes increase production of mucus and
edema of the airway wall, and may causebronchoconstriction. Montelukast and zafirlukastare leukotriene receptor antagonists. Zileutoninhibits synthesis of leukotrienes.
2. Montelukast (Singulair) is modestly effective
for maintenance treatment of intermittent orpersistent asthma. It is taken once daily in theevening. It is less effective than inhaledcorticosteroids, but addition of montelukast maypermit a reduction in corticosteroid dosage.
Montelukast added to oral or inhaledcorticosteroids can improve symptoms.
3. Zafirlukast (Accolate) is modestly effective for
maintenance treatment of mild-to-moderateasthma It is less effective than inhaledcorticosteroids. Taking zafirlukast with foodmarkedly decreases its bioavailability.
Theophylline can decrease its effect. Zafirlukastincreases serum concentrations of oral anticoag-ulants and may cause bleeding. Infrequentadverse effects include mild headache, gastroin-testinal disturbances and increased serumaminotransferase activity. Drug-induced lupusand Churg-Strauss vasculitis have been re-ported.
4. Zileuton (Zyflo) is modestly effective for mainte-
nance treatment, but it is taken four times a dayand patients must be monitored for hepatictoxicity.
D. Cromolyn (Intal) and nedocromil (Tilade)
1. Cromolyn sodium, an inhibitor of mast cell
degranulation, can decrease airwayhyperresponsiveness in some patients withasthma. The drug has no bronchodilating activityand is useful only for prophylaxis. Cromolyn hasvirtually no systemic toxicity.
2. Nedocromil has similar effects as cromolyn. Both
cromolyn and nedocromil are much less effectivethan inhaled corticosteroids.
1. Oral theophylline has a slower onset of action
than inhaled beta agonists and has limited usefulness for treatment of acute symptoms. Itcan, however, reduce the frequency and severityof symptoms, especially in nocturnal asthma, andcan decrease inhaled corticosteroid require-ments.
2. When theophylline is used alone, serum concen-
trations between 8-12 mcg/mL provide a modestimprovement is FEV . Serum levels of 15-20 mcg/mL are only minimally more effective andare associated with a higher incidence of cardio-vascular adverse events.
F. Oral corticosteroids are the most effective drugs
available for acute exacerbations of asthma unre-
sponsive to bronchodilators.
1. Oral corticosteroids decrease symptoms and
may prevent an early relapse. Chronic use of oralcorticosteroids can cause glucose intolerance,weight gain, increased blood pressure, osteopo-rosis, cataracts, immunosuppression and de-creased growth in children. Alternate-day use ofcorticosteroids can decrease the incidence ofadverse effects, but not of osteoporosis.
methylprednisolone (Solu-Medrol), 40-60 mg
qd; for children, 1-2 mg/kg/day to a maximum of
60 mg/day. Therapy is continued for 3-10 days.
The oral steroid dosage does not need to be
tapered after short-course "burst" therapy if the
patient is receiving inhaled steroid therapy.
Pharmacotherapy for Asthma Based on Disease
Classification
Short-acting beta2 agonist as needed Short-acting beta2 corticosteroid or agonist as needed cromolyn sodium (Intal)or nedocromil (Tilade) Medium-dose inhaled Short-acting beta2 corticosteroid plus a agonist as needed long-actingbronchodilator (long-acting beta agonist) High-dose inhaled Short-acting beta2 corticosteroid plus a agonist as needed long-actingbronchodilator and sys-temic corticosteroid III. Management of acute exacerbations
A. High-dose, short-acting beta agonists delivered by
a metered-dose inhaler with a volume spacer or viaa nebulizer remains the mainstay of urgent treat-ment.
B. Most patients require therapy with systemic
corticosteroids to resolve symptoms and preventrelapse. Hospitalization should be considered if thePEFR remains less than 70% of predicted. Patientswith a PEFR less than 50% of predicted who exhibitan increasing pCO level and declining mental status are candidates for intubation.
C. Non-invasive ventilation with bilevel positive airway
pressure (BIPAP) may be used to relieve the work-of-breathing while awaiting the effects of acutetreatment, provided that consciousness and theability to protect the airway have not been compro-mised.
Chronic obstructive pulmonary disease (COPD) is the mostcommon cause of death in the United States and currentlykills more than 100,000 Americans each year. COPD ischaracterized by airflow limitation that is not fully reversible.
Airflow limitation is usually both progressive and associatedwith an abnormal inflammatory response of the lungs tonoxious particles or gases.
A. Airflow obstruction is the result of both small airway
disease (obstructive bronchiolitis) and parenchymaldestruction (emphysema). Airflow obstruction can beaccompanied by partially reversible airwayshyperreactivity.
B. Alpha-1 antitrypsin (AAT) deficiency is the only
genetic abnormality that predisposes to lung diseasesimilar to COPD. Severe AAT deficiency has a fre-quency of about 1 in 3,000 live births. These individu-als may have liver disease in infancy or in old age, orthey may develop AAT-COPD in their thirties orforties, especially if they smoke. About 2 percent ofpatients with COPD or sustained asthma may havesevere AAT deficiency. Persons with known COPD, orasthma with non-remittent airflow obstruction shouldbe screened for AAT deficiency.
A. Patients with COPD have usually been smoking at
least 20 cigarettes per day for 20 or more yearsbefore symptoms develop. Chronic productive cough,sometimes with wheezing, often begins when patientsare in their forties.
B. Dyspnea on effort does not usually begin until the mid
sixties or early seventies. Sputum production initiallyoccurs only in the morning. Sputum is usually mucoidbut becomes purulent with an exacerbation. Acutechest illnesses may occur intermittently, and arecharacterized by increased cough, purulent sputum,wheezing, dyspnea, and occasionally fever.
C. Late in the course of the illness, an exacerbation may
cause hypoxemia with cyanosis. Associated findings
also include:
1. Weight loss.
2. Hypercapnia with more severe hypoxemia in the
setting of end-stage disease.
Morning headache, which suggests hypercapnia.
3. Cor pulmonale with right heart failure and edema.
These abnormalities can develop in patients withhypoxemia and hypercapnia.
D. Physical examination of the chest early in the
disease may show only prolonged expiration andwheezes on forced exhalation. As obstruction pro-gresses, hyperinflation becomes evident, and theanteroposterior diameter of the chest increases. Thediaphragm is depressed. Breath sounds are de-creased and heart sounds become distant. Coarsecrackles may be heard at the lung bases. Wheezesare frequently heard.
1. Patients with end-stage COPD may lean forward
with arms outstretched and weight supported on
the palms. Other signs in a patient with end-stage
disease may include:
a. The full use of the accessory respiratory mus-
cles of the neck and shoulder girdle.
b. Expiration through pursed lips.
c. Paradoxical retraction of the lower interspaces
during inspiration (Hoover's sign).
d. Cyanosis.
e. An enlarged, tender liver secondary to right
heart failure.
f. Asterixis due to severe hypercapnia.
E. Plain chest radiography. Emphysema is character-
ized by over distention of the lungs as indicated onfrontal chest radiographs by a low, flat diaphragm anda long, narrow heart shadow. Flattening of the dia-phragmatic contour and an increased retrosternalairspace are present on the lateral projection. Rapidtapering of the vascular shadows accompanied byhypertransradiancy of the lungs is a sign of emphy-sema. Bullae, presenting as radiolucent areas largerthan one centimeter in diameter and surrounded byarcuate hairline shadows, are proof of emphysema.
F. Pulmonary function tests are necessary for diagnos-
ing and assessing the severity of airflow obstruction,and are helpful in following its progress. The FEV has less variability than other measurements of airwaysdynamics. In the mildest degree of airflow obstruction,the FEV /FVC ratio falls below 0.70 and the FEV percent predicted is normal. Up to 30 percent ofpatients have an increase of 15 percent or more intheir FEV following inhalation of a beta-agonist.
G. Arterial blood gases reveal mild or moderate
hypoxemia without hypercapnia in the early stages. Asthe disease progresses, hypoxemia becomes moresevere and hypercapnia supervenes. The frequencyof erythrocytosis increases as arterial PO falls below H. Sputum examination. In stable chronic bronchitis,
sputum is mucoid. During an exacerbation, sputumusually becomes purulent with an influx of neutrophils.
The Gram stain usually shows a mixture of organisms.
The most frequent pathogens cultured from thesputum are Streptococcus pneumoniae andHaemophilus influenzae.
Diagnosis of chronic obstructive pulmonary dis-
ease (COPD)
Age at initiationAverage amount smoked per dayDate when stopped smoking or a current smoker Chronic productive cough for at least one quarterof the year for two successive years is the definingcharacteristic of chronic bronchitis. Sputum, bloodor blood streaking in the sputum.
WheezingAcute chest illnesses Frequency of episodes of increased cough andsputum with wheezing.
Amount of effort required to induce uncomfortablebreathing.
The presence of severe emphysema is indicatedby: overdistention of the lungs in the stable posi-tion; decreased intensity of breath and heartsounds and prolonged expiratory phase.
Wheezes during auscultation on slow or forcedbreathing and prolongation of forced expiratorytime.
Severe disease is indicated by pursed-lip breath-ing, use of accessory respiratory muscles, retrac-tion of lower interspaces.
OtherUnusual positions to relieve dyspnea at rest.
Digital clubbing suggests the possibility of lungcancer or bronchiectasis.
Mild dependent edema may be seen in the absenceof right heart failure.
Differential diagnosis of COPD
Onset in mid-lifeSymptoms slowly progressiveLong smoking historyDyspnea during exerciseLargely irreversible airflow limitation Onset in childhoodSymptoms vary from day to daySymptoms at night/early morningAllergy, rhinitis, and/or eczema alsopresentFamily history of asthmaLargely reversible airflow limitation Fine basilar cracklesChest X-ray shows dilated heart,pulmonary edemaPulmonary function tests indicatevolume restriction, not airflow limita-tion Large volumes of purulent sputum Commonly associated with bacterialinfectionCoarse crackles/clubbing onauscultationChest X-ray/CT shows bronchialdilation, bronchial wall thickening Chest X-ray shows lung infiltrateMicrobiological confirmationHigh local prevalence of tuberculosis Onset in younger age, nonsmokers May have history of rheumatoid ar-thritis or fume exposureCT on expiration shows hypodenseareas Most patients are male and non- smokers. Almost all have chronic sinusitisChest X-ray and HRCT show diffusesmall centrilobular nodular opacitiesand hyperinflation Classification of Severity of Chronic Obstructive
Pulmonary Disease
Normal spirometryChronic symptoms (cough, sputumproduction) FEV /FVC <70 percent FEV >80 percent predicted With or without chronic symptoms(cough, sputum production) FEV /FVC <70 percent 30 percent <FEV1 <80 percent pre-dicted IIA: 50 percent <FEV1 <80 percentpredictedIIB: 30 percent <FEV1 <50 percentpredicted FEV /FVC <70 percent FEV 30 percent predicted or FEV predicted plus respiratory failure orclinical signs of right heart failure Management of Acute Exacerbations of Chronic
Obstructive Pulmonary Disease
A. Criteria for hospital admission. Acute respiratory
acidemia and/or worsening hypoxemia justify hospital-ization. Specific risk factors for relapse after emer-gency room (ER) discharge include a prior ER visitwithin one week, a greater number of doses ofnebulized bronchodilator required during the ER visit,use of supplemental oxygen at home, prior relapseafter an ER visit, use of aminophylline in the ER, andthe use of corticosteroids and/or antibiotics.
B. Pharmacologic treatment
1. Inhaled beta-adrenergic agonists, such as
albuterol, are the mainstay of therapy for an acuteexacerbation of COPD because of their rapid onsetof action and efficacy in producing bronchodilation.
2. Typical doses of albuterol are 180 mcg (two puffs)
by metered dose inhaler, or 500 mcg by nebulizer,given every one to two hours.
3. Anticholinergic bronchodilators, such as
ipratropium bromide, may be used in combination
with beta-adrenergic agonists to produce
bronchodilation in excess of that achieved by either
agent alone.
a. Ipratropium may be administered during acute
exacerbations either by nebulizer (500 mcgevery two to four hours), or via MDI (two puffs[36 mcg] every two to four hours with a spacer).
Glycopyrrolate is available for nebulized use inCOPD (1 to 2 mg every two to four hours).
4. Parenteral corticosteroids are frequently used for
acute exacerbations of COPD. Methylprednisolone(60 to 125 mg intravenously, two to four timesdaily) commonly is given.
5. Antibiotics are recommended for acute exacerba-
tions of COPD characterized by increased volumeand purulence of secretions. A 10-day course ofamoxicillin, doxycycline, or trimethoprim-sulfamethoxazole should be prescribed.
Choice of empirical antibiotic therapy for COPD
exacerbation
First-line treatment
Amoxicillin (Amoxil, Trimox, 1 tablet (80/400 mg) bid ole (Bactrim, Cotrim, Septra) Second-line treatment**
Amoxicillin and clavulanate Second- or third-generationcephalosporin (eg, cefuroxime [Ceftin]) Macrolides
Clarithromycin (Biaxin) 500 mg on day 1, then 250 Azithromycin (Zithromax) Quinolones
Ciprofloxacin (Cipro) Levofloxacin (Levaquin)*** *May need adjustment in patients with renal or hepatic insuffi-ciency. **For patients in whom first-line therapy has failed and thosewith moderate to severe disease or resistant orgram-negative pathogens. ***Although the newer quinolones have better activity againstStreptococcus pneumoniae, ciprofloxacin may be preferablein patients with gram-negative organisms. 6. Methylxanthines. Aminophylline and theophylline
are not recommended for the management of acuteexacerbations of COPD.
C. Oxygen therapy
1. Supplemental oxygen should achieve a target
PaO of 60 to 65 mm Hg, with a hemoglobin satura- tion exceeding 90 percent.
2. Venturi masks are the preferred means of oxygen
delivery because they permit a precise deliveredfraction of inspired oxygen (FiO ).
3. Nasal cannulae can provide flow rates up to 6
L/min with an associated FiO of approximately 44 percent. Nasal cannulae are also more comfortablefor the patient and permit oral feedings.
4. Facemasks can be used when higher inspired
concentrations of oxygen are needed. Simplefacemasks using flow rates of 6 to 10 L/min providean FiO up to 55 percent.
5. Non-rebreather masks with a reservoir, one-way
valves, and a tight face seal can deliver an inspiredoxygen concentration up to 90 percent.
D. Mechanical ventilation. Patients with life-threatening
respiratory failure require ventilatory assistance.
1. Noninvasive positive pressure ventilation (NIPPV)
is effective and less morbid than intubation for
selected patients with acute exacerbations of
COPD. Early use of NIPPV is recommended when
each of the following is present:
a. Respiratory distress with moderate-to-severe
b. pH less than 7.35 or PaCO above 45 mm Hg.
c. Respiratory rate of 25/minute or greater.
2. NIPPV is contraindicated in the presence of cardio-
vascular instability (eg, hypotension, seriousdysrhythmias, myocardial ischemia), craniofacialtrauma or burns, inability to protect the airway, orwhen indications for emergent intubation arepresent. Approximately 26 to 31 percent of patientsinitially treated with NIPPV ultimately requireintubation and mechanical ventilation.
IV. Management of Stable Chronic Obstructive Pul-
monary Disease (COPD).
A. Determination of FEV and FVC by spirometry is the
only reliable method of detecting mild airflow limitationand is therefore mandatory for all adults with a historyof cigarette smoking. Spirometry is useful to monitorthe course of the disease. A plain chest radiograph isindicated to exclude the presence of other disordersassociated with airflow limitation.
B. Bronchodilators. Bronchodilators can improve
symptoms and reduce airflow limitation in patients with
COPD. Use of a metered dose inhaler (MDI) results in
a bronchodilator response equivalent to that of a
nebulizer. Nebulizer therapy may still be necessary if
dyspnea and severe bronchospasm during impair
proper MDI technique.
1. Selective beta-2 agonists are the
sympathomimetic agents of choice. Beta-2 agonistscan cause tremor and a reflex tachycardia.
Hypokalemia can also occur and should be moni-tored in patients at risk. Scheduled use of short-acting beta-2 agonists, such as albuterol, does notoffer advantages over as-needed use.
C. Anticholinergic bronchodilators, such as inhaled
ipratropium, are first-line treatments for COPD. The
long-acting inhaled anticholinergic agent, tiotropium,
confers longer bronchodilation than ipratropium and
lessens the frequency of acute exacerbations in
patients with moderate COPD. The effects of
anticholinergics and beta-2 agonists are additive.
Combination therapy may be simplified with a metered
dose inhaler that delivers a combination of ipratropium
and albuterol.
1. The recommended dose of ipratropium (2 puffs qid)
is suboptimal; higher doses (3 to 6 puffs) provideadditional benefit without significant side effects.
Therapy at each stage of COPD
Avoidance of riskfactor(s)Influenza vacci-nation 0: At risk
Chronic symp-toms (cough, Exposure to riskfactor(s) I: Mild COPD
cent predictedwith or withoutsymptoms II: Moderate
<FEV <80 per- <FEV <50 per- cent predicted or right heart fail- symptoms andlung function re-sponse or if re-peated exacer-bationsTreatment ofcomplicationsRehabilitationLong-term oxy-gen therapy ifrespiratory failureSurgical treat-ments D. Theophylline provides clear benefits to some patients
with COPD. Theophylline decreases dyspnea andimproves arterial blood gases, FEV , FVC, and respi- ratory muscle function. Theophylline also has pulmo-nary vasodilator and cardiac inotropic effects. Patientswith COPD can be adequately treated with serumlevels in the 8 to 12 mcg/mL range. A long-actingpreparation at night may reduce the nocturnaldyspnea.
E. Supplemental oxygen
1. Arterial blood gases or pulse oximetry is useful for
detecting hypoxemia and hypercapnia. Oxygentherapy in ambulatory outpatients has physiologicand symptomatic benefits and prolongs life.
2. Noninvasive ventilatory support may be utilized in
the treatment of acute and chronic respiratoryinsufficiency.
F. Corticosteroids. Twenty percent of stable patients
with COPD demonstrate objective improvement inairflow with oral corticosteroids. Chronic steroidtherapy should be considered only in patients whohave continued symptoms despite maximal therapywith other agents. Only patients with documentedimprovement in airflow during a trial should be consid-ered for long-term therapy. Alternate day or inhaledsteroids should be considered in steroid-respondingpatients.
G. Prevention and treatment of infection.
Pneumococcal vaccination is recommended for all
patients with COPD, with revaccination after more
than five years for those at risk for significant declines
in immune function.
1. Annual influenza vaccine is recommended in
patients with COPD.
2. Antiviral agents should be considered in
nonimmunized patients at high risk for contractinginfluenza.
3. Antibiotics have been shown to be beneficial in the
treatment of acute infectious exacerbations ofCOPD. Examination of the sputum gram stain forpurulence may be of help in determining the needfor antibiotics.
H. Surgical management
1. Lung volume reduction surgery (LVRS) is rec-
ommended in patients with upper lobe predominantdisease and low exercise capacity.
2. Indications for lung transplantation
a. FEV is <25 percent of predicted,
b. PaCO is >55 mm Hg (7.3 kPa),
c. Cor pulmonale is present.
d. Candidates must be under 65 years of age, not
have dysfunction of major organs other than the lung, and not have active or recent malignancyor infection with HIV, hepatitis B, or hepatitis Cviruses.
I. Indications. The indication for diagnostic thoracentesis
is the new finding of a pleural effusion.
A. Pre-thoracentesis chest x-ray: A bilateral
decubitus x-ray should be obtained before thethoracentesis. Thoracentesis is safe when fluidfreely layers out and is greater than 10 mm in depthon the decubitus film.
B. Labs: CBC, ABG, SMA 12, protein, albumin, amy-
lase, rheumatoid factor, ANA, ESR. INR/PTT, UA.
Chest x-ray PA & LAT repeat after thoracentesis,bilateral decubitus, ECG.
C. Pleural fluid analysis:
1. Tube 1. LDH, protein, amylase, triglyceride,
glucose (10 mL).
2. Tube 2. Gram stain, C&S, AFB, fungal C&S, (20-
60 mL, heparinized).
3. Tube 3. Cell count and differential (5-10 mL,
4. Tube 4. Antigen tests for S. pneumoniae, H.
influenza (25-50 mL, heparinized).
5. Syringe. pH (2 mL collected anaerobically,
heparinized on ice).
6. Bottle. Cytology.
II. Separation of transudates and exudates
A. Transudates. Transudates are largely caused by
imbalances in hydrostatic and oncotic pressures inthe chest. However, they can also result from move-ment of fluid from the peritoneal or retroperitonealspaces, or from iatrogenic causes, such ascrystalloid infusion into a central venous catheterthat has migrated.
B. Exudates. Exudative pleural effusions are caused
by infection, malignancy, immunologic responses,lymphatic abnormalities, noninfectious inflammation,iatrogenic causes, and movement of fluid from belowthe diaphragm. Exudates result from pleural andlung inflammation or from impaired lymphatic drain-age of the pleural space. Exudates can also resultfrom movement of fluid from the peritoneal space, asseen with pancreatitis, chylous ascites, andperitoneal carcinomatosis.
Diagnoses that can be established definitively by
pleural fluid analysis
Diagnostic pleural fluid test
Observation (pus, putrid odor); cul-ture Positive cytology LE cells present; pleural fluid se-rum ANA >1.0 Tuberculous pleurisy Positive AFB stain, culture Esophageal rupture High salivary amylase, pleural fluidacidosis (often as low as 6.00) Positive KOH stain, culture Triglycerides (>110 mg/dL); lipopro-tein electrophoresis (chylomicrons) Hematocrit (pleural fluid/blood>0.5) Creatinine (pleural fluid/serum>1.0) Diagnostic pleural fluid test
Peritoneal dialysis Protein (<1g/dL); glucose (300 to400 mg/dL) Extravascular migra- Observation (milky if lipids are in- tion of central venous fused); pleural fluid/serum glucose Rheumatoid pleurisy Characteristic cytology C. Diagnostic criteria. The most practical method of
separating transudates and exudates is measure-
ment of serum and pleural fluid protein and LDH. If
at least one of the following three criteria is present,
the fluid is virtually always an exudate; if none is
present, the fluid is virtually always a transudate:
1. Pleural fluid protein/serum protein ratio greater
2. Pleural fluid LDH/serum LDH ratio greater than
3. Pleural fluid LDH greater than two thirds the
upper limits of normal of the serum LDH.
Causes of Transudative Pleural Effusions
Effusion always transudative
Congestive heart failure Hepatic hydrothorax Nephrotic syndrome Peritoneal dialysis Superior vena caval obstruc-tion Classic exudates that can be transudates
Pulmonary embolism Hypothyroid pleural effusion D. An exudate is best determined by any one of
the following:
1. Pleural fluid protein >2.9 g/dL
2. Pleural fluid cholesterol >45 mg/dL
3. Pleural fluid LDH >60 percent of upper limits of
normal serum value Causes of exudative pleural effusions
Bacterial pneumonia Tuberculous pleurisy Cholesterol effusion Atypical pneumonia(viral, mycoplasma)Nocardia, ActinomycesSubphrenic abscessHepatic abscessSplenic abscessHepatitisSpontaneous esopha-geal rupture Esophageal perforation hyperstimulation syn- Central venous cathetermisplacement/migrationEnteral feeding tube inpleural space Yel ow nail syndrome Paraproteinemia (multi- Other inflammatory disor-
Movement of fluid from ab-
domen to pleural space
Pancreatitis (acute, Pancreatic pseudocyst Benign asbestos pleural Pulmonary embolism Radiation therapy Subphrenic abscess Hepatic abscess (bac- Postcardiac injury syn- Splenic abscess, infarc- III. Chemical analysis
A. Pleural fluid protein and LDH
1. Most transudates have absolute total protein
concentrations below 3.0 g/dL; however, acutediuresis in congestive heart failure can elevateprotein levels into the exudative range.
2. Tuberculous pleural effusions virtually always
have total protein concentrations above 4.0 g/dL.
When pleural fluid protein concentrations are inthe 7.0 to 8.0 g/dL range, Waldenstrom'smacroglobulinemia and multiple myeloma shouldbe considered.
3. Pleural fluid LDH levels above 1000 IU/L are
found in empyema, rheumatoid pleurisy, andpleural paragonimiasis, and are sometimesobserved with malignancy. Pleural fluid second-ary to Pneumocystis carinii pneumonia has apleural fluid/serum LDH ratio greater than 1.0 anda pleural fluid/serum protein ratio of less than 0.5.
B. Pleural fluid glucose. A low pleural fluid glucose
concentration (less than 60 mg/dL), or a pleural
fluid/serum glucose ratio less than 0.5) narrows the
differential diagnosis of the exudate to the following
possibilities:
1. Rheumatoid pleurisy
2. Complicated parapneumonic effusion or
3. Malignant effusion
4. Tuberculous pleurisy
5. Lupus pleuritis
6. Esophageal rupture
C. All transudates and all other exudates have pleural
fluid glucose concentrations similar to that of bloodglucose. The lowest glucose concentrations arefound in rheumatoid pleurisy and empyema, withglucose being undetectable in some cases. Incomparison, when the glucose concentration is lowin tuberculous pleurisy, lupus pleuritis, and malig-nancy, it usually falls into the range of 30 to 50mg/dL.
D. Pleural fluid pH. Pleural fluid pH should always be
measured in a blood gas machine. A pleural fluid pHbelow 7.30 with a normal arterial blood pH is foundwith the same diagnoses associated with low pleuralfluid glucose concentrations. The pH of normalpleural fluid is approximately 7.60. Transudateshave a pleural fluid pH in the 7.40 to 7.55 range,while the majority of exudates range from 7.30 to7.45.
E. Pleural fluid amylase. The finding of an amy-
lase-rich pleural effusion, defined as either a pleural
fluid amylase greater than the upper limits of normal
for serum amylase or a pleural fluid to serum amy-
lase ratio greater than 1.0, narrows the differential
diagnosis of an exudative effusion to the following
major possibilities:
1. Acute pancreatitis
2. Chronic pancreatic pleural effusion
3. Esophageal rupture
4. Malignancy
5. Other rare causes of an amylase-rich pleural
effusion include pneumonia, ruptured ectopicpregnancy, hydronephrosis, and cirrhosis. Pan-creatic disease is associated with pancreaticisoenzymes, while malignancy and esophagealrupture are characterized by a predominance ofsalivary isoenzymes.
IV. Pleural fluid nucleated cells
A. Counts above 50,000/μL are usually found only in
complicated parapneumonic effusions, includingempyema.
B. Exudative effusions from bacterial pneumonia, acute
pancreatitis, and lupus pleuritis usually have totalnucleated cell counts above 10,000/μL C. Chronic exudates, typified by tuberculous pleurisy
and malignancy, typically have nucleated cell countsbelow 5000/μL.
D. Pleural fluid lymphocytosis. Pleural fluid
lymphocytosis, particularly with lymphocyte countsrepresenting 85 to 95 percent of the total nucleatedcells, suggests tuberculous pleurisy, lymphoma,sarcoidosis, chronic rheumatoid pleurisy, yellow nailsyndrome, or chylothorax. Carcinomatous pleuraleffusions will be lymphocyte predominant in overone-half of cases; however, the percentage oflymphocytes is usually between 50 and 70 percent.
E. Pleural fluid eosinophilia. Pleural fluid
eosinophilia (pleural fluid eosinophils representing
more than 10 percent of the total nucleated cells)
usually suggests a benign, self-limited disease, and
is commonly associated with air or blood in the
pleural space. The differential diagnosis of pleural
fluid eosinophilia includes:
1. Pneumothorax
2. Hemothorax
3. Pulmonary infarction
4. Benign asbestos pleural effusion
5. Parasitic disease
6. Fungal infection (coccidioidomycosis,
7. Drugs
8. Malignancy (carcinoma, lymphoma)
9. Pleural fluid eosinophilia appears to be rare with
tuberculous pleurisy on the initial thoracentesis F. Mesothelial cells are found in small numbers in
normal pleural fluid, are prominent in transudativepleural effusions, and are variable in exudativeeffusions. Tuberculosis is unlikely if there are morethan five percent mesothelial cells.
G. Treatment: Chest tube drainage is indicated for
complicated parapneumonic effusions (pH <7.10,glucose <40 mEq/dL, LDH >1000 IU/L) and frankempyema.
References: See page 168.
Blanding U. Jones, MD I. Management of pneumothorax
A. Small primary spontaneous pneumothorax (<10-
15%): (not associated with underlying pulmonary
diseases). If the patient is not dyspneic
1. Observe for 4-8 hours and repeat a chest x-ray.
2. If the pneumothorax does not increase in size and
the patient remains asymptomatic, consider dis-charge home with instructions to rest and curtail allstrenuous activities. The patient should return ifthere is an increase in dyspnea or recurrence ofchest pain.
B. Secondary spontaneous pneumothorax (associ-
ated with underlying pulmonary pathology, em-
physema) or primary spontaneous pneumothorax
>15%, or if patient is symptomatic.
1. Give high-flow oxygen by nasal cannula. A needle
thoracotomy should be placed at the anterior,second intercostal space in the midclavicular line.
2. Anesthetize and prep the area, then insert a 16-
gauge needle with an internal catheter and a 60mL syringe, attached via a 3-way stopcock. Aspi-rate until no more air is aspirated. If no additionalair can be aspirated, and the volume of aspiratedair is <4 liters, occlude the catheter and observefor 4 hours.
3. If symptoms abate and chest-x-ray does not show
recurrence of the pneumothorax, the catheter canbe removed, and the patient can be dischargedhome with instructions. 4. If the aspirated air is >4 liters and additional air is
aspirated without resistance, this represents anactive bronchopleural fistula with continued airleak. Admission is required for insertion of a chesttube.
C. Traumatic pneumothorax associated with a
penetrating injury, hemothorax, mechanical
ventilation, tension pneumothorax, or if
pneumothorax does not resolve after needle
aspiration: Give high- flow oxygen and insert a chest
tube. Do not delay the management of a tension
pneumothorax until radiographic confirmation; insert
needle thoracotomy or chest tube immediately.
D. Iatrogenic pneumothorax
1. Iatrogenic pneumothoraces include lung puncture
caused by thoracentesis or central line placement.
2. Administer oxygen by nasal cannula.
3. If the pneumothorax is less than 10% and the
patient is asymptomatic, observe and repeat
chest x-ray in 4 hours. If unchanged, manage
expectantly with close follow-up, and repeat chest
x-ray in 24 hours.
4. If the pneumothorax is more than 10% and/or
the patient is symptomatic, perform a tube
thoracostomy under negative pressure.
II. Technique of chest tube insertion
A. Place patient in supine position, with involved side
elevated 20 degrees. Abduct the arm to 90 degrees.
The usual site is the fourth or fifth intercostal space,between the mid-axillary and anterior axillary line(drainage of air or free fluid). The point at which theanterior axillary fold meets the chest wall is a usefulguide. Alternatively, the second or third intercostalspace, in the midclavicular line, may be used forpneumothorax drainage alone (air only).
B. Cleanse the skin with Betadine iodine solution, and
drape the field. Determine the intrathoracic tube distance (lateral chest wall to the apices), and markthe length of tube with a clamp. C. Infiltrate 1% lidocaine into the skin, subcutaneous
tissues, intercostal muscles, periosteum, and pleurausing a 25-gauge needle. Use a scalpel to make atransverse skin incision, 2 centimeters wide, locatedover the rib, just inferior to the interspace where thetube will penetrate the chest wall.
D. Use a Kelly clamp to bluntly dissect a subcutaneous
tunnel from the skin incision, extending just over thesuperior margin of the lower rib. Avoid the nerve,artery and vein located at the upper margin of theintercostal space.
E. Penetrate the pleura with the clamp, and open the
pleura 1 centimeter. With a gloved finger, explore thesubcutaneous tunnel, and palpate the lung medially.
Exclude possible abdominal penetration, and ensurecorrect location within pleural space; use finger toremove any local pleural adhesions. F. Use the Kelly clamp to grasp the tip of the
thoracostomy tube (36 F, internal diameter 12 mm),and direct it into the pleural space in a posterior,superior direction for pneumothorax evacuation.
Direct the tube inferiorly for pleural fluid removal.
Guide the tube into the pleural space until the lasthole is inside the pleural space and not inside thesubcutaneous tissue.
G. Attach the tube to a underwater seal apparatus
containing sterile normal saline, and adjust to 20 cmH O of negative pressure, or attach to suction if leak is severe. Suture the tube to the skin of the chest wallusing O silk. Apply Vaseline gauze, 4 x 4 gauzesponges, and elastic tape. Obtain a chest x-ray toverify correct placement and evaluate reexpansion ofthe lung.
I. Clinical evaluation
A. Clinical signs: Severe hemodynamic and/or respira-
tory compromise; contralaterally deviated trachea;decreased or absent breath sounds andhyperresonance to percussion on the affected side;jugular venous distention, asymmetrical chest wallmotion with respiration.
B. Radiologic signs: Flattening or inversion of the
ipsilateral hemidiaphragm; contralateral shifting ofthe mediastinum; flattening of the cardio-mediastinalcontour and spreading of the ribs on the ipsilateralside.
II. Acute management
A. A temporary large-bore IV catheter may be inserted
into the ipsilateral pleural space, at the level of thesecond intercostal space at the midclavicular lineuntil the chest tube is placed.
B. A chest tube should be placed emergently.
C. Draw blood for CBC, INR, PTT, type and cross-
matching, chem 7, toxicology screen.
D. Send pleural fluid for hematocrit, amylase and pH (to
rule out esophageal rupture).
E. Indications for cardiothoracic exploration: Severe
or persistent hemodynamic instability despite ag-gressive fluid resuscitation, persistent active bloodloss from chest tube, more than 200 cc/hr for 3consecutive hours, or >1 1/2 L of acute blood lossafter chest tube placement.
I. General considerations
A. Cardiac tamponade occurs most commonly second-
ary to penetrating injuries.
B. Beck's Triad: Venous pressure elevation, drop in
the arterial pressure, muffled heart sounds. Othersigns include enlarged cardiac silhouette on chest x-ray; signs and symptoms of hypovolemic shock;pulseless electrical activity, decreased voltage onECG.
C. Kussmaul's sign is characterized by a rise in venous
pressure with inspiration. Pulsus paradoxus orelevated venous pressure may be absent whenassociated with hypovolemia.
A. Pericardiocentesis is indicated if the patient is unre-
sponsive to resuscitation measures for hypovolemicshock, or if there is a high likelihood of injury to themyocardium or one of the great vessels.
B. All patients who have a positive pericardiocentesis
(recovery of non-clotting blood) because of trauma,require an open thoracotomy with inspection of themyocardium and the great vessels.
C. Rule out other causes of cardiac tamponade such as
pericarditis, penetration of central line through thevena cava, atrium, or ventricle, or infection.
D. Consider other causes of hemodynamic instability
that may mimic cardiac tamponade (tensionpneumothorax, massive pulmonary embolism, shocksecondary to massive hemothorax).
I. General considerations
A. If acute cardiac tamponade with hemodynamic
insta b ility is su sp e c te d , e m ergencypericardiocentesis should be performed; infusion ofRinger's lactate, crystalloid, colloid and/or blood mayprovide temporizing measures.
A. Protect airway and administer oxygen. If patient can
be stabilized, pericardiocentesis should be per-formed in the operating room or catheter lab. Thepara-xiphoid approach is used for pericardiocentesis.
B. Place patient in supine position with chest ele-
vated at 30-45 degrees, then cleanse and drapeperi-xiphoid area. Infiltrate lidocaine 1% with epi-nephrine (if time permits) into skin and deep tissues.
C. Attach a long, large bore (12-18 cm, 16-18 gauge),
short bevel cardiac needle to a 50 cc syringe with
a 3-way stop cock. Use an alligator clip to attach a V-
lead of the ECG to the metal of the needle.
D. Advance the needle just below costal margin,
immediately to the left and inferior to the xiphoidprocess. Apply suction to the syringe while advancingthe needle slowly at a 45 -degree horizontal angletowards the mid point of the left clavicle.
E. As the needle penetrates the pericardium, resis-
tance will be felt, and a "popping" sensation will benoted.
F. Monitor the ECG for ST segment elevation (indicat-
ing ventricular heart muscle contact); or PR segmentelevation (indicating atrial epicardial contact). Afterthe needle comes in contact with the epicardium,withdraw the needle slightly. Ectopic ventricular beatsare associated with cardiac penetration.
G. Aspirate as much blood as possible. Blood from the
pericardial space usually will not clot. Blood, inadver-tently, drawn from inside the ventricles or atriumusually will clot. If fluid is not obtained, redirect theneedle more towards the head. Stabilize the needleby attaching a hemostat or Kelly clamp.
H. Consider emergency thoracotomy to determine the
cause of hemopericardium (especially if activebleeding). If the patient does not improve, considerother problems that may resemble tamponade, suchas tension pneumothorax, pulmonary embolism, orshock secondary to massive hemothorax.
References: See page 168.
I. Acute hemolytic transfusion reaction
A. Transfusion reactions are rare and most commonly
associated with ABO incompatibility, usually relatedto a clerical error. Early symptoms include suddenonset of anxiety, flushing, tachycardia, andhypotension. Chest and back pain, fever, anddyspnea are common.
B. Life-threatening manifestations include vascular
collapse (shock), renal failure, bronchospasm, anddisseminated intravascular coagulation. C. Hemoglobinuria, and hemoglobinemia occurs be-
cause of intravascular red cell lysis.
D. The direct antiglobulin test (direct Coombs test) is
positive. The severity of reaction is usually related tothe volume of RBCs infused. 1. The transfusion should be discontinued immedi-
ately, and the unused donor blood and a sampleof recipient's venous blood should be sent forretyping and repeat cross match, including a directand indirect Coombs test.
2. Urine analysis should be checked for free hemo-
globin and centrifuged plasma for pink coloration(indicating free hemoglobin).
3. Hypotension should be treated with normal saline.
Vasopressors may be used if volume replacementalone is inadequate to maintain blood pressure.
4. Maintain adequate renal perfusion with volume
replacement. Furosemide may be used to main-tain urine output after adequate volume replace-ment has been achieved.
5. Monitor INR/PTT, platelets, fibrinogen, and fibrin
degradation products for evidence of dissemi-nated intravascular coagulation. Replace requiredclotting factors with fresh frozen plasma, platelets,and/or cryoprecipitate.
II. Febrile transfusion reaction (nonhemolytic)
A. Febrile transfusion reactions occur in 0.5-3% of
transfusions. It is most commonly seen in patientsreceiving multiple transfusions. Chills develop,followed by fever, usually during or within a few hoursof transfusion. This reaction may be severe but isusually mild and self limited.
1. Symptomatic and supportive care should be
p r o v i d e d w i t h a c e t a m i n o p h e n a n ddiphenhydramine. Meperidine 50 mg IV is usefulin treating chills. A WBC filter should be used forthe any subsequent transfusions.
2. More serious transfusion reactions must be ex-
cluded (eg, acute hemolytic reaction or bacterialcontamination of donor blood).
III. Transfusion-related noncardiogenic pulmonary
edema
A. This reaction is characterized by sudden develop-
ment of severe respiratory distress, associated withfever, chills, chest pain, and hypotension.
B. Chest radiograph demonstrates diffuse pulmonary
edema. This reaction may be severe and life threat-ening but generally resolves within 48 hours.
1. Treatment of pulmonary edema and hypoxemia
may include mechanical ventilatory support andhemodynamic monitoring. 2. Diuretics are useful only if fluid overload is pres-
ent. Use a WBC filter should be used for anysubsequent transfusions.
I. Clinical manifestations
A. Disseminated intravascular coagulation (DIC) is
manifest by generalized ecchymosis and petechiae,bleeding from peripheral IV sites, central catheters,surgical wounds, and oozing from gums. B. Gastrointestinal and urinary tract bleeding are fre-
quently encountered. Grayish discoloration orcyanosis of the distal fingers, toes, or ears may occurbecause of intravascular thrombosis. Large, sharplydemarcated, ecchymotic areas may be seen as aresult of thrombosis.
A. Fibrin degradation products are the most sensitive
screening test for DIC; however, no single laboratoryparameter is diagnostic of DIC.
B. Peripheral smear: Evidence of microangiopathic
hemolysis, with schistocytes and thrombocytopenia,is often present. A persistently normal platelet countnearly excludes the diagnosis of acute DIC.
C. Coagulation studies: INR, PTT, and thrombin time
are generally prolonged. Fibrinogen levels areusually depleted (<150 mg/dL). Fibrin degradationproducts (>10 mg/dL) and D-dimer is elevated (>0.5mg/dL).
III.Management of disseminated intravascular coagula-
tion
A. The primary underlying precipitating condition (eg,
sepsis) should be treated. Severe DIC withhypocoagulability may be treated with replacement ofclotting factors. Hypercoagulability is managed withheparin.
B. Severe hemorrhage and shock is managed with
fluids and red blood cell transfusions.
C. If the patient is at high risk of bleeding or actively
bleeding with DIC: Replace fibrinogen with 10 units
of cryoprecipitate. Replace clotting factors with 2-4
units of fresh frozen plasma. Replace platelets with
platelet pheresis.
D. If factor replacement therapy is transfused,
fibrinogen and platelet levels should be obtained 30-60 minutes post-transfusion and every 4-6 hoursthereafter to determine the efficacy of therapy. Eachunit of platelets should increase the platelet count by5000-10,000/mcL. Each unit of cryoprecipitate shouldincrease the fibrinogen level by 5-10 mg/dL.
E. Heparin
1. Indications for heparin include evidence of fibrin
deposition (ie, dermal necrosis, acral ischemia,venous thromboembolism). Heparin is used whenthe coagulopathy is believed to be secondary to aretained, dead fetus, amniotic fluid embolus, gianthemangioma, aortic aneurysm, solid tumors, orpromyelocytic leukemia. Heparin is also usedwhen clotting factors cannot be corrected withreplacement therapy alone.
2. Heparin therapy is initiated at a relatively low dose
(5-10 U/kg/hr) by continuous IV infusion without abolus. Coagulation parameters must then befollowed to guide therapy. The heparin dose maybe increased by 2.5 U/kg/hr until the desired effectis achieved.
I. Clinical presentation: Post-fibrinolysis hemorrhage
may present as a sudden neurologic deficit (intracranialbleeding), massive GI bleeding, progressive back painaccompanied by hypotension (retroperitoneal bleeding),or a gradual decline in hemoglobin without overt evi-dence of bleeding.
II. Laboratory evaluation
A. Low fibrinogen (<100 mg/dL) and elevated fibrin
degradation products confirm the presence of a lyticstate. Elevated thrombin time and PTT may suggesta persistent lytic state; however, both are prolongedin the presence of heparin. Prolonged reptilase timeidentifies the persistent lytic state in the presence ofheparin.
B. Depleted fibrinogen in the fibrinolytic state will be
reflected by an elevated PTT, thrombin time, orreptilase time. The post-transfusion fibrinogen levelis a useful indicator of response to replacementtherapy.
C. The bleeding time may be a helpful guide to platelet
replacement therapy if the patient has persistentbleeding despite factor replacement withcryoprecipitate and fresh frozen plasma. A. Discontinue thrombolytics, aspirin, and heparin
immediately, and consider protamine reversal ofheparin and cryoprecipitate to replenish fibrinogen.
B. Place two large-bore IV catheters for volume replace-
ment. If possible, apply local pressure to bleedingsites. Blood specimens should be sent for INR/PTT,fibrinogen, and thrombin time. Reptilase time shouldbe checked if the patient is also receiving heparin.
Patient's blood should be typed and crossed becauseurgent transfusion may be needed.
1. Cryoprecipitate (10 units over 10 minutes) should
be transfused to correct the lytic state. Transfu-sions may be repeated until the fibrinogen level isabove 100 mg/dL or hemostasis is achieved.
Cryoprecipitate is rich in fibrinogen and factor VIII.
2. Fresh frozen plasma transfusion is also important
for replacement of factor VIII and V. If bleedingpersists after cryoprecipitate and FFP replace-ment, check a bleeding time and consider platelettransfusion if bleeding time is greater than 9 minutes. If bleeding time is less than 9 minutes,then antifibrinolytic drugs may be warranted.
D. Antifibrinolytic agents
1. Aminocaproic acid (EACA) inhibits the conversion
of plasminogen to plasmin. It is used when re-placement of blood products are not sufficient toattain hemostasis.
2. Loading dose: 5 g or 0.1 g/kg IV infused in 250 cc
NS over 30-60 min, followed by continuous infu-sion at 0.5-2.0 g/h until bleeding is controlled. Usewith caution in upper urinary tract bleeding be-cause of the potential for obstruction.
References: See page 168.
Guy Foster, MDFarhad Mazdisnian, MDMichael Krutzik, MDGeorgina Heal, MD Meningitis is an infection of the meninges and thecerebrospinal fluid (CSF) of the subarachnoid space andthe cerebral ventricles. Meningitis is one of the ten mostcommon infectious causes of death. Neurologic sequelaeare common among survivors.
A. Causative organisms in adults
1. Up to age 60, S. pneumoniae is responsible for 60
percent of cases, followed by N. meningitidis (20percent), H. influenzae (10 percent), L.
monocytogenes (6 percent), and group B strepto-coccus (4 percent).
2. Age 60 and above, almost 70 percent of cases are
caused by S. pneumoniae, 20 percent to L.
monocytogenes, and 3 to 4 percent each to N.
meningitidis, group B streptococcus, and H.
influenzae. An increased prevalence of L.
monocytogenes occurs in the elderly.
B. Predisposing factors. Major mechanisms for
developing meningitis:
1. Colonization of the nasopharynx with subsequent
bloodstream invasion and subsequent centralnervous system (CNS) invasion 2. Invasion of the CNS following bacteremia due to
a localized source, such as infective endocarditisor a urinary tract infection 3. Direct entry of organisms into the CNS from a
contiguous infection (eg, sinuses, mastoid),trauma, neurosurgery, or medical devices (eg,shunts or intracerebral pressure monitors).
C. Host factors that can predispose to meningitis include
asplenia, complement deficiency, corticosteroid
excess, and HIV infection. Other predisposing factors
for meningitis include:
1. Recent exposure to someone with meningitis
2. A recent infection (especially respiratory or otic
3. Recent travel, particularly to areas with endemic
meningococcal disease such as sub-SaharanAfrica 4. Injection drug use
5. Recent head trauma
6. Otorrhea or rhinorrhea
II.Clinical features. Patients with bacterial meningitis
appear ill and often present soon after symptom onset.
A. Presenting manifestations. The classic triad of acute
bacterial meningitis consists of fever, nuchal rigidity,and a change in mental status, although many pa-tients do not have all three features. Most patientshave high fevers, often greater than 38ºC, but a smallpercentage have hypothermia.
B. Headache is also common. The headache is severe
and generalized. It is not easily confused with normalheadaches.
C. Fever is present in 95 percent at presentation and
developed in another 4 percent within the first 24hours.
D. Nuchal rigidity is present in 88 percent.
E. Mental status is altered in 78 percent. Most were
confused or lethargic, but 22 percent are responsiveonly to pain and 6 percent are unresponsive to allstimuli.
F. Significant photophobia is common.
G. Neurologic complications such as seizures, focal
neurologic deficits (including cranial nerve palsies),and papilledema, may be present early or occur laterin the course. Seizures occur in 15 to 30 percent andfocal neurologic deficits in 20 to 30 percent. Hearing loss is a late complication. Dexamethasone therapymay reduce the rate of neurologic sequelae.
H. N. meningitidis can cause petechiae and palpable
I. Examination for nuchal rigidity. Passive or active
flexion of the neck will usually result in an inability to
touch the chin to the chest.
1. Brudzinski sign refers to spontaneous flexion of the
hips during flexion of the neck.
2. The Kernig sign refers to the inability or reluctance
to allow full extension of the knee when the hip isflexed 90º.
3. The sensitivity of meningeal signs is extremely low
(5 percent for each sign and 30 percent for nuchalrigidity); the specificity was 95 percent for each signand 68 percent for nuchal rigidity.
J. Initial blood tests should include a complete blood
count with differential and platelet count, and two sets
of blood cultures. A specimen of cerebrospinal fluid
(CSF) should be obtained for cell count and differen-
tial, glucose and protein concentration, Gram stain,
and culture. Characteristic findings in bacterial menin-
gitis include a CSF glucose concentration below 45
mg/dL, a protein concentration above 500 mg/dL, and
a white blood cell count above 1000/microL, usually
composed primarily of neutrophils. Most often the
white blood cell count is elevated with a shift toward
immature forms. Severe infection can be associated
with leukopenia. The platelet count may be reduced if
disseminated intravascular coagulation or
meningococcal bacteremia is present.
1. Blood cultures are often positive. Approximately
50 to 75 percent of patients with bacterial meningi-tis have positive blood cultures. Cultures obtainedafter antimicrobial therapy are much less likely tobe positive, particularly for meningococcus. Testsof serum and urine for bacterial antigens areunhelpful.
K. Lumbar puncture. Every patient with suspected
meningitis should have CSF obtained unless the
procedure is contraindicated. Risk factors for an occult
mass lesion on CT scan include the presence of
impaired cellular immunity, history of previous central
nervous system disease, a seizure within the previous
week, reduced level of consciousness, and focal
motor or cranial abnormalities. A CT scan is recom-
mended before an LP only in patients with suspected
bacterial meningitis who have one or more risk factors
for a mass lesion.
1. Opening pressure is typically elevated in patients
with bacterial meningitis. The mean opening pres-sure is 350 mm H O (normal up to 200 mm H O).
2. CSF analysis. When the clinical diagnosis strongly
suggests meningitis, CSF Gram stain, culture, andanalysis can distinguish between bacterial and viralinfection. A Gram stain should be obtained when-ever there is suspicion of bacterial meningitis. Thefollowing findings may be seen: 3. Gram positive diplococci suggest pneumococcal
4. Gram negative diplococci suggest meningococcal
5. Small pleomorphic Gram negative coccobacilli
suggest Haemophilus influenzae.
6. Gram positive rods and coccobacilli suggest
Utility of CSF Analysis in Infectious Causes of
CNS Infection
Total WBC
Common self-limited forms of viral meningitis usually have aCSF protein concentration below 100 mg/dL (1 g/L) and a totalWBC less than 100/μL. In addition to the total WBC, the percentneutrophils also may be helpful: more than 50 percent suggestsbacterial meningitis while a value below 10 percent is compati-ble with viral infection Treatment of bacterial meningitis in adults
A. Antibiotic therapy should be initiated immediately after
the results of lumbar puncture (LP) or immediatelyafter LP alone if the clinical suspicion is high. Ascreening CT scan is not necessary in the majority ofpatients. Risk factors for cerebral herniation includepresence of impaired cellular immunity, history ofprevious central nervous system disease, or a seizurewithin the previous week reduced level of conscious-ness, focal motor or cranial abnormalities, andpapilledema. Should LP be delayed by the need forcranial imaging, blood cultures should be obtainedand antibiotics should be administered empiricallybefore the imaging study, followed as soon as possi-ble by the LP. In addition, dexamethasone (0.15mg/kg IV every six hours) should be given shortlybefore or at the same time as the antibiotics clinicaland laboratory evidence suggests bacterial meningitis.
B. Empiric drug regimen. Selected third-generation
cephalosporins, such as cefotaxime and ceftriaxone,
are the beta-lactams of choice in the empiric treatment
of meningitis.
1. Cefotaxime and ceftriaxone are equivalent or
superior to penicillin and ampicillin because of theirconsistent CSF penetration and their activityagainst the major pathogens of meningitis with onenotable exception, some penicillin-resistant S.
pneumoniae. Ceftazidime, another third-generationcephalosporin, is much less active againstpenicillin-resistant pneumococci than cefotaximeand ceftriaxone.
Empiric antibiotic therapy in adults with sus-
pected bacterial meningitis and a nondiagnostic
CSF gram stain
Most likely pathogens
Immunocompetent adults Age 18 to 60 years S. Pneumoniae, N. Men- Ceftriaxone (2 g twice daily) OR, less prefer-
H. influenzae, and, ably, cefotaxime (2 g every four to six or six L. monocytogenes and to eight hours) AND
group B streptococci vancomycin (2 g/dayin two to four divideddoses) ifcephalosporin-resis-tant pneumococci incommunity S. Pneumoniae, L.
monocytogenes, and, ampicillin (200 mg/kg less often, group B per day in six divided streptococci, N. Menin- gitis,H. influenzae Most likely pathogens
Impaired cellular immu- L. Monocytogenes, gram negative bacilli Ceftazidime (2 g every
eight hours) PLUS
Ampicillin (2 g every
four hours) AND
vancomycin (2 g/day
in two to four divided
doses) if
cephalosporin-resis-
tant pneumococci in
community
2. Intravenous antibiotics should be directed at the
presumed pathogen if the Gram stain is diagnostic.
Antibiotic therapy should then be modified once the
CSF culture results are available.
a. If Gram positive cocci are seen in community-
acquired meningitis, S. pneumoniae should bethe suspected pathogen. However, in the settingof neurosurgery or head trauma within the pastmonth, a neurosurgical device, or a CSF leak,Staphylococcus aureus and coagulase negativestaphylococci are more common andvancomycin is required.
b. If Gram negative cocci are seen, N. meningitidis
is the probable pathogen.
c. Gram positive bacilli suggest Listeria.
d. Gram negative bacilli usually represent
Enterobacteriaceae (eg, Klebsiella, Escherichiacoli) in cases of community-acquired meningitis.
e. If there is a history of neurosurgery or head
trauma within the past month, a neurosurgicaldevice, or a CSF leak in patients with Gramnegative rods, ceftriaxone should be replacedwith ceftazidime since such patients are atgreater risk for Pseudomonas and Acinetobacterinfection.
C. Adjuvant dexamethasone. Permanent neurologic
sequelae, such as hearing loss and focal neurologicdeficits, are not uncommon in survivors of bacterialmeningitis, particularly with pneumococcal meningitis.
Intravenous dexamethasone (0.15 mg/kg every sixhours) should be given shortly before or at the time ofinitiation of antibiotic therapy in adults with suspectedbacterial meningitis who have a Glasgow coma scoreof 8 to 11. Dexamethasone should be continued forfour days if the Gram stain or the CSF culture revealsS. pneumoniae. Dexamethasone should be discontin-ued if the Gram stain and/or culture reveal anotherpathogen or no meningitis.
D. Choice of agent when pathogen is unknown.
Antibiotic selection must be empiric when lumbar
puncture is delayed or Gram stain of the CSF does
not reveal a pathogen.
1. In adults up to age 60, S. pneumoniae was respon-
sible for 60 percent of cases, followed by N.
meningitidis (20 percent), H. influenzae (10 per-cent), L. monocytogenes (6 percent), and group Bstreptococcus (4 percent).
2. In adults >60 years of age, almost 70 percent of
cases are caused by S. pneumoniae, 20 percent toL. monocytogenes, and 3 to 4 percent each to N.
meningitidis, group B streptococcus, and H.
influenzae. An increased prevalence of L.
monocytogenes in the elderly has been noted.
3. No known immune deficiency. Meningococcus,
pneumococcus, and, less often, H. influenzae andgroup B streptococcus are the most likely causes ofcommunity-acquired bacterial meningitis in adoles-cents and adults up to the age of 60. Such patientsshould be treated with intravenous ceftriaxone (2 gBID) or cefotaxime (2 g every six to eight hours). Ifcephalosporin resistance occurs in more than 3percent S. pneumoniae isolates, vancomycinshould be added (2 g/day intravenously in two tofour divided doses if renal function is normal). Beta-lactams should be continued even if in vitro testssuggest possible intermediate or resistant organ-isms, since they will provide synergy withvancomycin. Adults >60 years of age, in whom 20percent of cases are due to listeria, should receiveampicillin (200 mg/kg per day IV in six divideddoses).
Antibiotic recommendations for adults with sus-
pected meningitis with a positive cerebrospinal
fluid gram stain or culture
Morphology on CSF Gram stain Gram positive cocci Vancomycin (500 mg Q6h)‡
PLUS either
ceftriaxone (2 g Q12h) or, less
preferably, cefotaxime (2 g
Q4-6h or Q6-8h)
Penicillin G (4 million U Q4h) or, if H. Influenzae (which typi-cally appears as small,pleomorphic rods) is sus-pected, ceftriaxone (2 g Q12h)or cefotaxime (2 g Q6-8h) Gram positive ba- Ampicillin (2 g Q4h) PLUS
gentamicin (1-2 mg/kg Q8h) Gram negative ba- Ceftriaxone (2 g Q12h) or cefotaxime (2 g Q6-8h) PLUS
gentamicin (1-2 mg/kg Q8h)
Growth in CSF culture
Vancomycin (500 mg Q6h)‡
PLUS either ceftriaxone (2 g
Q12h) or, less preferably,
cefotaxime (2 g Q4-6h or Q6-
8h) for 14 days; vancomycin
can be discontinued if the iso-
late is not cephalosporin-re-
sistant
Penicillin G (4 million unitsQ4h) for seven days Ceftriaxone (2 g Q12h) orcefotaxime (2 g Q6h) forseven days Ampicillin (2 g Q4h) or penicil-
lin G (3-4 million U Q4h)
PLUS gentamicin (1-2 mg/kg
Q8h); ampicillin is given for
two to four weeks in
immunocompetent patients
and for at lease six to eight
w
immunocompromised pa-tients; gentamicin is gen untilthe patient improves (usually10 to 14 days) or, in poor re-sponders, for up to threeweeks if there are no signs ofnephrotoxicity and ototoxicity Penicillin G (4 million U Q4h) for two to three weeks Ceftriaxone (2 g Q12h) or
cefotaxime (2 g Q6h-8h)
PLUS gentamicin (1-2 mg/kg
Q8h) for three weeks
ceftazidime (2 g Q8h) PLUS
gentamicin (1-2 mg/kg Q8h)for 21 days 4. Impaired cellular immunity due to lymphoma,
cytotoxic chemotherapy, or high-doseglucocorticoids requires coverage against L.
monocytogenes and Gram negative bacilli as wellas S. pneumoniae. Patients should receiveceftazidime (2 g every eight hours) and ampicillin(200 mg/kg per day IV in six divided doses).
Vancomycin should be added (2 g/day intrave-nously in two to four divided doses if renal functionis normal) if there is possible cephalosporin-resis-tant pneumococci.
5. Nosocomial infection. Empiric therapy must cover
both Gram negative (such as Klebsiellapneumoniae and Pseudomonas aeruginosa) andGram positive nosocomial pathogens. Ceftazidime(2 g every eight hours) plus vancomycin (2 g/dayintravenously in two to four divided doses if renalfunction is normal) is recommended.
1. Vaccines are available for S. pneumoniae, N.
meningitidis, and H. influenzae.
a. Pneumococcal vaccine is administered to
chronically ill and older adults (over age 65).
b. Meningococcal vaccine is not warranted as
postexposure prophylaxis unless the strain isdocumented to have a capsular serotype repre-sented in the vaccine (type A, C, Y or W-135).
Meningococcal vaccination is indicated forpatients with asplenia and complement deficien-cies.
c. H. influenzae vaccine. A marked reduction in
H. influenzae meningitis has been associatedwith the near universal use of a H. influenzaevaccine.
a. Neisseria meningitidis. Chemoprophylaxis of
close contacts consists of rifampin (600 mg POevery 12 h for a total of four doses in adults),ciprofloxacin (500 mg PO once), and ceftriaxone(250 mg IM once).
Antimicrobial chemoprophylaxis regimens for
meningococcal infection
hours600 mgevery 12hours b. H. influenzae. Unvaccinated, young children
(less than four years of age) who have closecontact with patients with H. influenzae type bmeningitis require rifampin (20 mg/kg with a maxof 600 mg/day PO for four days).
Four million cases of Community-acquired pneumonia(CAP) occur annually. Bacteria are the most commoncause of pneumonia and have been divided into twogroups: "typical" and "atypical": "Typical" organisms includeStreptococcus pneumoniae, Haemophilus influenzae,Staphylococcus aureus, and other Gram negative bacteria.
Atypical" refers to pneumonia caused by Legionella sp,Mycoplasma pneumoniae, and Chlamydia pneumoniae.
A. Pneumococcal pneumonia
1. S. pneumoniae is the most common cause of
CAP. The organism is isolated in only 5 to 18percent. Risk factors for pneumococcal pneumo-nia include: advanced age, cigarette smoking,dementia, malnutrition, the presence of chronicillnesses, and human immunodeficiency virus(HIV) infection.
2. Pneumonia caused by pneumococcus is usually
associated with cough, sputum production, andfever. Bacteremia accompanies the pneumonia in20 to 30 percent of cases. A parapneumonicpleural effusion is present in the majority of pa-tients, but empyema occurs in only two percent ofcases.
3. Penicillin resistance is an increasing problem.
B. Other bacteria. H. influenzae (generally other than
type B), S. aureus, Legionella, and Gram negative
bacteria each account for 3 to 10 percent of cases of
CAP.
1. The patient population and clinical presentation of
H. influenzae pneumonia is similar to that withpneumococcal disease.
2. S. aureus pneumonia that is community-acquired
is usually seen in the elderly and in younger patients who are recovering from influenza (post-influenza pneumonia).
3. Legionella accounts for 2 to 8 percent of cases of
CAP. Among patients with pneumonia who can betreated as outpatients, the frequency of Legion-naires' disease is less than 1 percent. Legionellais much more frequent in hospitalized patients,especially those admitted to intensive care units.
4. Gram-negative bacilli, especially P. aeruginosa,
are an uncommon cause of CAP except in pa-tients with neutropenia, cystic fibrosis, late stageHIV infection and bronchiectasis.
5. Other bacteria that can cause CAP include
Neisseria meningitidis, Moraxella catarrhalis, andStreptococcus pyogenes.
6. Anaerobic organisms may be the cause of aspira-
tion pneumonia and lung abscess.
A. Clinical evaluation. CAP caused by pyogenic
organisms presents with the sudden onset of rigors,fever, pleuritic chest pain, and cough productive ofpurulent sputum. Chest pain occurs in 30 percent ofcases, chills in 40 to 50 percent, and rigors in 15percent.
B. On physical examination, 80 percent are febrile,
although this finding is frequently absent in olderpatients. A respiratory rate above 24 breaths/minuteis noted in 45 to 70 percent of patients; tachycardiais also common. Chest examination reveals audiblerales in most patients, while one-third have consoli-dation.
C. The major blood test abnormality is leukocytosis
(15,000 and 30,000 per mm3) with a leftward shift.
Leukopenia can occur.
D. Chest radiographs. The presence of an infiltrate on
plain chest radiograph is the "gold standard" fordiagnosing pneumonia. The radiographic appear-ances include lobar consolidation, interstitial infil-trates, and cavitation.
E. Sputum examination. An etiologic agent is found in
51 percent of patients. A specimen that has greaterthan 25 PMN and less than 10 epithelial cells per lowpower field represents a purulent specimen. Gramstain and culture may identify the cause of thepneumonia.
F. Blood cultures should be obtained in patients who
G. Urinary antigen testing for pneumococcal cell wall
components has a sensitivity of 70 to 90 percent;specificity is 80 to 100 percent. Urinary antigentesting is also available for Legionella species and ishighly sensitive and specific and inexpensive. Urinaryantigen testing is recommended for both S.
pneumoniae and Legionella, particularly in patientswith risk factors for Legionella infection (eg, smoking,chronic lung disease, immunosuppression, and CAPrequiring hospitalization).
Causes of Community-acquired Pneumonia
Hemophilus influenzae Staphylococcus aureus Gram-negative bacilli Legionella sp.
Mycoplasma pneumoniae Chlamydia pneumoniae III. Treatment of Community-Acquired Pneumonia
A. Empiric regimens. For uncomplicated pneumonia
in patients who do not require hospitalization,macrolide therapy is recommended. Erythromycinis the least expensive macrolide but is associatedwith gastrointestinal upset in many patients.
Azithromycin (Zithromax [500 mg PO QD]) isrecommended because it causes less gastrointesti-nal upset; if macrolide resistance in the communityis high, doxycycline (100 mg PO twice a day)should be considered. Telithromycin (Ketek) or aquinolone is also reasonable if macrolide resis-tance is prevalent. Quinolones are not recom-mended for patients with CAP because achievabletissue concentrations of these agents will be closeto the minimum inhibitory concentration forpneumococcus and resistance may emerge withoveruse.
B. Duration of therapy. The usual recommended
duration of therapy is 7 to 14 days. Three days of azithromycin may be as effective as longer courseof antibiotics. For a hospitalized patient, ceftriaxone(Rocephin [2 g IV QD]) with or without azithromycin(depending upon the likelihood of an atypicalorganism) is recommended. For more severely illpatients who might have an atypical pneumonia orpatients admitted to an ICU, therapy consists of aquinolone, such as levofloxacin (Levaquin [500 mgIV QD]) or azithromycin to treat legionella infectionas well as mycoplasma and chlamydia. Consider-ation should be given to adding a second agent forpneumococcus to levofloxacin. Ceftriaxone shouldbe given with azithromycin in these sicker patients.
Recommended Empiric Drug Therapy for Pa-
tients with Community-Acquired Pneumonia
Older (>60 yr) Beta-lactamase in- legionella infection Common Antimicrobial Agents for Community-
Acquired Pneumonia in Adults
Oral therapy
1, then 250 mg qd 500 mg tid or 875 0.75-1.5 g IV q8h (Kefurox, Zinacef) Load 2.0 mg/kg IV, then 1.5 mg/kgq8h A. Patients initially treated with intravenous antibiotics can
be switched to oral agents when the patient is afebrile.
The regimens for the hospitalized patient are alsoappropriate for patients admitted from long-term carefacilities. Discharged from the hospital may be com-pleted once oral therapy.
B. Most patients respond to a course of 10 to 14 days of
antibiotics, although 3 to 5 days of azithromycin is analternative in ambulatory patients.
C. Response to therapy. Some improvement in the
patient's clinical course should be seen within 48 to 72hours. Fever in patients with lobar pneumonia oftentakes 72 hours or longer to improve. The chest x-rayusually clears within four weeks in patients younger than50 years of age without underlying pulmonary disease.
D. The nonresponding patient
1. If the patient does not improve within 72 hours, an
organism which is not covered by the initial antibioticregimen should be considered. This could be theresult of drug resistance, nonbacterial infection,unusual pathogens (eg, Pneumocystis carinii orMycobacterium tuberculosis), drug fever, or a compli-cation such as postobstructive pneumonia,empyema, or abscess. The differential diagnosis alsoincludes noninfectious etiologies, such as malig-nancy, inflammatory conditions, or heart failure.
2. When evaluating a patient who is not responding to
therapy, it is important to repeat the history to includetravel and pet exposures to look for unusual patho-gens. Bronchoscopy can be performed to evaluatethe airway for obstruction due to a foreign body ormalignancy. Previously unsuspected pathogens mayinclude P. carinii or M. tuberculosis.
Pneumocystis Carinii Pneumonia
PCP is the most common life-threatening opportunisticinfection occurring in patients with HIV disease. In the eraof PCP prophylaxis and highly active antiretroviral therapy,the incidence of PCP is decreasing. The incidence of PCPhas declined steadily from 50% in 1987 to 25% currently.
I. Risk factors for Pneumocystis carinii pneumonia
A. Patients with CD4 counts of 200 cells/µL or less are
4.9 times more likely to develop PCP.
B. Candidates for PCP prophylaxis include: patients with
a prior history of PCP, patients with a CD4 cell countof less than 200 cells/µL, and HIV-infected patientswith thrush or persistent fever.
II. Clinical presentation
A. PCP usually presents with fever, dry cough, and
shortness of breath or dyspnea on exertion with agradual onset over several weeks. Tachypnea maybe pronounced. Circumoral, acral, and mucousmembrane cyanosis may be evident.
B. Laboratory findings
1. Complete blood count and sedimentation rate
shows no characteristic pattern in patients withPCP. The serum LDH concentration is frequentlyincreased.
2. Arterial blood gas measurements generally show
increases in P(A-a)O , although PaO values vary widely depending on disease severity. Up to 25%of patients may have a PaO of 80 mm Hg or above while breathing room air.
3. Pulmonary function tests. Patients with PCP
usually have a decreased diffusing capacity forcarbon monoxide (DLCO).
C. Radiographic presentation
1. PCP in AIDS patients usually causes a diffuse
interstitial infiltrate. High resolution computerizedtomography (HRCT) may be helpful for thosepatients who have normal chest radiographicfindings.
2. Pneumatoceles (cavities, cysts, blebs, or bullae)
and spontaneous pneumothoraces are common inpatients with PCP.
III. Laboratory diagnosis
A. Sputum induction. The least invasive means of
establishing a specific diagnosis is the examination ofsputum induced by inhalation of a 3-5% saline mist.
The sensitivity of induced sputum examination forPCP is 74-77% and the negative predictive value is58-64%. If the sputum tests negative, an invasive diagnostic procedure is required to confirm thediagnosis of PCP.
B. Transbronchial biopsy and bronchoalveolar
lavage. The sensitivity of transbronchial biopsy for
PCP is 98%. The sensitivity of bronchoalveolar is
90%.
C. Open-lung biopsy should be reserved for patients
with progressive pulmonary disease in whom the lessinvasive procedures are nondiagnostic.
A. If the chest radiograph of a symptomatic patient
appears normal, a DLCO should be performed.
Patients with significant symptoms, a normal-appear-ing chest radiograph, and a normal DLCO shouldundergo high-resolution CT. Patients with abnormalfindings at any of these steps should proceed tosputum induction or bronchoscopy. Sputum speci-mens collected by induction that reveal P. cariniishould also be stained for acid-fast organisms andfungi, and the specimen should be cultured formycobacteria and fungi.
B. Patients whose sputum examinations do not show P.
carinii or another pathogen should undergo bron-choscopy.
C. Lavage fluid is stained for P. carinii, acid-fast organ-
isms, and fungi. Also, lavage fluid is cultured formycobacteria and fungi and inoculated onto cellculture for viral isolation. Touch imprints are madefrom tissue specimens and stained for P. carinii. Fluidis cultured for mycobacteria and fungi, and stainedfor P. carinii, acid-fast organisms, and fungi. If allprocedures are nondiagnostic and the lung diseaseis progressive, open-lung biopsy may be considered.
V. Treatment of Pneumocystic carinii pneumonia
A. Trimethoprim-sulfamethoxazole DS (Bactrim DS,
Septra DS) is the recommended initial therapy for
PCP. Dosage is 15-20 mg/kg/day of TMP IV divided
q6h for 14-21 days. Adverse effects include rash
(33%), elevation of liver enzymes (44%), nausea and
vomiting (50%), anemia (40%), creatinine elevation
(33%), and hyponatremia (94%).
B. Pentamidine is an alternative in patients who have
adverse reactions or fail to respond to TMP-SMX.
The dosage is 4 mg/kg/day IV for 14-21 days. Ad-verse effects include anemia (33%), creatinineelevation (60%), LFT elevation (63%), andhyponatremia (56%). Pancreatitis, hypoglycemia, andhyperglycemia are common side effects.
C. Corticosteroids. Adjunctive corticosteroid treatment
is beneficial with anti-PCP therapy in patients with apartial pressure of oxygen (PaO ) less than 70 mm Hg, (A-a)DO greater than 35 mm Hg, or oxygen saturation less than 90% on room air. Contraindica-
tions include suspected tuberculosis or disseminated
fungal infection. Treatment with methylprednisolone
(SoluMedrol) should begin at the same time as anti-
PCP therapy. The dosage is 30 mg IV q12h x 5 days,
then 30 mg IV qd x 5 days, then 15 mg qd x 11 days
OR prednisone, 40 mg twice daily for 5 days, then 40
mg daily for 5 days, and then 20 mg daily until day 21
of therapy.
A. HIV-infected patients who have CD4 counts less than
200 cells/mcL should receive prophylaxis againstPCP. If CD4 count increases to greater than 200cells/mcL after receiving antiretroviral therapy, PCPprophylaxis can be safely discontinued.
B. Trimethoprim-sulfamethoxazole (once daily to
three times weekly) is the preferred regimen for PCPprophylaxis.
C. Dapsone (100 mg daily or twice weekly) is a prophy-
lactic regimen for patients who can not tolerate TMP-SMX.
D. Aerosolized pentamidine (NebuPent) 300 mg in 6
mL water nebulized over 20 min q4 weeks is anotheralternative.
Antiretroviral Therapy and Opportu-
nistic Infections in AIDS
I. Antiretroviral therapy
A. A combination of three agents is recommended as
initial therapy. The preferred options are 2 nucleo-sides plus 1 protease inhibitor or 1 non-nucleoside.
Alternative options are 2 protease inhibitors plus 1nucleoside or 1 non-nucleoside. Combinations of 1nucleoside, 1 non-nucleoside, and 1 protease inhibi-tor are also effective. B. Nucleoside analogs
1. Abacavir (Ziagen) 300 mg PO bid [300 mg].
2. Didanosine (Videx) 200 mg PO bid [chewable
tabs: 25, 50, 100, 150 mg]; oral ulcers discouragecommon usage.
3. Lamivudine (Epivir) 150 mg PO bid [tab: 150 mg].
4. Stavudine (Zerit) 40 mg PO bid [cap: 15, 20, 30,
5. Zalcitabine (Hivid) 0.75 mg PO tid [tab: 0.375, 0.75
6. Zidovudine (Retrovir, AZT) 200 mg PO tid or 300
mg PO bid [cap: 100, 300 mg].
7. Zidovudine 300 mg/lamivudine 150 mg (Combivir)
1 tab PO bid.
C. Protease inhibitors
1. Amprenavir (Agenerase) 1200 mg PO bid [50, 150
2. Indinavir (Crixivan) 800 mg PO tid [cap: 200, 400
3. Nelfinavir (Viracept) 750 mg PO tid [tab: 250 mg]
4. Ritonavir (Norvir) 600 mg PO bid [cap: 100 mg].
5. Saquinavir ( Invirase) 600 mg PO tid [cap: 200
D. Non-nucleoside analogs
1. Delavirdine (Rescriptor) 400 mg PO tid [tab: 100
2. Efavirenz (Sustiva) 600 mg qhs [50, 100, 200 mg]
3. Nevirapine (Viramune) 200 mg PO bid [tab: 200
II. Oral candidiasis
A. Fluconazole (Diflucan), acute: 200 mg PO x 1, then
100 mg qd x 5 days OR
B. Ketoconazole (Nizoral), acute: 400 mg po qd 1-2
weeks or until resolved OR
C. Clotrimazole (Mycelex) troches 10 mg dissolved
slowly in mouth 5 times/d.
A. Fluconazole (Diflucan) 200 mg PO x 1, then 100 mg
PO qd until improved.
B. Ketoconazole (Nizoral) 200 mg po bid.
Primary or recurrent mucocutaneous HSV.
Acyclovir (Zovirax), 200-400 mg PO 5 times a day for
10 days, or 5 mg/kg IV q8h; or in cases of acyclovir
resistance, foscarnet 40 mg/kg IV q8h for 21 days.
V. Herpes simplex encephalitis. Acyclovir 10 mg/kg IV
q8h x 10-21 days.
Herpes varicella zoster
A. Acyclovir (Zovirax) 10 mg/kg IV over 60 min q8h OR
B. Valacyclovir (Valtrex) 1000 mg PO tid x 7 days
[caplet: 500 mg].
A. Ganciclovir (Cytovene) 5 mg/kg IV (dilute in 100 mL
D5W over 60 min) q12h x 14-21 days (concurrentuse with zidovudine increases hematological toxic-ity).
B. Suppressive treatment for CMV: Ganciclovir
(Cytovene) 5 mg/kg IV qd, or 6 mg/kg IV 5 times/wk,or 1000 mg orally tid with food.
A. Pyrimethamine 200 mg PO loading dose, then 50-
75 mg qd plus leucovorin calcium (folinic acid) 10-
20 mg PO qd for 6-8 weeks for acute therapy AND
B. Sulfadiazine (1.0-1.5 gm PO q6h) or clindamycin
450 mg PO qid/600-900 mg IV q6h.
C. Suppressive treatment for toxoplasmosis
1. Pyrimethamine 25-50 mg PO qd with or without
sulfadiazine 0.5-1.0 gm PO q6h; and folinic acid 5-
10 mg PO qd OR
2. Pyrimethamine 50 mg PO qd; and clindamycin
300 mg PO q6h; and folinic acid 5-10 mg PO qd.
IX. Cryptococcus neoformans meningitis
A. Amphotericin B at 0.7 mg/kg/d IV for 14 days or until
clinically stable, followed by fluconazole (Diflucan)400 mg qd to complete 10 weeks of therapy, fol-lowed by suppressive therapy with fluconazole(Diflucan) 200 mg PO qd indefinitely.
B. Amphotericin B lipid complex (Abelcet) may be used
in place of non-liposomal amphotericin B if thepatient is intolerant to non-liposomal amphotericinB. The dosage is 5 mg/kg IV q24h.
X. Active tuberculosis
A. Isoniazid (INH) 300 mg PO qd; and rifabutin 300 mg
PO qd; and pyrazinamide 15-25 mg/kg PO qd (500mg PO bid-tid); and ethambutol 15-25 mg/kg PO qd(400 mg PO bid-tid).
B. All four drugs are continued for 2 months; isoniazid
and rifabutin (depending on susceptibility testing)are continued for a period of at least 9 months andat least 6 months after the last negative cultures. C. Pyridoxine (vitamin B6) 50 mg PO qd, concurrent
XI. Disseminated mycobacterium avium complex
(MAC)
A. Azithromycin (Zithromax) 500-1000 mg PO qd or
clarithromycin (Biaxin) 500 mg PO bid; AND
B. Ethambutol 15-25 mg/kg PO qd (400 mg bid-tid)
C. Rifabutin 300 mg/d (two 150 mg tablets qd).
D. Prophylaxis for MAC
1. Clarithromycin (Biaxin) 500 mg PO bid OR
2. Rifabutin (Mycobutin) 300 mg PO qd or 150 mg
A. Amphotericin B (Fungizone) 0.8 mg/kg IV qd OR
B. Amphotericin B lipid complex (Abelcet) 5 mg/kg IV
C. Fluconazole (Diflucan) 400-800 mg PO or IV qd.
XIII. Disseminated histoplasmosis
A. Amphotericin B (Fungizone) 0.5-0.8 mg/kg IV qd,
until total dose 15 mg/kg OR
B. Amphotericin B lipid complex (Abelcet) 5 mg/kg IV
C. Itraconazole (Sporanox) 200 mg PO bid.
D. Suppressive treatment for histoplasmosis:
Itraconazole (Sporanox) 200 mg PO bid.
About 400,000 cases of sepsis, 200,000 cases of septicshock, and 100,000 deaths from both occur each year.
I. Pathophysiology
A. Sepsis is defined as the systemic response to infec-
tion. In the absence of infection, it is called systemicinflammatory response syndrome and is character-ized by at least two of the following: temperaturegreater than 38°C or less than 36°C; heart rategreater than 90 beats per minute; respiratory ratemore than 20/minute or PaCO less than 32 mm Hg; and an alteration in white blood cell count(>12,000/mm3 or <4,000/mm3).
B. Septic shock is defined as sepsis-induced
hypotension that persists despite fluid resuscitationand is associated with tissue hypoperfusion.
C. The initial cardiovascular response to sepsis includes
decreased systemic vascular resistance and de-pressed ventricular function. Low systemic vascularresistance occurs. If this initial cardiovascular re-sponse is uncompensated, generalized tissuehypoperfusion results. Aggressive fluid resuscitationmay improve cardiac output and systemic bloodpressure, resulting in the typical hemodynamicpattern of septic shock (ie, high cardiac index and lowsystemic vascular resistance).
D. Although gram-negative bacteremia is commonly
found in patients with sepsis, gram-positive infectionmay affect 30-40% of patients. Fungal, viral and para-sitic infections are usually encountered inimmunocompromised patients.
Defining sepsis and related disorders
The systemic inflammatory response to a severe clinical insult manifested by >2 of the fol owing conditions: Temperature >38EC or <36EC, heart rate >90 beats/min, respiratory rate >20breaths/min or PaCO <32 mm Hg, white blood cell count >12,000 cells/mm3 ,<4000 cells/mm3 , or >10% band cells The presence of SIRS caused by an in-fectious process; sepsis is consideredsevere if hypotension or systemic mani-festations of hypoperfusion (lactic acido-sis, oliguria, change in mental status) ispresent.
Sepsis-induced hypotension despite ade-quate fluid resuscitation, along with thepresence of perfusion abnormalities thatmay induce lactic acidosis, oliguria, or analteration in mental status.
The presence of altered organ function in an acutely ill patient such that homeosta- sis cannot be maintained without interven- E. Sources of bacteremia leading to sepsis include the
urinary, respiratory and GI tracts, and skin and softtissues (including catheter sites). The source ofbacteremia is unknown in 30% of patients.
F. Escherichia coli is the most frequently encountered
gram-negative organism, followed by Klebsiellapneumoniae, Enterobacter aerogenes or cloacae,Serratia marcescens, Pseudomonas aeruginosa,Proteus mirabilis, Providencia, and Bacteroidesspecies. Up to 16% of sepsis cases are polymicrobic.
G. Gram-positive organisms, including methicillin-
sensitive and methicillin-resistant Staphylococcusaureus and Staphylococcus epidermidis, are associ-ated with catheter or line-related infections.
A. A patient who is hypotensive and in shock should be
evaluated to identify the site of infection, and monitor for end-organ dysfunction. History should be ob-tained and a physical examination performed.
B. The early phases of septic shock may produce
evidence of volume depletion, such as dry mucousmembranes, and cool, clammy skin. After resuscita-tion with fluids, however, the clinical picture resem-bles hyperdynamic shock, including tachycardia,bounding pulses with a widened pulse pressure, ahyperdynamic precordium on palpation, and warmextremities.
C. Signs of infection include fever, localized erythema
or tenderness, consolidation on chest examination,abdominal tenderness, and meningismus. Signs ofend-organ hypoperfusion include tachypnea, oliguria,cyanosis, mottling of the skin, digital ischemia,abdominal tenderness, and altered mental status.
D. Laboratory studies should include arterial blood
gases, lactic acid level, electrolytes, renal function,liver function tests, and chest radiograph. Cultures ofblood, urine, and sputum should be obtained beforeantibiotics are administered. Cultures of pleural,peritoneal, and cerebrospinal fluid may be appropri-ate. If thrombocytopenia or bleeding is present, testsfor disseminated intravascular coagulation shouldinclude fibrinogen, d-dimer assay, platelet count,peripheral smear for schistocytes, prothrombin time,and partial thromboplastin time.
Manifestations of Sepsis
Temperature instability Respiratory alkaloses Increased serum lactate Altered mental status Leukocytosis and increased neutrophil concentration Peripheral vasodilation EosinopeniaThrombocytopeniaAnemiaProteinuriaMildly elevated serum biliru-bin levels III. Treatment of septic shock
A. Early management of septic shock is aimed at
restoring mean arterial pressure to 65 to 75 mm Hgto improve organ perfusion. Continuous SVO2 monitoring is recommended to insure optimal organperfusion at the cellular level. Clinical clues toadequate tissue perfusion include skin temperature,mental status, and urine output. Urine output shouldbe maintained at >20 to 30 mL/hr. Lactic acid levelsshould decrease within 24 hours if therapy is effec-tive.
B. Intravenous access and monitoring
1. Intravenous access is most rapidly obtained
through peripheral sites with two 16- to 18-gaugecatheters. More stable access can be achievedlater with central intravenous access. Placementof a large-bore introducer catheter in the rightinternal jugular or left subclavian vein allows themost rapid rate of infusion.
2. Arterial lines should be placed to allow for more
reliable monitoring of blood pressure. Pulmonaryartery catheters measure cardiac output, systemicvascular resistance, pulmonary artery wedgepressure, and mixed venous oxygen saturation.
These data are useful in providing rapid assess-ment of response to various therapies.
C. Fluids
1. Aggressive volume resuscitation is essential in
treatment of septic shock. Most patients require 4to 8 L of crystalloid. Fluid should be administeredas a bolus. The mean arterial pressure should beincreased to 65 to 75 mm Hg and organ perfusionshould be improved within 1 hour of the onset ofhypotension.
2. Repeated boluses of crystalloid (isotonic sodium
chloride solution or lactated Ringer's injection),500 to 1,000 mL, should be given intravenouslyover 5 to 10 minutes, until mean arterial pressureand tissue perfusion are adequate (about 4 to 8 Ltotal over 24 hours for the typical patient). Bolusesof 250 mL are appropriate for patients who areelderly or who have heart disease or suspectedpulmonary edema. Red blood cells should bereserved for patients with a hemoglobin value ofless than 10 g/dL and either evidence of de-creased oxygen delivery or significant risk fromanemia (eg, coronary artery disease). D. Vasoactive agents
1. Patients who do not respond to fluid therapy
should receive vasoactive agents. The primarygoal is to increase mean arterial pressure to 65 to75 mm Hg.
2. Dopamine (Intropin) traditionally has been used
as the initial therapy in hypotension, primarilybecause it is thought to increase systemic bloodpressure. However, dopamine is a relatively weakvasoconstrictor in septic shock.
Hemodynamic effects of vasoactive agents
3. Norepinephrine (Levophed) is superior to
dopamine in the treatment of hypotension associ-ated with septic shock. Norepinephrine is theagent of choice for treatment of hypotensionrelated to septic shock. 4. Dobutamine (Dobutrex) should be reserved for
patients with a persistently low cardiac index orunderlying left ventricular dysfunction.
E. Antibiotics should be administered within 2 hours
of the recognition of sepsis. Use of vancomycinshould be restricted to settings in which the caus-ative agent is most likely resistant Enterococcus,methicillin-resistant Staphylococcus aureus, orhigh-level penicillin-resistant Streptococcuspneumoniae. Recommended Antibiotics in Septic Shock
Recommended antibiotics
Third or 4th-generation cephalosporin(cefepime, ceftazidime, cefotaxime,ceftizoxime) plus macrolide(antipseudomonal beta lactam plusaminoglycoside if hospital-acquired) + an-aerobic coverage with metronidazole orclindamycin.
Ampicillin plus gentamicin (Garamycin) orthird-generation cephalosporin (ceftazidime,cefotaxime, ceftizoxime) or a quinolone(ciprofloxacin, levofloxacin).
Nafcillin (add metronidazole [Flagyl] or clindamycin if anaerobic infection suspected) Third-generation cephalosporin (ceftazidime,cefotaxime, ceftizoxime) Third-generation cephalosporin (ceftazidime, cefotaxime, ceftizoxime) plus metronidazoleor clindamycin Ticarcillin/clavulanate (Timentin) or Dosages of Antibiotics Used in Sepsis
Cefepime (Maxipime) 2 gm IV q12h; if neutropenic,use 2 gm q8h Ceftizoxime (Cefizox) Ceftazidime (Fortaz) Cefotaxime (Claforan) Cefuroxime (Kefurox, Cefoxitin (Mefoxin) Cefotetan (Cefotan) 3.375-4.5 gm IV q6h 3.1 gm IV q4-6h (200-300 Nafcillin (Nafcil) Meropenem (Merrem) 2 mg/kg IV loading dose, then Amikacin (Amikin) 7.5 mg/kg IV loading dose, then5 mg/kg IV q8h Metronidazole (Flagyl) Clindamycin (Cleocin) 600-900 mg IV q8h Linezolid (Zyvox) 600 mg IV/PO q12h 1. Initial treatment of life-threatening sepsis
usually consists of a third or 4th-generationcephalosporin (cefepime, ceftazidime, cefotaxime,ceftizoxime) or piperacillin/tazobactam (Zosyn).
An aminoglycoside (gentamicin, tobramycin, oramikacin) should also be included.
Antipseudomonal coverage is important forhospital- or institutional-acquired infections.
Appropriate choices include an antipseudomonalpenicillin, cephalosporin, or an aminoglycoside.
2. Methicillin-resistant staphylococci. If line
sepsis or an infected implanted device is a possi-bility, vancomycin should be added to the regimento cover for methicillin-resistant Staph aureus andmethicillin-resistant Staph epidermidis.
3. Vancomycin-resistant enterococcus (VRE):
An increasing number of enterococcal strains are
resistant to ampicillin and gentamicin. The inci-
dence of vancomycin-resistant enterococcus
(VRE) is rapidly increasing.
a. Linezolid (Zyvox) is an oral or parenteral
agent active against vancomycin-resistantenterococci, including E. faecium and E.
faecalis. Linezolid is also active againstmethicillin-resistant staphylococcus aureus.
b. Quinupristin/dalfopristin (Synercid) is a
parenteral agent active against strains ofvancomycin-resistant enterococcus faecium,but not enterococcus faecalis. Most strains ofVRE are enterococcus faecium.
F. Other therapies
1. Hydrocortisone (100 mg every 8 hours) in
patients with refractory shock significantly im-proves hemodynamics and survival rates.
Corticosteroids may be beneficial in patients withrefractory shock caused by an Addison's crisis.
2. Activated protein C (drotrecogin alfa [Xigris])
has antithrombotic, profibrinolytic, andanti-inflammatory properties. Activated protein Creduces the risk of death by 20%. Activatedprotein C is approved for treatment of patientswith severe sepsis who are at high risk of death.
Drotrecogin alfa is administered as 24 mcg/kg/hrfor 96 hours. There is a small risk of bleeding.
Contraindications are thrombocytopenia, coagulopathy, recent surgery or recent hemor-rhage.
I. Acute Peritonitis
A. Acute peritonitis is inflammation of the peritoneum or
peritoneal fluid from bacteria or intestinal contents inthe peritoneal cavity. Secondary peritonitis resultsfrom perforation of a viscus caused by acute appendi-citis or diverticulitis, perforation of an ulcer, or trauma.
Primary peritonitis refers to peritonitis arising withouta recognizable preceding cause. Tertiary peritonitisconsists of persistent intra-abdominal sepsis withouta discrete focus of infection, usually occurring aftersurgical treatment of peritonitis.
B. Clinical features
1. Acute peritonitis presents with abdominal pain,
abdominal tenderness, and the absence of bowelsounds. Severe, sudden-onset abdominal painsuggests a ruptured viscus. Signs of peritonealirritation include abdominal tenderness, reboundtenderness, and abdominal rigidity. 2. In severe cases, fever, hypotension, tachycardia,
and acidosis may occur. Spontaneous bacterialperitonitis arising from ascites will often presentwith only subtle signs.
C. Diagnosis
1. Plain abdominal radiographs and a chest x-ray
may detect free air in the abdominal cavity causedby a perforated viscus. CT and/or ultrasonographycan identify the presence of free fluid or an ab-scess.
2. Paracentesis
a. Tube 1 - Cell count and differential (1-2 mL,
EDTA purple top tube) b. Tube 2 - Gram stain of sediment; C&S, AFB,
fungal C&S (3-4 mL); inject 10-20 mL intoanaerobic and aerobic culture bottle at thebedside.
c. Tube 3 - Glucose, protein, albumin, LDH,
triglyceride, specific gravity, amylase, (2-3 mL,red top tube). Serum/fluid albumin gradientshould be determined. d. Syringe - pH (3 mL).
D. Treatment of acute peritonitis
1. Resuscitation with intravenous fluids and correc-
tion of metabolic and electrolyte disturbances arethe initial steps. Laparotomy is a cornerstone oftherapy for secondary or tertiary acute peritonitis.
2. Broad-spectrum systemic antibiotics are critical to
cover bowel flora, including anaerobic species.
3. Mild to moderate infection (community-ac-
quired)
a. Cefotetan (Cefotan) 1-2 gm IV q12h OR
b. Ampicillin/sulbactam (Unasyn) 3.0 gm IV q6h
c. Ticarcillin/clavulanate (Timentin) 3.1 gm IV q6h
4. Severe infection (hospital-acquired)
a. Cefepime (Maxipime) 2 gm IV q12h and
metronidazole (Flagyl) 500 mg IV q6h OR
b. Piperacillin/tazobactam (Zosyn) 3.375 gm IV
c. Imipenem/cilastatin (Primaxin) 1 g IV q6h OR
d. Ciprofloxacin (Cipro) 400 mg IV q12h and
clindamycin 600 mg IV q8h OR
e. Gentamicin or tobramycin 100-120 mg (1.5
mg/kg); then 80 mg IV q8h (3-5 mg/kg/d) andmetronidazole (Flagyl) 500 mg IV q6h. II. Spontaneous bacterial peritonitis
A. SBP, which has no obvious precipitating cause,
occurs almost exclusively in cirrhotic patients B. Diagnosis
1. Spontaneous bacterial peritonitis is diagnosed by
paracentesis in which the ascitic fluid is found tohave 250 or more polymorphonuclear (PMN) cellsper cubic millimeter.
C. Therapy
1. Antibiotics are the cornerstone of managing SBP,
and laparotomy has no place in therapy for SBP,unless perforation is present. Three to 5 days ofintravenous treatment with broad-spectrum antibi-otics is usually adequate, at which time efficacycan be determined by estimating the ascitic fluidPMN cell count.
2. Option 1:
a. Cefotaxime (Claforan) 2 gm IV q4-6h
3. Option 2:
a. Ticarcillin/clavulanate (Timentin) 3.1 gm IV q6h
b. Piperacillin/tazobactam (Zosyn) 3.375 gm IV
q6h or 4.5 gm IV q8h.
4. Option 3 if extended-spectrum beta-lactamase
(ESBL):
a. Imipenem/cilastatin (Primaxin) 1.0 gm IV q6h.
b. Ciprofloxacin (Cipro) 400 mg IV q12h OR
c. Levofloxacin (Levaquin) 500 mg IV q24h.
Michael Krutzik, MDH.L. Daneschvar, MDS.E. Wilson, MDRoham T. Zamanian, MD Upper Gastrointestinal Bleeding
When bleeding is believed to be caused by a sourceproximal to the ligament of Treitz or the source of bleedingis indeterminant, flexible upper gastrointestinal endoscopyis indicated after initial resuscitation and stabilization.
I. Clinical evaluation
A. Initial evaluation of upper GI bleeding should estimate
the severity, duration, location, and cause of bleed-ing. A history of bleeding occurring after forcefulvomiting suggests Mallory-Weiss Syndrome.
B. Abdominal pain, melena, hematochezia (bright red
blood per rectum), history of peptic ulcer, cirrhosis orprior bleeding episodes may be present.
C. Precipitating factors. Use of aspirin, nonsteroidal
anti-inflammatory drugs, alcohol, or anticoagulantsshould be sought.
II. Physical examination
A. General: Pallor and shallow, rapid respirations may
be present; tachycardia indicates a 10% bloodvolume loss. Postural hypotension (increase in pulseof 20 and a systolic blood pressure fall of 10-15mmHg), indicates a 20-30% loss.
B. Skin: Delayed capillary refill and stigmata of liver dis-
ease (jaundice, spider angiomas, parotid gland hy-pertrophy) should be sought.
C. Abdomen: Scars, tenderness, masses, hepatomeg-
aly, and dilated abdominal veins should be evaluated.
Stool occult blood should be checked.
III. Laboratory evaluation: CBC, SMA 12, liver function
tests, amylase, INR/PTT, type and cross for pRBC,ECG.
IV. Differential diagnosis of upper bleeding: Peptic
ulcer, gastritis, esophageal varices, Mallory-Weiss tear,esophagitis, swallowed blood from epistaxis, malig-nancy (esophageal, gastric), angiodysplasias, aorto-en-teric fistula, hematobilia.
V. Management of upper gastrointestinal bleeding
A. If the bleeding appears to have stopped or has
significantly slowed, medical therapy with H2blockers and saline lavage is usually all that isrequired.
B. Two 14- to16-gauge IV lines should be placed.
Normal saline solution should be infused until bloodis ready, then transfuse 2-6 units of pRBCs as fastas possible.
C. A large bore nasogastric tube should be placed,
followed by lavage with 2 L of room temperature tapwater. The tube should then be connected to lowintermittent suction, and the lavage should berepeated hourly. The NG tube may be removedwhen bleeding is no longer active.
D. Oxygen is administered by nasal cannula. Urine
output should be monitored.
E. Serial hematocrits should be checked and main-
tained greater than 30%. Coagulopathy should beassessed and corrected with fresh frozen plasma,vitamin K, cryoprecipitate, and platelets.
F. Definitive diagnosis requires upper endoscopy, at
which time electrocoagulation, banding, and/or localinjection of vasoconstrictors at bleeding sites maybe completed. Surgical consultation should berequested in unstable patients or patients whorequire more than 6 units of pRBCs.
Clinical Indicators of Gastrointestinal Bleeding
and Probable Source
VI. Peptic Ulcer Disease
A. Peptic ulcer disease is the commonest cause of
upper gastrointestinal bleeding, responsible for 27-40% of all upper gastrointestinal bleeding episodes.
Duodenal ulcer is more frequent than gastric ulcer.
Three fourths of all peptic ulcer hemorrhages sub-side spontaneously.
B. Upper gastrointestinal endoscopy is the most effec-
tive diagnostic technique for peptic ulcer disease.
Endoscopic therapy is the method of choice forcontrolling active ulcer hemorrhage.
C. Proton-pump inhibitor administration is effective
in decreasing rebleeding rates with bleeding ulcers.
Therapy consists of intravenous pantoprazole.
1. Pantoprazole (Protonix) dosage is 80 mg IV,
followed by continuous infusion with 8 mg/hr,then 40 mg PO bid when active bleeding hassubsided.
2. Twice daily dosing of oral proton pump inhibitors
may be a reasonable alternative when intrave-nous formulations are not available. Oralomeprazole (Prilosec) for duodenal ulcer: 20 mgqd for 4-8 weeks. Gastric ulcers: 20 mg bid.
Lansoprazole (Prevacid), 15 mg qd.
Esomeprazole (Nexium) 20-40 mg qd.
D. Indications for surgical operation include (1)
severe hemorrhage unresponsive to initialresuscitative measures; (2) failure of endoscopic orother nonsurgical therapies; and (3) perforation,obstruction, or suspicion of malignancy.
E. Duodenal ulcer hemorrhage. Suture ligation of the
ulcer-associated bleeding artery combined with avagotomy is indicated for duodenal ulcer hemor-rhage that does not respond to medical therapy.
Truncal vagotomy and pyloroplasty is widely usedbecause it is rapidly and easily accomplished.
F. Gastric ulcer hemorrhage is most often managed
by truncal vagotomy and pyloroplasty with wedgeexcision of ulcer.
G. Transcatheter angiographic embolization of the
bleeding artery responsible for ulcer hemorrhage isrecommended in patients who fail endoscopicattempts at control and who are poor surgical candi-dates.
VII. Hemorrhagic Gastritis
A. The diffuse mucosal inflammation of gastritis rarely
manifest as severe or life-threatening hemorrhage.
Hemorrhagic gastritis accounts for 4% of uppergastrointestinal hemorrhage. The bleeding is usuallymild and self-limited. When coagulopathy accompa-nies cirrhosis and portal hypertension, however,gastric mucosal bleeding can be brisk and refrac-tory.
B. Endoscopic therapy can be effective for multiple
punctate bleeding sites, but when diffuse mucosalhemorrhage is present, selective intra-arterialinfusion of vasopressin may control bleeding. Forthe rare case in which surgical intervention is re-quired, total gastrectomy is the most effectiveprocedure.
A. This disorder is defined as a mucosal tear at the
gastroesophageal junction following forceful retchingand vomiting.
B. Treatment is supportive, and the majority of patients
stop bleeding spontaneously. Endoscopic coagula-tion or operative suturing may rarely be necessary.
Esophageal varices eventually develop in most patientswith cirrhosis, but variceal bleeding occurs in only one thirdof them. The initiating event in the development of portalhypertension is increased resistance to portal outflow.
Causes of Portal Hypertension
Extrahepatic causes
Portal vein thrombosis
Extrinsic compression of the portal vein
Cavernous transformation of the portal vein
Intrahepatic causes
Sarcoidosis
Primary biliary cirrhosis
Hepatoportal sclerosis Schistosomiasis Sinusoidal: Cirrhosis, alcoholic hepatitis
Postsinusoidal
Budd-Chiari syndrome (hepatic vein thrombosis)Veno-occlusive diseaseSevere congestive heart failureRestrictive heart disease A. Varices develop annually in 5% to 15% of patients
with cirrhosis, and varices enlarge by 4% to 10%each year. Each episode of variceal hemorrhagecarries a 20% to 30% risk of death.
B. After an acute variceal hemorrhage, bleeding re-
solves spontaneously in 50% of patients. Bleeding isleast likely to stop in patients with large varices anda Child-Pugh class C cirrhotic liver.
II. Management of variceal hemorrhage
A. Primary prophylaxis
1. All patients with cirrhosis should undergo endos-
copy to screen for varices every 2 to 3 years.
2. Propranolol (Inderal) and nadolol (Corgard) re-
duce portal pressure through beta blockade.
Beta-blockade reduces the risk of bleeding by45% and bleeding-related death by 50%. Thebeta-blocker dose is adjusted to decrease theresting heart rate by 25% from its baseline, but notto less than 55 to 60 beats/min. 3. Propranolol (Inderal) is given at 10 to 480 mg
daily, in divided doses, or nadolol (Corgard) 40 to320 mg daily in a single dose.
B. Treatment of acute hemorrhage
1. Variceal bleeding should be considered in any
patient who presents with significant upper gastro-intestinal bleeding. Signs of cirrhosis may includespider angiomas, palmar erythema, leukonychia,clubbing, parotid enlargement, and Dupuytren'scontracture. Jaundice, lower extremity edema andascites are indicative of decompensated liverdisease.
2. The severity of the bleeding episode can be
assessed on the basis of orthostatic changes (eg,resting tachycardia, postural hypotension), whichindicates one-third or more of blood volume loss.
3. Blood should be replaced as soon as possible.
While blood for transfusion is being made avail-able, intravascular volume should be replenishedwith normal saline solution. Once euvolemia isestablished, the intravenous infusion should bechanged to solutions with a lower sodium content(5% dextrose with 1/2 or 1/4 normal saline). Bloodshould be transfused to maintain a hematocrit ofat least 30%. Serial hematocrit estimations shouldbe obtained during continued bleeding.
4. Fresh frozen plasma is administered to patients
who have been given massive transfusions. Each3 units of PRBC should be accompanied byCaCL 1 gm IV over 30 min. Clotting factors should be assessed. Platelet transfusions arereserved for counts below 50,000/mL in an ac-tively bleeding patient.
5. If the patient's sensorium is altered because of
hepatic encephalopathy, the risk of aspirationmandates endotracheal intubation. Placement ofa large-caliber nasogastric tube (22 F or 24 F)permits tap water lavage for removal of blood andclots in preparation for endoscopy.
6. Octreotide acetate (Sandostatin) is a synthetic,
analogue of somatostatin, which causessplanchnic vasoconstriction. Octreotide is the drugof choice in the pharmacologic management ofacute variceal bleeding. Octreotide infusion shouldbe started with a loading dose of 50 micrograms,followed by an infusion of 50 micrograms/hr.
Treatment is continued until hemorrhage sub-sides. Definitive endoscopic therapy is performedshortly after hemostasis is achieved.
7. Endoscopic therapy
a. A sclerosant (eg, morrhuate [Scleromate]) is
injected into each varix. Complications includebleeding ulcers, dysphagia due to strictures,and pleural effusions.
b. Endoscopic variceal ligation with elastic bands
is an alternative to sclerotherapy because offewer complications and similar efficacy.
c. If bleeding persists (or recurs within 48 hours
of the initial episode) despite pharmacologictherapy and two endoscopic therapeutic at-tempts at least 24 hours apart, patients shouldbe considered for salvage therapy with TIPS orsurgical treatment (transection of esophagealvarices and devascularization of the stomach,portacaval shunt, or liver transplantation).
8. Transjugular intrahepatic portosystemic shunt
(TIPS) consists of the angiographic creation of a
shunt between hepatic and portal veins which iskept open by a fenestrated metal stent. It decom-presses the portal system, controlling activevariceal bleeding over 90% of the time. Complica-tions include secondary bleeding, worseningencephalopathy in 20%, and stent thrombosis orstenosis.
C. Secondary prophylaxis
1. A patient who has survived an episode of variceal
hemorrhage has an overall risk of rebleeding thatapproaches 70% at 1 year.
2. Endoscopic sclerotherapy decreases the risk of
rebleeding (50% versus 70%) and death (30% to60% versus 50% to 75%). Endoscopic varicealligation is superior to sclerotherapy. Banding iscarried out every 2 to 3 weeks until obliteration.
Lower Gastrointestinal Bleeding
The spontaneous remission rates for lower gastrointestinalbleeding is 80 percent. No source of bleeding can beidentified in 12 percent of patients, and bleeding is recur-rent in 25 percent. Bleeding has usually ceased by the timethe patient presents to the emergency room.
I. Clinical evaluation
A. The severity of blood loss and hemodynamic status
should be assessed immediately. Initial managementconsists of resuscitation with crystalloid solutions(lactated Ringers) and blood products if necessary.
B. The duration and quantity of bleeding should be
assessed; however, the duration of bleeding is oftenunderestimated.
C. Risk factors that may have contributed to the bleed-
ing include nonsteroidal anti-inflammatory drugs,anticoagulants, colonic diverticulitis, renal failure,coagulopathy, colonic polyps, and hemorrhoids.
Patients may have a prior history of hemorrhoids,diverticulosis, inflammatory bowel disease, pepticulcer, gastritis, cirrhosis, or esophageal varices.
D. Hematochezia. Bright red or maroon output per
rectum suggests a lower GI source; however, 12 to20% of patients with an upper GI bleed may havehematochezia as a result of rapid blood loss.
E. Melena. Sticky, black, foul-smelling stools suggest a
source proximal to the ligament of Treitz, but Melenacan also result from bleeding in the small intestine orproximal colon.
F. Clinical findings
1. Abdominal pain may result from ischemic bowel,
inflammatory bowel disease, or a ruptured aneu-rysm. 2. Painless massive bleeding suggests vascular
bleeding from diverticula, angiodysplasia, or hem-orrhoids.
3. Bloody diarrhea suggests inflammatory bowel
disease or an infectious origin.
4. Bleeding with rectal pain is seen with anal fis-
sures, hemorrhoids, and rectal ulcers.
5. Chronic constipation suggests hemorrhoidal
bleeding. New onset of constipation or thin stoolssuggests a left sided colonic malignancy.
6. Blood on the toilet paper or dripping into the toilet
water suggests a perianal source of bleeding, suchas hemorrhoids or an anal fissure.
7. Blood coating the outside of stools suggests a
lesion in the anal canal.
8. Blood streaking or mixed in with the stool may
results from polyps or a malignancy in the de-scending colon.
9. Maroon colored stools often indicate small bowel
and proximal colon bleeding.
II. Physical examination
A. Postural hypotension indicates a 20% blood volume
loss, whereas, overt signs of shock (pallor,hypotension, tachycardia) indicates a 30 to 40 per-cent blood loss.
B. The skin may be cool and pale with delayed refill if
bleeding has been significant.
C. Stigmata of liver disease, including jaundice, caput
medusae, gynecomastia and palmar erythema,should be sought because patients with these find-ings frequently have GI bleeding.
Differential diagnosis of lower GI bleeding
A. Angiodysplasia and diverticular disease of the right
colon accounts for the vast majority of episodes ofacute lower GI bleeding. Most acute lower GI bleed-ing originates from the colon however 15 to 20percent of episodes arise from the small intestine andthe upper GI tract.
B. Elderly patients. Diverticulosis and angiodysplasia
are the most common causes of lower GI bleeding.
C. Younger patients. Hemorrhoids, anal fissures and
inflammatory bowel disease are most commoncauses of lower GI bleeding.
Clinical Indicators of Gastrointestinal Bleeding
and Probable Source
Probability of Up-
nal source
Diagnosis and management of lower gastrointes-
tinal bleeding
A. Rapid clinical evaluation and resuscitation should
precede diagnostic studies. Intravenous fluids (1 to 2liters) should be infused over 10- 20 minutes torestore intravascular volume, and blood should betransfused if there is rapid ongoing blood loss or ifhypotension or tachycardia are present.
Coagulopathy is corrected with fresh frozen plasma,platelets, and cryoprecipitate.
B. When small amounts of bright red blood are passed
per rectum, then lower GI tract can be assumed to bethe source. In patients with large volume maroonstools, nasogastric tube aspiration should be per-formed to exclude massive upper gastrointestinalhemorrhage.
C. If the nasogastric aspirate contains no blood then
anoscopy and sigmoidoscopy should be performed todetermine weather a colonic mucosal abnormality(ischemic or infectious colitis) or hemorrhoids mightbe the cause of bleeding.
D. Colonoscopy in a patient with massive lower GI
bleeding is often nondiagnostic, but it can detectulcerative colitis, antibiotic-associated colitis, orischemic colon.
E. Polyethylene glycol-electrolyte solution (CoLyte or
GoLytely) should be administered by means of anasogastric tube (Four liters of solution is given overa 2-3 hour period), allowing for diagnostic and thera-peutic colonoscopy.
V. Definitive management of lower gastrointestinal
1. Colonoscopy is the procedure of choice for diag-
nosing colonic causes of GI bleeding. It should beperformed after adequate preparation of the bowel.
If the bowel cannot be adequately prepared be-cause of persistent, acute bleeding, a bleedingscan or angiography is preferable.
2. If colonoscopy fails to reveal the source of the
bleeding, the patient should be observed because,in 80% of cases, bleeding ceases spontaneously.
B. Radionuclide scan or bleeding scan. Technetium-
labeled (tagged) red blood cell bleeding scans candetect bleeding sites when bleeding is intermittent.
Localization may not he a precise enough to allowsegmental colon resection.
C. Angiography. Selective mesenteric angiography
detects arterial bleeding that occurs at rates of 0.5mL/per minute or faster. Diverticular bleeding causespooling of contrast medium within a diverticulum.
Bleeding angiodysplastic lesions appear as abnormalvasculature. When active bleeding is seen withdiverticular disease or angiodysplasia, selectivearterial infusion of vasopressin may be effective.
D. Surgery
1. If bleeding continues and no source can be found,
surgical intervention is usually warranted. Surgicalresection may be indicated for patients with recur-rent diverticular bleeding, or for patients who havehad persistent bleeding from colonicangiodysplasia and have required blood transfu-sions.
2. Surgical management of lower gastrointestinal
bleeding is ideally undertaken with a secure knowl-edge of the location and cause of the bleedinglesion. A segmental bowel resection to include thelesion and followed by a primary anastomosis isusually safe and appropriate in all but the mostunstable patients.
A. Diverticulosis of the colon is present in more than
50% of the population by age 60 years. Bleeding fromdiverticula is relatively rare, affecting only 4% to 17%of patients at risk. B. In most cases, bleeding ceases spontaneously, but in
10% to 20% of cases, the bleeding continues. Therisk of rebleeding after an episode of bleeding is 25%.
Right-sided colonic diverticula occur less frequentlythan left-sided or sigmoid diverticula but are responsi-ble for a disproportionate incidence of diverticularbleeding.
C. Operative management of diverticular bleeding is
indicated when bleeding continues and is not amena-ble to angiographic or endoscopic therapy. It alsoshould be considered in patients with recurrentbleeding in the same colonic segment. The operationusually consists of a segmental bowel resection(usually a right colectomy or sigmoid colectomy)followed by a primary anastomosis.
VII. Arteriovenous malformations
A. AVMs or angiodysplasias are vascular lesions that
occur primarily in the distal ileum, cecum, and as-cending colon of elderly patients. The arteriographiccriteria for identification of an AVM include a cluster ofsmall arteries, visualization of a vascular tuft, andearly and prolonged filling of the draining vein.
B. The typical pattern of bleeding of an AVM is recurrent
and episodic, with most individual bleeding episodesbeing self-limited. Anemia is frequent, and continuedmassive bleeding is distinctly uncommon. Afternondiagnostic colonoscopy, enteroscopy should beconsidered.
C. Endoscopic therapy for AVMs may include heater
probe, laser, bipolar electrocoagulation, or argonbeam coagulation. Operative management is usuallyreserved for patients with continued bleeding, ane-mia, repetitive transfusion requirements, and failure ofendoscopic management. Surgical managementconsists of segmental bowel resection with primaryanastomosis.
VIII. Inflammatory bowel disease
A. Ulcerative colitis and, less frequently, Crohn's colitis
or enteritis may present with major or massive lowergastrointestinal bleeding. Infectious colitis can alsomanifest with bleeding, although it is rarely massive.
B. When the bleeding is minor to moderate, therapy
directed at the inflammatory condition is appropriate.
When the bleeding is major and causeshemodynamic instability, surgical intervention isusually required. When operative intervention isindicated, the patient is explored through a midlinelaparotomy, and a total abdominal colectomy with endileostomy and oversewing of the distal rectal stump isthe preferred procedure.
Tumors of the colon and rectum
A. Colon and rectal tumors account for 5% to 10% of all
hospitalizations for lower gastrointestinal bleeding.
Visible bleeding from a benign colonic or rectal polypis distinctly unusual. Major or massive hemorrhagerarely is caused by a colorectal neoplasm; however,chronic bleeding is common. When the neoplasm isin the right colon, bleeding is often occult and mani-fests as weakness or anemia. B. More distal neoplasms are often initially confused with
hemorrhoidal bleeding. For this reason, the treatmentof hemorrhoids should always be preceded by flexiblesigmoidoscopy in patients older than age 40 or 50years. In younger patients, treatment of hemorrhoidswithout further investigation may be appropriate ifthere are no risk factors for neoplasm, there is aconsistent clinical history, and there is anoscopicevidence of recent bleeding from enlarged internalhemorrhoids.
X. Anorectal disease
A. When bleeding occurs only with bowel movements
and is visible on the toilet tissue or the surface of thestool, it is designated outlet bleeding. Outlet bleedingis most often associated with internal hemorrhoids oranal fissures.
B. Anal fissures are most commonly seen in young
patients and are associated with severe pain duringand after defecation. Other benign anorectal bleedingsources are proctitis secondary to inflammatory boweldisease, infection, or radiation injury. Additionally,stercoral ulcers can develop in patients with chronicconstipation.
C. Surgery for anorectal problems is typically undertaken
only after failure of conservative medical therapy withhigh-fiber diets, stool softeners, and/orhemorrhoidectomy.
A. Ischemic colitis is seen in elderly patients with known
vascular disease. The abdomen pain may be post-prandial and associated with bloody diarrhea or rectalbleeding. Severe blood loss is unusual but can occur.
B. Abdominal films may reveal "thumb-printing" caused
by submucosal edema. Colonoscopy reveals a well-demarcated area of hyperemia, edema and mucosalulcerations. The splenic flexure and descending colonare the most common sites. Most episodes resolvespontaneously, however, vascular bypass or resec-tion may be required.
The incidence of acute pancreatitis ranges from 54 to 238episodes per 1 million per year. Patients with mild pancre-atitis respond well to conservative therapy, but those withsevere pancreatitis may have a progressively downhillcourse to respiratory failure, sepsis, and death (less than10%).
I. Etiology
A. Alcohol-induced pancreatitis. Consumption of large
quantities of alcohol may cause acute pancreatitis. B. Cholelithiasis. Common bile duct or pancreatic duct
obstruction by a stone may cause acute pancreatitis.
(90% of all cases of pancreatitis occur secondary toalcohol consumption or cholelithiasis).
C. Idiopathic pancreatitis. The cause of pancreatitis
cannot be determined in 10 percent of patients.
D. Hypertriglyceridemia. Elevation of serum triglycer-
ides (>l,000mg/dL) has been linked with acute pan-creatitis.
E. Pancreatic duct disruption. In younger patients, a
malformation of the pancreatic ducts (eg, pancreaticdivisum) with subsequent obstruction is often thecause of pancreatitis. In older patients without anapparent underlying etiology, cancerous lesions ofthe ampulla of Vater, pancreas or duodenum must beruled out as possible causes of obstructive pancreati-tis.
F. Iatrogenic pancreatitis. Radiocontrast studies of the
hepatobiliary system (eg, cholangiogram, ERCP) cancause acute pancreatitis in 2-3% of patients undergo-ing studies.
G. Trauma. Blunt or penetrating trauma of any kind to
the peri-pancreatic or peri-hepatic regions mayinduce acute pancreatitis. Extensive surgical manipu-lation can also induce pancreatitis during laparotomy.
Causes of Acute Pancreatitis
Idiopathic causes Medications Associated with Acute Pancreatitis
Azathioprine (Imuran) Thiazide diuretics Furosemide (Lasix) Valproic acid (Depakote) Didanosine (Videx) II. Pathophysiology. Acute pancreatitis results when an
initiating event causes the extrusion of zymogen gran-ules, from pancreatic acinar cells, into the interstitium ofthe pancreas. Zymogen particles cause the activation oftrypsinogen into trypsin. Trypsin causes auto-digestionof pancreatic tissues.
III. Clinical presentation
A. Signs and symptoms. Pancreatitis usually presents
with mid-epigastric pain that radiates to the back,associated with nausea and vomiting. The pain issudden in onset, progressively increases in intensity,and becomes constant. The severity of pain oftencauses the patient to move continuously in search ofa more comfortable position.
B. Physical examination
1. Patients with acute pancreatitis often appear very
ill. Findings that suggest severe pancreatitisinclude hypotension and tachypnea with de-creased basilar breath sounds. Flank ecchymoses(Grey Tuner's Sign) or periumbilical ecchymoses(Cullen's sign) may be indicative of hemorrhagicpancreatitis.
2. Abdominal distension and tenderness in the
epigastrium are common. Fever and tachycardiaare often present. Guarding, rebound tenderness,and hypoactive or absent bowel sounds indicateperitoneal irritation. Deep palpation of abdominal organs should be avoided in the setting of sus-pected pancreatitis.
IV. Laboratory testing
A. Leukocytosis. An elevated WBC with a left shift and
elevated hematocrit (indicating hemoconcentration)and hyperglycemia are common. Pre-renal azotemiamay result from dehydration. Hypoalbuminemia,h y p e r t r i g l y c e r i d e m i a , h y p o c a l c e m i a ,hyperbilirubinemia, and mild elevations of trans-aminases and alkaline phosphatase are common.
B. Elevated amylase. An elevated amylase level often
confirms the clinical diagnosis of pancreatitis.
C. Elevated lipase. Lipase measurements are more
specific for pancreatitis than amylase levels, but lesssensitive. Hyperlipasemia may also occur in patientswith renal failure, perforated ulcer disease, bowelinfarction and bowel obstruction.
D. Abdominal Radiographs may reveal non-specific
findings of pancreatitis, such as "sentinel loops"(dilated loops of small bowel in the vicinity of thepancreas), ileus and, pancreatic calcifications.
E. Ultrasonography demonstrates the entire pancreas
in only 20 percent of patients with acute pancreatitis.
Its greatest utility is in evaluation of patients withpossible gallstone disease.
F. Helical high resolution computed tomography is
the imaging modality of choice in acute pancreatitis.
CT findings will be normal in 14-29% of patients withmild pancreatitis. Pancreatic necrosis, pseudocystsand abscesses are readily detected by CT.
Selected Conditions Other Than Pancreatitis
Associated with Amylase Elevation
Carcinoma of the pancreas Common bile duct obstruc- Diabetic ketoacidosis Mesenteric infarction Pancreatic trauma Ruptured ectopic pregnancy Perforated viscus Salivary gland infection V. Prognosis. Ranson's criteria is used to determine
prognosis in acute pancreatitis. Patients with two orfewer risk factors have a mortality rate of less than 1percent, those with three or four risk-factors a mortalityrate of 16 percent, five or six risk factors, a mortalityrate of 40 percent, and seven or eight risk factors, amortality rate approaching 100 percent.
Ranson's Criteria for Acute Pancreatitis
At admission
During initial 48 hours
1. Age >55 years 1. Hematocrit drop >10% 2. WBC >16,000/mm3 2. BUN rise >5 mg/dL 3. Blood glucose >200 3. Arterial pO <60 mm Hg 4. Base deficit >4 mEq/L 4. Serum LDH >350 IU/L 5. Serum calcium <8.0 mg/dL 5. AST >250 U/L 6. Estimated fluid sequestration>6 L VI. Treatment of pancreatitis
A. Expectant management. Most cases of acute
pancreatitis will improve within three to seven days.
Management consists of prevention of complicationsof severe pancreatitis.
B. NPO and bowel rest. Patients should take nothing
by mouth. Total parenteral nutrition should beinstituted for those patients fasting for more than fivedays. A nasogastric tube is warranted if vomiting orileus.
C. IV fluid resuscitation. Vigorous intravenous
hydration is necessary. A decrease in urine outputto less than 30 mL per hour is an indication ofinadequate fluid replacement.
D. Pain control. Morphine is discouraged because it
may cause Oddi's sphincter spasm, which mayexacerbate the pancreatitis. Meperidine (Demerol),25-100 mg IV/IM q4-6h, is favored. Ketorolac(Toradol), 60 mg IM/IV, then 15-30 mg IM/IV q6h, isalso used.
E. Antibiotics. Routine use of antibiotics is not recom-
mended in most cases of acute pancreatitis. Incases of infectious pancreatitis, treatment withcefoxitin (1-2 g IV q6h), cefotetan (1-2 g IV q12h),imipenem (1.0 gm IV q6h), or ampicillin/sulbactam(1.5-3.0 g IV q6h) may be appropriate.
F. Alcohol withdrawal prophylaxis. Alcoholics may
require alcohol withdrawal prophylaxis withlorazepam (Ativan) 1-2mg IM/IV q4-6h as needed x3 days, thiamine 100mg IM/IV qd x 3 days, folic acid1 mg IM/IV qd x 3 days, multivitamin qd.
G. Octreotide. Somatostatin is also a potent inhibitor
of pancreatic exocrine secretion. Octreotide is asomatostatin analogue, which has been effective inreducing mortality from bile-induced pancreatitis.
Clinical trials, however, have failed to document asignificant reduction in mortality H. Blood sugar monitoring and insulin administra-
tion. Serum glucose levels should be monitored.
A. Chronic pancreatitis
B. Severe hemorrhagic pancreatitis
C. Pancreatic pseudocysts
D. Infectious pancreatitis with development of sepsis
(occurs in up to 5% of all patients with pancreatitis) E. Portal vein thrombosis
Hepatic encephalopathy develops when ammonia andtoxins, which are usually metabolized (detoxified) by theliver, enter into the systemic circulation. Hepaticencephalopathy can be diagnosed in 50-70% of patientswith chronic hepatic failure. I. Clinical manifestations
A. Hepatic encephalopathy manifests as mild changes
in personality to altered motor functions and/or levelof consciousness.
B. Most episodes are precipitated by identifiable factors,
including gastrointestinal bleeding, excessive proteinintake, constipation, excessive diuresis, hypokalemia,hyponatremia or hypernatremia, azotemia, infection,poor compliance with lactulose therapy, sedatives(benzodiazepines, barbiturates, antiemetics), hepaticinsult (alcohol, drugs, viral hepatitis), surgery, orhepatocellular carcinoma.
C. Hepatic encephalopathy is a diagnosis of exclusion.
Therefore, if a patient with acute or chronic liverfailure suddenly develops altered mental status,concomitant problems must be excluded, such asintracranial lesions (hemorrhage, infarct, tumor,abscess), infections (meningitis, encephalitis, sepsis),metabolic encephalopathies (hyperglycemia or hypo-glycemia, uremia, electrolyte imbalance), alcoholintoxication or withdrawal, W erni cke 'sencephalopathy, drug toxicity (sedatives, psychoac-tive medications), or postictal encephalopathy.
D. Physical exam may reveal hepatosplenomegaly,
ascites, jaundice, spider angiomas, gynecomastia,testicular atrophy, and asterixis.
E. Computed tomography may be useful to exclude
intracranial abscess or hemorrhage. Laboratoryevaluation may include serum ammonia, CBC,electrolyte panel, liver profile, INR/PTT, UA, andblood cultures.
II. Treatment of hepatic encephalopathy
A. Flumazenil (Romazicon) may transiently improve
the mental state in patients with hepaticencephalopathy. Dosage is 0.2 mg (2 mL) IV over 30seconds q1min until a total dose of 3 mg; if a partialresponse occurs, continue 0.5 mg doses until a totalof 5 mg. Excessive doses of flumazenil may precipi-tate seizures.
B. Lactulose is a non-absorbable disaccharide, which
decreases the absorption of ammonia into the bloodstream. Lactulose can be given orally, through anasogastric tube, or rectally (less effective). Thedosage is 30-45 mL PO q1h x 3 doses, then 15-45mL PO bid-qid titrate to produce 2-4 soft stools/d. Alaxative such as magnesium sulfate and an enemaare given before lactulose therapy is started.
Lactulose enema (300 mL of lactulose in 700 mL oftap water), 250 mL PR q6h.
C. Neomycin, a poorly absorbed antibiotic, alters
intestinal flora and reduces the release of ammoniainto the blood (initially 1-2 g orally four times a day).
Because chronic neomycin use can causenephrotoxicity and ototoxicity, neomycin should beused for short periods of time, and the dose shouldbe decreased to 1-2 g/day after achievement of thedesired clinical effect. Alternatively, metronidazolecan be given at 250 mg orally three times a day aloneor with neomycin.
D. Dietary protein is initially withheld, and intravenous
glucose is administered to prevent excessive endog-enous protein breakdown. As the patient improves,dietary protein can be reinstated at a level of 20 gmper day and then increased gradually to a minimumof 60 gm per day. If adequate oral intake of proteincannot be achieved, therapy with oral or enteralformulas of casein hydrolysates (Ensure) or aminoacids (FreAmine) is indicated.
References: See page 168.
Hans Poggemeyer, MD Poisoning and Drug Overdose
I. Management of poisoning and drug overdose
A. Stabilize vital signs; maintain airway, breathing and
B. Consider intubation if patient has depressed mental
status and is at risk for aspiration or respiratoryfailure.
C. Establish IV access and administer oxygen.
D. Draw blood for baseline labs (see below).
E. If altered mental status is present, administer D50W
50 mL IV push, followed by naloxone (Narcan) 2 mgIV, followed by thiamine 100 mg IV.
II. Gastrointestinal decontamination
A. Gastric lavage
1. Studies have challenged the safety and efficacy of
gastric lavage. Lavage retrieves less than 30% ofthe toxic agent when performed 1 hour afteringestion. Gastric lavage may propel toxins intothe duodenum, and accidental placement of thetube into the trachea or mainstem bronchus mayoccur.
2. Gastric lavage may be considered if the patient
has ingested a potentially life-threatening amountof poison and the procedure can be undertakenwithin 60 minutes of ingestion.
3. Contraindications: Acid, alkali, or hydrocarbons.
4. Place the patient in Trendelenburg's position and
left lateral decubitus. Insert a large bore (32-40)french Ewald orogastric tube. A smaller NG tubemay be used but may be less effective in retriev-ing large particles.
5. After tube placement has been confirmed by
auscultation, aspirate stomach contents andlavage with 200 cc aliquots of saline or water untilclear (up to 2 L). The first 100 cc of fluid should besent for toxicology analysis.
B. Activated charcoal
1. Activated charcoal is not effective for alcohols,
aliphatic hydrocarbons, caustics, cyanide, ele-mental metals (boric acid, iron, lithium, lead), orpesticides. 2. The oral or nasogastric dose is 50 gm mixed with
sorbitol. The dose should be repeated at 25-50gm q4-6h for 24-48 hours if massive ingestion,sustained release products, tricyclic antidepres-sants, phenothiazines, sertraline (Zoloft),paroxetine (Paxil), carbamazepine, digoxin,phenobarbital, phenytoin, valproate, salicylate,doxepin, or theophylline were ingested.
3. Give oral cathartic (70% sorbitol) with charcoal.
C. Whole bowel irrigation
1. Whole bowel irrigation can prevent further absorp-
tion in cases of massive ingestion, delayed pre-sentation, or in overdoses of enteric coated orsustained release pills. This treatment may beuseful in eliminating objects, such as batteries, oringested packets of drugs.
2. Administer GoLytely, or CoLyte orally at 1.6-2.0
liter per hour until fecal effluent is clear.
D. Hemodialysis: Indications include ingestion of
phenobarbital, theophylline, chloral hydrate,salicylate, ethanol, lithium, ethylene glycol, isopropylalcohol, procainamide, and methanol, or severemetabolic acidosis.
E. Hemoperfusion: May be more effective than
hemodialysis except for bromides, heavy metals,
lithium, and ethylene glycol. Hemoperfusion is
effective for disopyramide, phenytoin, barbiturates,
theophylline.
I. Characteristics of common toxicologic syndromes
A. Cholinergic poisoning: Salivation, bradycardia,
defecation, lacrimation, emesis, urination, miosis. B. Anticholinergic poisoning: Dry skin, flushing,
fever, urinary retention, mydriasis, thirst, delirium,conduction delays, tachycardia, ileus.
C. Sympathomimetic poisoning: Agitation, hyperten-
sion, seizure, tachycard i a , m yd r iasis,vasoconstriction.
D. Narcotic poisoning: Lethargy, hypotension, hypo-
ventilation, miosis, coma, ileus.
E. Withdrawal syndrome: Diarrhea, lacrimation,
mydriasis, cramps, tachycardia, hallucination.
F. Salicylate poisoning: Fever, respiratory alkalosis,
or mixed acid-base disturbance, hyperpnea,hypokalemia, tinnitus.
G. Causes of toxic seizures: Amoxapine,
anticholinergics, camphor, carbon monoxide, co-caine, ergotamine, isoniazid, lead, lindane, lithium,LSD, parathion, phencyclidine, phenothiazines,propoxyphene propranolol, strychnine, theophylline,tricyclic antidepressants, normeperidine (metaboliteof meperidine), thiocyanate.
H. Causes of toxic cardiac arrhythmias: Arsenic,
beta-blockers, chloral hydrate, chloroquine,clonidine, calcium channel blockers, cocaine, cya-nide, carbon monoxide, digitalis, ethanol, phenol,phenothiazine, tricyclics.
I. Extrapyramidal syndromes: Dysphagia,
dysphonia, trismus, rigidity, torticollis, laryngospasm.
I. Clinical features
A. Acute lethal dose = 13-25 g. Acetaminophen is partly
metabolized to N-acetyl-p-benzoquinonimine whichis conjugated by glutathione. Hepatic glutathionestores can be depleted in acetaminophen overdose,leading to centrilobular hepatic necrosis.
B. Liver failure occurs 3 days after ingestion if un-
treated. Liver failure presents with right upper quad-rant pain, elevated liver function tests, coagulopathy,hypoglycemia, renal failure and encephalopathy.
A. Gastrointestinal decontamination should consist of
gastric lavage followed by activated charcoal. Resid-ual charcoal should be removed with saline lavageprior to giving N-acetyl-cysteine (NAC). B. Check acetaminophen level 4 hours after ingestion.
A nomogram should be used to determine if treat-ment is necessary (see next page). Start treatment iflevel is above the nontoxic range or if the level ispotentially toxic but the time of ingestion is unknown.
C. Therapy must start no later than 8-12 hours after
ingestion. Treatment after 16-24 hours of non-sus-tained release formulation is significantly less effec-tive, but should still be accomplished.
D. Oral N-acetyl-cysteine (Mucomyst): 140 mg/kg PO
followed by 70 mg/kg PO q4h x 17 doses (total 1330mg/kg over 72 h). Repeat loading dose if emesisoccurs. Complete all doses even afteracetaminophen level falls below critical value.
E. Hemodialysis and hemoperfusion are somewhat
effective, but should not take the place of NACtreatment.
I. Clinical evaluation
A. Cocaine can be used intravenously, smoked, in-
gested, or inhaled nasally. Street cocaine often is cutwith other substances including amphetamines, LSD,PCP, heroin, strychnine, lidocaine, talc, and quinine.
B. One-third of fatalities occur within 1 hour, with an-
other third occurring 6-24 hours later.
C. Persons may transport cocaine by swallowing
wrapped packets, and some users may hastilyswallow packets of cocaine to avoid arrest.
II. Clinical features
A. CNS: Sympathetic stimulation, agitation, seizures,
tremor, headache, subarachnoid hemorrhage,ischemic cerebral stoke, psychosis, hallucinations,fever, mydriasis, formication (sensation of insectscrawling on skin).
B. Cardiovascular: Atrial and ventricular arrhythmias,
myocardial infarction, hypertension, hypotension,myocarditis, aortic rupture, cardiomyopathy.
C. Pulmonary: Noncardiogenic pulmonary edema,
pneumomediastinum, alveolar hemorrhage, hyper-sensitivity pneumonitis, bronchiolitis obliterans.
D. Other: Rhabdomyolysis, mesenteric ischemia,
A. Treatment consists of supportive care because no
antidote exists. GI decontamination, including re-peated activated charcoal, whole bowel irrigation andendoscopic evaluation is provided if oral ingestion issuspected.
B. Hyperadrenergic symptoms should be treated with
benzodiazepines, such as lorazepam.
C. Seizures: Treat with lorazepam, phenytoin, or
1. Treat hyperadrenergic state and supraventricular
tachycardia with lorazepam and propranolol.
2. Ventricular arrhythmias are treated with lidocaine
or propranolol.
1. Use lorazepam first for tachycardia and hyperten-
2. If no response, use labetalol because it has alpha
and beta blocking effects.
3. If hypertension remains severe, administer sodium
nitroprusside or esmolol drip.
F. Myocardial ischemia and infarction: Treat with
thrombolysis, heparin, aspirin, beta-blockers, nitro-glycerin. Control hypertension and exclude CNSbleeding before using thrombolytic therapy.
Cyclic Antidepressant Overdose
I. Clinical features
A. Antidepressants have prolonged body clearance
rates, and cannot be removal by forced diuresis,hemodialysis, and hemoperfusion. Delayed absorp-tion is common because of decreased GI motilityfrom anticholinergic effects. Cyclic antidepressantsundergo extensive enterohepatic recirculation.
B. CNS: Lethargy, coma, hallucinations, seizures,
myoclonic jerks. C. Anticholinergic crises: Blurred vision, dilated
pupils, urinary retention, dry mouth, ileus,hyperthermia. D. Cardiac: Hypotension, ventricular tachyarrhythmias,
sinus tachycardia. E. ECG: Sinus tachycardia, right bundle branch block,
right axis deviation, increased PR and QT interval,QRS >100 msec, or right axis deviation. Prolonga-tion of the QRS width is a more reliable predictor ofCNS and cardiac toxicity than the serum level.
A. Gastrointestinal decontamination and systemic
drug removal
1. Magnesium citrate 300 mL via nasogastric tube x
2. Activated charcoal premixed with sorbitol 50 gm
via nasogastric tube q4-6h around-the-clock untilthe serum level decreases to therapeutic range.
Maintain the head-of-bed at a 30-45 degree angleto prevent aspiration.
3. Cardiac toxicity
a. Alkalinization is a cardioprotective measure
and it has no influence on drug elimination. Thegoal of treatment is to achieve an arterial pH of7.50-7.55. If mechanical ventilation is neces-sary, hyperventilate to maintain desired pH.
b. Administer sodium bicarbonate 50-100 mEq (1-
2 amps or 1-2 mEq/kg) IV over 5-10 min.
Followed by infusion of sodium bicarbonate, 2amps in 1 liter of D5W at 100-150 cc/h. AdjustIV rate to maintain desired pH.
4. Seizures
a. Administer lorazepam or diazepam IV followed
by phenytoin.
b. Physostigmine, 1-2 mg slow IV over 3-4 min, is
necessary if seizures continue.
I. Clinical features
A. The therapeutic window of digoxin is 0.8-2.0 ng/mL.
Drugs that increase digoxin levels include verapamil,quinidine, amiodarone, flecainide, erythromycin, andtetracycline. Hypokalemia, hypomagnesemia andhypercalcemia enhance digoxin toxicity.
B. CNS: Confusion, lethargy; yellow-green visual halo.
C. Cardiac: Common dysrhythmias include ventricular
tachycardia or fibrillation; variable atrioventricularblock, atrioventricular dissociation; sinusbradycardia, junctional tachycardia, prematureventricular contractions. D. GI: Nausea, vomiting.
E. Metabolic: Hypokalemia enhances the toxic effects
of digoxin on the myocardial tissue and may bepresent in patients on diuretics. A. Gastrointestinal decontamination: Gastric lavage,
followed by repeated doses of activated charcoal, iseffective; hemodialysis is ineffective.
B. Treat bradycardia with atropine, isoproterenol, and
cardiac pacing.
C. Treat ventricular arrhythmias with lidocaine or
phenytoin. Avoid procainamide and quinidinebecause they are proarrhythmic and slow AV con-duction.
D. Electrical DC cardioversion may be dangerous in
severe toxicity. Hypomagnesemia and hypokalemiashould be corrected.
E. Digibind (Digoxin-specific Fab antibody frag-
ment)
1. Indication: Life-threatening arrhythmias refractory
to conventional therapy.
2. Dosage of Digoxin immune Fab:
(number of 40 mg vials)= Digoxin level (ng/mL) x 3. Dissolve the digoxin immune Fab in 100-150 mL
of NS and infuse IV over 15-30 minutes. A 0.22micron in-line filter should be used during infu-sion.
4. Hypokalemia, heart failure, and anaphylaxis may
occur. The complex is renally excreted; afteradministration, serum digoxin levels may beartificially high because both free and bounddigoxin is measured.
Ethylene Glycol Ingestion
I. Clinical features
A. Ethylene glycol is found in antifreeze, detergents,
and polishes.
B. Toxicity: Half-life 3-5 hours; the half-life increases to
17 hours if coingested with alcohol. The minimallethal dose is 1.0-1.5 cc/kg, and the lethal blood levelis 200 mg/dL.
C. Anion gap metabolic acidosis and severe osmolar
gap is often present. CNS depression and cranialnerve dysfunction (facial and vestibulocochlearpalsies) are common.
D. GI symptoms such as flank pain. Oxalate crystals
may be seen in the urine sediment. Other findingsmay include hypocalcemia (due to calcium oxalateformation); tetany, seizures, and prolonged QT.
A. Fomepizole (Antizol) loading dose 15 mg/kg IV; then
10 mg/kg IV q12h x 4, then 15 mg/kg IV q12h untilethylene glycol level is <20 mg/dL.
B. Pyridoxine 100 mg IV qid x 2 days and thiamine 100
mg IV qid x 2 days.
C. If definitive therapy is not immediately available, 3-4
ounces of whiskey (or equivalent) may be givenorally.
D. Hemodialysis indications: Severe refractory meta-
bolic acidosis, crystal uria, serum ethylene glycol level>50 mg/dL; keep glycol level <10 mg/dL.
I. Clinical features
A. Gamma-hydroxybutyrate (GHB) was used as an
anesthetic agent but was banned because of theoccurrence of seizures. Gamma-hydroxybutyrate isnow an abused substance at dance clubs because ofthe euphoric effects of the drug. It is also abused bybody builders because of a mistaken belief that it hasanabolic properties. Gamma-hydroxybutyrate is aclear, odorless, oily, salty liquid. It is rapidly absorbedwithin 20-40 minutes of ingestion and metabolized inthe liver. The half-life of GHB is 20-30 min.
B. Gamma-hydroxybutyrate is not routinely included on
toxicological screens, but it can be detected in theblood and urine by gas chromatography within 12hours of ingestion. Gamma hydroxybutyrate maycause respiratory depression, coma, seizures, andsevere agitation. Cardiac effects include hypotension,cardiac arrest, and severe vomiting.
A. Gastric lavage is not indicated due to rapid absorp-
tion of GHB.
B. Immediate care consists of support of ventilation and
circulation. Agitation should be treated withbenzodiazepines, haloperidol, or propofol. Seizuresshould be treated with lorazepam, phenytoin, orvalproic acid.
I. Clinical features
A. Toxicity is caused by free radical organ damage to
the GI mucosa, liver, kidney, heart, and lungs. Thecause of death is usually shock and liver failure.
Toxic dosages and serum levels
<10-20 mg/kg of elemental iron(0-100 mcg/dL) >20 mg/kg of elemental iron(350-1000 mcg/dL) >180-300 mg/kg of elemental iron(>1000 mcg/dL) B. Two hours after ingestion: Severe hemorrhagic
gastritis; vomiting, diarrhea, lethargy, tachycardia,and hypotension.
C. Twelve hours after ingestion: Improvement and
D. 12-48 hours after ingestion: GI bleeding, coma,
seizures, pulmonary edema, circulatory collapse,hepatic and renal failure, coagulopathy,hypoglycemia, and severe metabolic acidosis.
A. Administer deferoxamine if iron levels reach toxic
values. Deferoxamine 100 mg binds 9 mg of freeelemental iron. The deferoxamine dosage is 10-15mg/kg/hr IV infusion.
B. Treat until 24 hours after vin rose colored urine
clears. Serum iron levels during chelation are notaccurate. Deferoxamine can cause hypotension,allergic reactions such as pruritus, urticarial wheals,rash, anaphylaxis, tachycardia, fever, and legcramps.
C. Gastrointestinal decontamination
1. Charcoal is not effective in absorbing elemental
iron. Abdominal x-rays should be evaluated forremaining iron tablets. Consider whole bowellavage if iron pills are past the stomach andcannot be removed by gastric lavage (see page128).
2. Hemodialysis is indicated for severe toxicity.
Isopropyl Alcohol Ingestion
I. Clinical features
A. Isopropyl alcohol is found in rubbing alcohol,
solvents, and antifreeze.
B. Toxicity: Lethal dose: 3-4 g/kg
1. Lethal blood level: 400 mg/dL
2. Half-life = 3 hours
C. Metabolism: Isopropyl alcohol is metabolized to
acetone. Toxicity is characterized by an anion gapmetabolic acidosis with high serum ketone level; mildosmolar gap; mildly elevated glucose.
D. CNS depression, headache, nystagmus; cardiovas-
cular depression, abdominal pain and vomiting, andpulmonary edema may occur.
A. Treatment consists of supportive care. No antidote is
available; ethanol is not indicated.
B. Hemodialysis: Indications: refractory hypotension,
coma, potentially lethal blood levels.
I. Clinical features
A. Lithium has a narrow therapeutic window of 0.8-1.2
B. Drugs that will increase lithium level include NSAIDs,
phenothiazines, thiazide and loop diuretics (bycausing hyponatremia).
C. Toxicity
1.5-3.0 mEq/L = moderate toxicity3.0-4.0 mEq/L = severe toxicity D. Toxicity in chronic lithium users occurs at much
lower serum levels than with acute ingestions. E. Common manifestations include seizures,
encephalopathy, hyperreflexia, tremor, nausea,vomiting, diarrhea, hypotension. Nephrogenic diabe-tes insipidus and hypothyroidism may also occur.
Conduction block and dysrhythmias are rare, butreversible T-wave depression may occur.
A. Correct hyponatremia with aggressive normal saline
hydration. Follow lithium levels until <1.0 mEq/L.
B. Forced solute diuresis: Hydrate with normal saline
infusion to maintain urine output at 2-4 cc/kg/hr; usefurosemide (Lasix) 40-80 mg IV doses as needed.
C. Gastrointestinal decontamination
1. Administer gastric lavage. Activated charcoal is
ineffective. Whole bowel irrigation may be useful.
2. Indications for hemodialysis: Level >4 mEq/L;
CNS or cardiovascular impairment with level of2.5-4.0 mEq/L.
I. Clinical features
A. Methanol is found in antifreeze, Sterno, cleaners,
B. Toxicity
1. 10 cc causes blindness
2. Minimal lethal dose = 1-5 g/kg
3. Lethal blood level = 80 mg/dL
4. Symptomatic in 40 minutes to 72 hours.
C. Signs and Symptoms
1. Severe osmolar and anion gap metabolic acidosis.
2. Visual changes occur because of optic nerve
toxicity, leading to blindness.
3. Nausea, vomiting, abdominal pain, pancreatitis,
and altered mental status.
A. Ethanol 10% is infuse in D5W as 7.5 cc/kg load then
1.4 cc/kg/h drip to keep blood alcohol level between100-150 mg/dL. Continue therapy until the methanollevel is below 20-25 mg/dL.
B. Give folate 50 mg IV q4h to enhance formic acid
C. Correct acidosis and electrolyte imbalances.
D. Hemodialysis: Indications: peak methanol level >50
mg/dL; formic acid level >20 mg/dL; severe metabolicacidosis; acute renal failure; any visual compromise.
I. Clinical features
A. Toxicity
150-300 mg/kg - mild toxicity300-500 mg/kg - moderate toxicity>500 mg/kg - severe toxicity B. Chronic use can cause toxicity at much lower levels
(ie, 25 mg/dL) than occurs with acute use.
C. Acid/Base Abnormalities: Patients present initially
with a respiratory alkalosis because of central hyper-ventilation. Later an anion gap metabolic acidosisoccurs.
D. CNS: Tinnitus, lethargy, irritability, seizures, coma,
cerebral edema.
E. GI: Nausea, vomiting, liver failure, GI bleeding.
F. Cardiac: Hypotension, sinus tachycardia, AV block,
wide complex tachycardia.
G. Pulmonary: Non-cardiogenic pulmonary edema,
adult respiratory distress syndrome.
H. Metabolic: Renal failure; coagulopathy because of
decreased factor VII; hyperthermia because ofuncoupled oxidative phosphorylation. Hypoglycemiamay occur in children, but it is rare in adults.
A. Provide supportive care and GI decontamination.
Aspirin may form concretions or drug bezoars, andingestion of enteric coated preparations may lead todelayed toxicity.
B. Multiple dose activated charcoal, whole bowel irriga-
tion, and serial salicylate levels are indicated.
Hypotension should be treated vigorously with fluids.
Abnormalities should be corrected, especiallyhypokalemia. Urine output should be maintained at200 cc/h or more. Metabolic acidosis should betreated with bicarbonate 50-100 mEq (1-2 amps) IVP.
C. Renal clearance is increased by alkalinization of urine
with a bicarbonate infusion (2-3 amps in 1 liter ofD5W IV at 150-200 mL/h), keeping the urine pH at7.5-8.5.
D. Hemodialysis is indicated for seizures, cardiac or
renal failure, intractable acidosis, acute salicylatelevel >120 mg/dL or chronic level >50 mg/dL (thera-peutic level 15-25 mg/dL).
I. Clinical features
A. Drug interactions can increase serum theophylline
level, including quinolone and macrolide antibiotics,propranolol, cimetidine, and oral contraceptives. Liverdisease or heart failure will decrease clearance.
B. Serum toxicity levels
20-40 mg/dL - mild40-70 mg/dL - moderate>70 mg/dL - life threatening C. Toxicity in chronic users occurs at lower serum levels
than with short-term users. Seizures and arrhythmiascan occur at therapeutic or minimally supra-therapeu-tic levels.
D. CNS: Hyperventilation, agitation, and tonic-clonic
E. Cardiac: Sinus tachycardia, multi-focal atrial tachy-
cardia, supraventricular tachycardia, ventriculartachycardia and fibrillation, premature ventricularcontractions, hypotension or hypertension.
F. Gastrointestinal: Vomiting, diarrhea, hematemesis.
G. Musculoskeletal: Tremor, myoclonic jerks
H. Metabolic: Hypokalemia, hypomagnesemia,
A. Gastrointestinal decontamination and systemic
drug removal
1. Activated charcoal premixed with sorbitol, 50 gm
PO or via nasogastric tube q4h around-the-clockuntil theophylline level is less than 20 mcg/mL.
Maintain head-of-bed at 30 degrees to preventcharcoal aspiration.
2. Hemodialysis is as effective as repeated oral
doses of activated charcoal and should be usedwhen charcoal hemoperfusion is not feasible.
3. Indications for charcoal hemoperfusion: Coma,
seizures, hemodynamic instability, theophyllinelevel >60 mcg/mL; rebound in serum levels mayoccur after discontinuation of hemoperfusion.
4. Seizures are generally refractory to
anticonvulsants. High doses of lorazepam, diaze-pam or phenobarbital should be used; phenytoinis less effective.
5. Treatment of hypotension
a. Normal saline fluid bolus.
b.Norepinephrine 8-12 mcg/min IV infusion or
c. Phenylephrine 20-200 mcg/min IV infusion.
6. Treatment of ventricular arrhythmias
a. Amiodarone 150-300 mg IV over 10 min, then 1
mg/min x 6 hours, followed by 0.5 mg/min IVinfusion. Lidocaine should be avoided becauseit has epileptogenic properties.
b.Esmolol (Brevibloc) 500 mcg/kg/min loading
dose, then 50-300 mcg/kg/min continuous IVdrip.
Warfarin (Coumadin) Overdose
I. Clinical management
A. Elimination measures: Gastric lavage and activated
charcoal if recent oral ingestion of warfarin(Coumadin).
B. Reversal of coumadin anticoagulation:
Coagulopathy should be corrected rapidly or slowlydepending on the following factors: 1) Intensity ofhypocoagulability, 2) severity or risk of bleeding, 3)need for reinstitution of anticoagulation.
C. Emergent reversal
1. Fresh frozen plasma: Replace vitamin K depend-
ent factors with FFP 2-4 units; repeat in 4 hours ifprothrombin time remains prolonged.
2. Vitamin K, 25 mg in 50 cc NS, to infuse no faster
than 1 mg/min; risk of anaphylactoid reactions andshock; slow infusion minimizes risk.
D. Reversal over 24-48 Hours: Vitamin K 10-25 mg
subcutaneously. Full reversal of anticoagulation willresult in resistance to further Coumadin therapy forseveral days.
E. Partial correction: Lower dose vitamin K (0.5-1.0
mg) will lower prothrombin time without interferingwith reinitiation of Coumadin.
References: See page 168.
Hans Poggemeyer, MD Acute Ischemic Stroke
I. Initial general assessment. Sudden loss of focal brain
function is the core feature of the onset of ischemic
stroke. The goals in this initial phase include:
A. Medically stabilize the patient.
B. Reverse any conditions that are contributing to the
patient's problem.
C. Assess the pathophysiologic basis of the neurologic
D. Screen for potential contraindications to thrombolysis
in acute ischemic stroke patients.
E. Diagnosing an intracerebral hemorrhage (ICH) or
subarachnoid hemorrhage (SAH) as soon as possiblecan be lifesaving. The presence of onset headacheand vomiting favor the diagnosis of ICH or SAHcompared with a thromboembolic stroke, while theabrupt onset of impaired cerebral function withoutfocal symptoms favors the diagnosis of SAH.
F. History and physical examination should distinguish
between seizures, syncope, migraine, andhypoglycemia, which can mimic acute ischemia. Inpatients with focal signs and altered level of con-sciousness, it is important to determine whether thepatient takes insulin or oral hypoglycemic agents, hasa history of a seizure disorder or drug overdose orabuse, medications on admission, or recent trauma.
Acute stroke differential diagnosis
MigraineIntracerebral hemorrhageHead traumaBrain tumorTodd's palsy (paresis, aphasia, neglect, etc., after aseizure episode)Functional deficit (conversion reaction)Systemic infectionToxic-metabolic disturbances (hypoglycemia, acuterenal failure, hepatic insufficiency, exogenous drug G. Physical examination should evaluate the neck and
retroorbital regions for vascular bruits, and palpate of
pulses in the neck, arms, and legs to assess for their
absence, asymmetry, or irregular rate.
1. The heart should be auscultated for murmurs.
Fluctuations in blood pressure occasionally pre-cede fluctuations in clinical signs.
2. The skin should be examined for signs of
endocarditis, cholesterol emboli, purpura, orecchymoses. The funduscopic examination mayreveal cholesterol emboli or papilledema. The headshould be examined for signs of trauma. A tonguelaceration may occur during a seizure.
3. The neck should be immobilized until evaluated
radiographically for evidence of serious trauma ifthere is a suspicion of a fall. The chest x-ray ishelpful if it shows cardiomegaly, metastases, or awidened mediastinum suggesting aortic dissection.
Examination of the extremities is important todetect deep vein thrombosis.
4. Breathing. Patients with increased ICP due to
hemorrhage, vertebrobasilar ischemia, orbihemispheric ischemia can present with a de-creased respiratory drive or muscular airwayobstruction. Intubation may be necessary to restoreadequate ventilation. Patients with adequateventilation should have the oxygen saturationmonitored. Patients who are hypoxic should receivesupplemental oxygen.
H. Immediate laboratory studies
1. All patients with acute neurologic deterioration or
acute stroke should have an electrocardiogram.
Chest radiography is indicated if lung or heartdisease is suspected. Oxygen saturation or arterialblood gas tests are indicated if hypoxia is sus-pected.
2. Blood studies include:
a. Complete blood count including platelets, and
erythrocyte sedimentation rate.
b. Electrolytes, urea nitrogen, creatinine.
c. Serum glucose. Finger stick for faster glucose
measurement if diabetic, taking insulin or oralhypoglycemic agents, or if there is clinical suspi-cion for hypoglycemia.
d. Liver function tests.
e. Prothrombin time and partial thromboplastin
f. Toxicology screen and blood alcohol level in
selected patients.
g. Blood for type and cross match in case fresh
frozen is needed to reverse a coagulopathy ifICH is present.
h. Urine human chorionic gonadotropin in women
of child-bearing potential.
i. Consider evaluation for hypercoagulable state in
young patients without apparent stroke riskfactors.
Complete blood count and erythrocyte sedimentation rateElectrolytes, urea nitrogen, creatinine, glucoseLiver function testsProthrombin time and partial thromboplastin timeToxicology screenBlood for type and cross matchUrine human chorionic gonadotropin in women ofchild-bearing potentialConsider evaluation for hypercoagulable state in young pa-tients without apparent stroke risk factors 3. Anticoagulant use is a common cause of
intracerebral hemorrhage. Thus, the prothrombinand partial thromboplastin time and the plateletcount should be checked. The effects of warfarinare corrected with intravenous vitamin K and fresh-frozen plasma (typically 4 units) in patients withintracerebral hemorrhage.
4. A drug overdose can mimic an acute stroke. In
addition, cocaine, intravenous drug abuse, andamphetamines can cause an ischemic stroke orintracranial hemorrhage. Hyponatremia and throm-botic thrombocytopenic purpura (TTP) can presentwith focal neurologic deficits, suggesting the needfor measurement of serum electrolytes and acomplete blood count with platelet count.
5. Hyperglycemia, defined as a blood glucose level
>108 mg/dL, is associated with poor functionaloutcome from acute stroke at presentation. Stresshyperglycemia is common in stroke patients,although newly diagnosed diabetes may be de-tected. Treatment with fluids and insulin to reduceserum glucose to less than 300 mg/dL is recom-mended.
6. Hypoglycemia can cause focal neurologic deficits
mimicking stroke. The blood sugar should bechecked and rapidly corrected if low. Glucoseshould be administered immediately after drawinga blood sample in "stroke" patients known to takeinsulin or oral hypoglycemic agents.
7. Fever. Primary central nervous system infection,
such as meningitis, subdural empyema, brainabscess, and infective endocarditis, need to beexcluded as the etiology of fever. Common etiolo-gies of fever include aspiration pneumonia andurinary tract infection. Fever may contribute to braininjury in patients with an acute stroke. Maintainingnormothermia is recommended after an acutestroke. Prophylactic administration ofacetaminophen (1 g four times daily) is moreeffective in preventing fever than placebo (5 versus36 percent).
8. Blood pressure management. Acute manage-
ment of blood pressure (BP) may vary according to
the type of stroke.
a. Ischemic stroke. Blood pressure should not be
treated acutely in the patient with ischemicstroke unless the hypertension is extreme (dia-stolic BP above 120 mm Hg and/or systolic BPabove 220 mm Hg), or the patient has activeischemic coronary disease, heart failure, oraortic dissection. If pharmacologic therapy isgiven, intravenous labetalol is the drug ofchoice.
b. Intracranial hemorrhage. With ICH, intrave-
nous labetalol, nitroprusside, or nicardipine,should be given if the systolic pressure is above170 mm Hg. The goal is to maintain the systolicpressure between 140 and 160 mm Hg. Intrave-nous labetalol is the first drug of choice in theacute phase since it allows rapid titration.
I. Neurologic evaluation. The history should focus
upon the time of symptom onset, the course of symp-toms over time, possible embolic sources, items in thedifferential diagnosis, and concomitant diseases. Theneurologic examination should attempt to confirm thefindings from the history and provide a quantifiableexamination for further assessment over time.
J. Neuroimaging studies are used to exclude hemor-
rhage as a cause of the deficit, to assess the degreeof brain injury, and to identify the vascular lesionresponsible for the ischemic deficit.
1. Computed tomography. In the hyperacute phase,
a non-contrast CT (NCCT) scan is usually ordered
to exclude or confirm hemorrhage. A NCCT scan
should be obtained as soon as the patient is medi-
cally stable.
a. Noncontrast CT. Early signs of infarction in-
clude: Subtle parenchymal hypodensity, whichcan be detected in 45 to 85 percent of cases.
Early focal brain swelling is present in up to 40percent of patients with early infarction and alsohas been adversely related to outcome. Ahyperdense middle cerebral artery (MCA) canbe visualized in 30 to 40 percent of patients withan MCA distribution stroke, indicating the pres-ence of thrombus inside the artery lumen (brightartery sign).
2. Transcranial Doppler ultrasound (TCD) visual-
izes intracranial vessels of the circle of Willis. It isa noninvasive means of assessing the patency ofintracranial vessels.
3. Carotid duplex ultrasound is as a noninvasive
examination to evaluate extracranial atheroscleroticdisease. It may help to establish the source of anembolic stroke, but is not used acutely.
Initial management of acute stroke
Determine whether stroke is ischemic or hemorrhagic by computed tomography Consider administration of t-PA if less than three hours from General management:
• Blood pressure (avoid hypotension)
• Assure adequate oxygenation
• Administer intravenous glucose
• Take dysphagia/aspiration precautions
• Consider prophylaxis for venous thrombosis if the patient
is unable to walk • Suppress fever, if present • Assess stroke mechanism (eg, atrial fibrillation, hyperten- • Consider aspirin or clopidogrel (Plavix) therapy if ischemic stroke and no contraindications (begin 24 hours after t-PA).
Antiplatelet Agents for Prevention of Ischemic
Stoke
• Enteric-coated aspirin (Ecotrin) 325 mg PO qd• Clopidogrel (Plavix) 75 mg PO qd• Extended-release aspirin 25 mg with dipyridamole 200 mg (Aggrenox) one tab PO qd Eligibility criteria for the treatment of acute
ischemic stroke with recombinant tissue
plasminogen activator (rt-PA)
Clinical diagnosis of ischemic stroke, with the on-set of symptoms within three hours of the initiationof treatment (if the exact time of stroke onset is notknow, it is defined as the last time the patient wasknown to be normal), and with a measurable neu-rologic deficit.
Stroke or head trauma within the prior 3monthsAny prior history of intracranial hemorrhageMajor surgery within 14 daysGastrointestinal or genitourinary bleeding withinthe previous 21 days Rapid improving stroke symptomsOnly minor and isolated neurologic signsSeizure at the onset of stroke with postictal resid-ual neurologic impairmentsSymptoms suggestive of subarachnoid hemor-rhage, even if the CT is normalClinical presentation consistent with acute MI orpost-MI pericarditisPersistent systolic BP >185 diastolic >110 mm Hg,or requiring aggressive therapy to control BPPregnancy or lactationActive bleeding or acute trauma (fracture) Platelets <100,000/mm3Serum glucose <50 mg/dL or >400 mg/dLINR >1.5 if on warfarinElevated partial thromboplastin time if on heparin Head CT scan
Evidence of hemorrhageEvidence major early infarct signs, such as diffuseswelling of the affected hemisphere, parenchymalhypodensity, and /or effacement of >35 percent ofthe middle cerebral artery territory K. Thrombolytic therapy. Patients presenting within
three hours of symptom onset may be given IValteplase (Activase) (0.9 mg/kg up to 90 mg; 10percent as a bolus, then a 60 minute infusion).
Elevated Intracranial Pressure
Cerebrospinal fluid (CSF) pressure in excess of 250 mmCSF is usually a manifestation of serious neurologicdisease. Intracranial hypertension is most often associatedwith rapidly expanding mass lesions, CSF outflow obstruc-tion, or cerebral venous congestion.
I. Clinical evaluation
A. Increased intracranial pressure may manifest as
headache caused by traction on pain-sensitivecerebral blood vessels or dura mater. B. Papilledema is the most reliable sign of ICP, al-
though it fails to develop in many patients withincreased ICP. Retinal venous pulsations, whenpresent, imply that CSF pressure is normal or notsignificantly elevated. Patients with increased ICPoften complain of worsening headache, in the morn-ing.
Causes of Increased Intracranial Pressure
Diffuse cerebral edema
Intracerebral hemor- Epidural hemorrhage Subdural hemorrhage Acute liver failure Electrolyte shifts Subarachnoid hemor- Posthypoxic brain in- Aqueductal stenosis Lead encephalopathy Pseudotumor cerebri Diffuse axonal injury Venous sinus throm-bosis II. Intracranial pressure monitoring
A. Clinical signs of elevated ICP, such as the Cushing
response (systemic hypertension, bradycardia, andirregular respirations), are usually a late findings andmay never even occur; therefore, ICP should bedirectly measured with an invasive device. B. Normal intracranial pressures range from approxi-
mately 10-20 cm H O (or about 5 to 15 mm Hg).
Ventricular catheterization involves insertion of asterile catheter into the lateral ventricle.
Treatment of Elevated Intracranial Pressure
Hypocarbia pCO 25 to Immediate on- H y p o t e n s i o n , y 33 mm Hg set, well toler- barotrauma, dura- hypervent- respiratory ated tion usually hours Mannitol 0.5 Rapid onset, H y p o t e n s i o n ,to 1 g/kg IV titratable, pre- hypokalemia, du-push ration hours ordays Barbiturates Pentobarbit Mutes BP and Hypotension, fixed al 25 mg/kg respiratory fluc- pupils (small), du-slow IV infu- tuations sion over 3-4 hours Hemicran- Timing criti- L a r g e s u s - Surgical risk, tis-iectomy tained ICP re- sue herniationduction III. Treatment of increased intracranial pressure
A. Positioning the patient in an upright position with
the head of the bed at 30 degrees will lower ICP.
B. Hyperventilation is the most rapid and effective
means of lowering ICP, but the effects are shortlived because the body quickly compensates. ThepCO should be maintained between 25-33 mm Hg C. Mannitol can quickly lower ICP, although the effect
is not long lasting and may lead to dehydration orelectrolyte imbalance. Dosage is 0.5-1 gm/kg (37.5-50 gm) IV q6h; keep osmolarity <315; do not givefor more than 48h.
D. Corticosteroids are best used to treat increased
ICP in the setting of vasogenic edema caused bybrain tumors or abscesses; however, these agentshave little value in the setting of stroke or headtrauma. Dosage is dexamethasone (Decadron) 10mg IV or IM, followed by 4-6 mg IV, IM or PO q6h.
E. Barbiturate coma is used for medically intractable
ICP elevation when other medical therapies havefailed. There is a reduction in ICP by decreasingcerebral metabolism. The pentobarbital loadingdose is 25 mg/kg body weight over 3-4 hours,followed by 2-3 mg/kg/hr IV infusion. Blood levelsare periodically checked and adjusted to 30-40mg/dL. Patients require mechanical ventilation,intracranial pressure monitoring, and continuouselectroencephalographic monitoring.
F. Management of blood pressure. Beta-blockers or
mixed beta and alpha blockers provide the bestantihypertensive effects without causing significantcerebral vasodilatation that can lead to elevatedICP.
Management of Status Epilepticus
An estimated 152,000 cases of status epilepticus occur peryear in the United States, resulting in 42,000 deaths peryear. Status epilepticus is defined as two or more sequen-tial seizures without full recovery of consciousness be-tween seizures, or more than 30 minutes of continuousseizure activity. Practically speaking, any person whoexhibits persistent seizure activity or who does not regainconsciousness for five minutes or more after a witnessedseizure should be considered to have status epilepticus.
Status epilepticus is classified into generalized (tonic-clonic, myoclonic, absence, atonic, akinetic) and partial(simple or complex) status epilepticus. A. Status epilepticus of partial onset accounts for the
majority of episodes. 69 percent of episodes in adultsand 64 percent of episodes in children are partialonset, followed by secondarily generalized statusepilepticus in 43 percent of adults and 36 percent ofchildren. The incidence of status epilepticus isbimodally distributed, occurring most frequentlyduring the first year of life and after the age of 60years. A variety in adults, the major causes were lowlevels of antiepileptic drugs (34 percent) andcerebrovascular disease (22 percent), includingacute or remote stroke and hemorrhage.
Systemic Complications of Generalized Convul-
sive Status Epilepticus
Metabolic Lactic acidosis
Acute renal failure from Autonomic
High output failure Failure of cerebral autoregulation Vomiting Incontinence
II. Management of Status Epilepticus
A. A single generalized seizure with complete recovery
does not require treatment. Once the diagnosis ofstatus epilepticus is made, however, treatmentshould be initiated immediately. B. Physicians first should assess the patient's airway
and oxygenation. If the airway is clear andintubation is not immediately required, blood pres-sure and pulse should be checked and oxygenadministered. In patients with a history of seizures,an attempt should be made to determine whethermedications have been taken recently. A screeningneurologic examination should be performed tocheck for signs of a focal intracranial lesion.
C. Intravenous access should be obtained, and blood
should be sent to the laboratory for measurement ofserum electrolyte, blood urea nitrogen, glucose, andantiepileptic drug levels, as well as a toxic drugscreen and complete blood cell count. An isotonicsaline infusion should be initiated. D. Glucose, 50 mL of 50 percent, should be given
immediately if hypoglycemia is suspected becausehypoglycemia may precipitate status epilepticus andis quickly reversible. If the physician cannot checkfor hypoglycemia or there is any doubt, glucoseshould be administered empirically. Thiamine (100mg) should be given along with the glucose, be-cause glucose infusion increases the risk ofWernicke's encephalopathy in susceptible patients.
E. Blood gas levels should be determined to ensure
adequate oxygenation. Initially, acidosis,hyperpyrexia, and hypertension need not betreated, because these are common findings inearly status epilepticus and should resolve on theirown with general treatment. If seizures persist afterinitial measures, medication should be adminis-tered. Imaging with computed tomography is recom-mended after stabilization of the airway and circula-tion. If imaging is negative, lumbar puncture isrequired to rule out infectious etiologies.
III. Electroencephalography
A. Electroencephalography (EEG) is extremely useful
in the diagnosis and management of statusepilepticus. EEG can establish the diagnosis in lessobvious circumstances. B. EEG also can help to confirm that an episode of
status epilepticus has ended. Patients with statusepilepticus who fail to recover rapidly and com-pletely should be monitored with EEG for at least 24hours after an episode. IV. Pharmacologic management
1. The benzodiazepines are some of the most
effective drugs in the treatment of acute seizuresand status epilepticus. The benzodiazepinesmost commonly used to treat status epilepticusare diazepam (Valium), lorazepam (Ativan), andmidazolam (Versed). 2. Lorazepam (Ativan)
a. Lorazepam has emerged as the preferred
benzodiazepine for acute management ofstatus epilepticus. Lorazepam is less lipid-soluble than diazepam, with a distributionhalf-life of two to three hours versus 15 min-utes for diazepam. Therefore, it has a longerduration of clinical effect. Lorazepam alsobinds the GABAergic receptor more tightlythan diazepam, resulting in a longer durationof action.
b. Anticonvulsant effects of lorazepam last six to
12 hours, and the typical dose ranges from 4to 8 mg (0.1 mg/kg). Lorazepam has a broadspectrum of efficacy, terminating seizures in75 to 80 percent of cases. Adverse effectsinclude respiratory suppression, hypotension,sedation, and local tissue irritation. 3. Phenytoin
a. Phenytoin (Dilantin) is one of the most effec-
tive drugs for treating acute seizures andstatus epilepticus. In addition, it is effective inthe management of chronic epilepsy.
b. The main advantage of phenytoin is the lack
of a significant sedating effect. Arrhythmiasand hypotension have been reported with theIV formulation. These effects are associatedwith a more rapid rate of administration andthe propylene glycol vehicle used as its dilu-ent. In addition, local irritation, phlebitis, anddizziness may accompany intravenous ad-ministration.
Antiepileptic Drugs Used in Status Epilepticus
hypotension,sialorrhea equivalentsat 150 mg a. Fosphenytoin (Cerebyx) is a water-soluble pro-
drug of phenytoin that completely converts tophenytoin. Thus, the adverse events that arerelated to propylene glycol are avoided. Likephenytoin, fosphenytoin is useful in treatingacute partial and generalized tonic-clonic sei-zures. Fosphenytoin is converted to phenytoinwithin eight to 15 minutes. Because 1.5 mg offosphenytoin is equivalent to 1 mg of phenytoin,the dosage, concentration, and infusion rate ofintravenous fosphenytoin are expressed asphenytoin equivalents (PE).
Protocol for Management of Status Epilepticus
At: zero minutes
Initiate general systemic support of the airway (insert
nasal airway or intubate if needed)
I. Check blood pressure.
II. Begin nasal oxygen. III. Monitor ECG and respiration. IV. Check temperature frequently. V. Obtain history. VI. Perform neurologic examination. Send sample serum for evaluation of electrolytes,
blood urea nitrogen, glucose level, complete blood
cell count, toxic drug screen, and anticonvulsant
levels; check arterial blood gas values.
Start IV line containing isotonic saline at a low infu-
sion rate.
Inject 50 mL of 50 percent glucose IV and 100 mg of
thiamine IV.
Call EEG laboratory to start recording as soon as
feasible.
Administer lorazepam (Ativan) at 0.1 to 0.15 mg per
kg IV (2 mg per minute); if seizures persist, adminis-
ter fosphenytoin (Cerebyx) at 18 mg per kg IV (150
mg per minute, with an additional 7 mg per kg if sei-
zures continue).
At: 20 to 30 minutes, if seizures persist
Intubate, insert bladder catheter, start EEG record-
ing, check temperature.
Administer phenobarbital in a loading dose of 20 mg
per kg IV (100 mg per minute).
At: 40 to 60 minutes, if seizures persist
Begin pentobarbital infusion at 5 mg per kg IV initial
dose, then IV push until seizures have stopped, us-
ing EEG monitoring; continue pentobarbital infusion
at 1 mg per kg per hour; slow infusion rate every four
to six hours to determine if seizures have stopped,
with EEG guidance; monitor blood pressure and
respiration carefully. Support blood pressure with
pressors if needed.
or
Begin midazolam (Versed) at 0.2 mg per kg, then at
a dosage of 0.05-0.6 mg/kg/min, titrated to EEG
monitoring.
or
Begin propofol (Diprivan) at 1 to 2 mg per kg loading
dose, followed by 2 to 10 mg per kg per hour. Adjust
maintenance dosage on the basis of EEG monitor-
ing.
b. The initial dose of fosphenytoin is 15 to 20 mg
PE per kg, given at 150 mg PE per minute.
Fosphenytoin may be administered IV or IM,although IM administration has a 3-hour delayedpeak effect.
c. Adverse effects that are unique to fosphenytoin
include perineal paresthesias and pruritus.
Unlike phenytoin, fosphenytoin does not causelocal irritation. Intravenous therapy has beenassociated with hypotension, so continuouscardiac and blood pressure monitoring arerecommended. a. Phenobarbital is used after lorazepam or
phenytoin has failed to control statusepilepticus. The normal loading dose is 15 to 20mg per kg. Because high-dose phenobarbital issedating, airway protection is important, andaspiration is a major concern. Intravenousphenobarbital also is associated withhypotension. It is diluted in 60 to 80 percentpropylene glycol, which is associated with renalfailure, myocardial depression, and seizures. Michael Krutzik, MDGuy Foster, MD Diabetic ketoacidosis is defined by hyperglycemia, meta-bolic acidosis, andketosis.
I. Clinical presentation
A. Diabetes is newly diagnosed in 20% of cases of
diabetic ketoacidosis. In patients with known diabe-tes, precipitating factors include infection, noncompli-ance with insulin, myocardial infarction, and gastroin-testinal bleeding.
B. Symptoms of DKA include polyuria, polydipsia,
fatigue, nausea, and vomiting, developing over 1 to 2days. Abdominal pain is prominent in 25%.
C. Physical examination
1. Patients are typically flushed, tachycardic,
tachypneic, and volume depleted with dry mucousmembranes. Kussmaul's respiration (rapid, deepbreathing and air hunger) occurs when the serumpH is between 7.0 and 7.24.
2. A fruity odor on the breath indicates the presence
of acetone, a byproduct of diabetic ketoacidosis.
3. Fever, although seldom present, indicates infec-
tion. Eighty percent of patients with diabeticketoacidosis have altered mental status. Most areawake but confused; 10% are comatose.
D. Laboratory findings
1. Serum glucose level >300 mg/dL
2. pH <7.35, pCO2 <40 mm Hg
3. Bicarbonate level below normal with an elevated
4. Presence of ketones in the serum
II. Differential diagnosis
A. Differential diagnosis of ketosis-causing condi-
tions
1. Alcoholic ketoacidosis occurs with heavy drink-
ing and vomiting. It does not cause an elevatedglucose.
2. Starvation ketosis occurs after 24 hours without
food and is not usually confused with DKA becauseglucose and serum pH are normal.
B. Differential diagnosis of acidosis-causing condi-
tions
1. Metabolic acidoses are divided into increased
anion gap (>14 mEq/L) and normal anion gap;anion gap = sodium - (CI- + HCO3-).
2. Anion gap acidoses can be caused by
ketoacidoses, lactic acidosis, uremia, salicylate,methanol, ethanol, or ethylene glycol poisoning.
3. Non-anion gap acidoses are associated with a
normal glucose level and absent serum ketones.
Causes of non-anion gap acidoses include renal orgastrointestinal bicarbonate loss.
C. Hyperglycemia caused by hyperosmolar
nonketotic coma occurs in patients with type 2
diabetes with severe hyperglycemia. Patients are
usually elderly and have a precipitating illness.
Glucose level is markedly elevated (>600 mg/dL),
osmolarity is increased, and ketosis is minimal.
Treatment of diabetic ketoacidosis
A. Fluid resuscitation
1. Fluid deficits average 5 liters or 50 mL/kg. Resusci-
tation consists of 1 liter of normal saline over thefirst hour and a second liter over the second andthird hours. Thereafter, 1/2 normal saline should beinfused at 100-120 mL/hr.
2. When the glucose level decreases to 250 mg/dL,
5% dextrose should be added to the replacementfluids to prevent hypoglycemia. If the glucose leveldeclines rapidly, 10% dextrose should be infusedalong with regular insulin until the anion gapnormalizes.
B. Insulin
1. An initial loading dose consists of 0.1 U/kg IV
bolus. Insulin is then infused at 0.1 U/kg per hour.
The biologic half-life of IV insulin is less than 20minutes. The insulin infusion should be adjustedeach hour so that the glucose decline does notexceed 100 mg/dL per hour.
2. The insulin infusion rate may be decreased when
the bicarbonate level is greater than 20 mEq/L, theanion gap is less than 16 mEq/L, or the glucose is<250 mg/dL.
C. Potassium
1. The most common preventable cause of death in
patients with DKA is hypokalemia. The typicaldeficit is between 300 and 500 mEq.
2. Potassium chloride should be started when fluid
therapy is started. In most patients, the initial rateof potassium replacement is 20 mEq/h, buthypokalemia requires more aggressive replace-ment (40 mEq/h).
3. All patients should receive potassium replacement,
except for those with renal failure, no urine output,or an initial serum potassium level greater than 6.0mEq/L.
D. Sodium. For every 100 mg/dL that glucose is ele-
vated, the sodium level should be assumed to behigher than the measured value by 1.6 mEq/L.
E. Phosphate. Diabetic ketoacidosis depletes phos-
phate stores. Serum phosphate level should bechecked after 4 hours of treatment. If it is below 1.5mg/dL, potassium phosphate should be added to theIV solution in place of KCl.
F. Bicarbonate therapy is not required unless the
arterial pH value is <7.0. For a pH of <7.0, add 50mEq of sodium bicarbonate to the first liter of IV fluid.
G. Magnesium. The usual magnesium deficit is 2-3 gm.
If the patient's magnesium level is less than 1.8mEq/L or if tetany is present, magnesium sulfate isgiven as 5g in 500 mL of 0.45% normal saline over 5hours.
H. Additional therapies
1. A nasogastric tube should be inserted in semi-
conscious patients to protect against aspiration. 2. Deep vein thrombosis prophylaxis with subcuta-
neous heparin should be provided for patients whoare elderly, unconscious, or severely hyperosmolar(5,000 U every 12 hours).
Monitoring of therapy
A. Serum bicarbonate level and anion gap should be
monitored to determine the effectiveness of insulintherapy.
B. Glucose levels should be checked at 1-2 hour
intervals during IV insulin administration.
C. Electrolyte levels should be assessed every 2 hours
for the first 6-8 hours, and then q8h. Phosphorus andmagnesium levels should be checked after 4 hours oftreatment.
D. Plasma and urine ketones are helpful in diagnosing
diabetic ketoacidosis, but are not necessary duringtherapy.
V. Determining the underlying cause
A. Infection is the underlying cause of diabetic
ketoacidosis in 50% of cases. Infection of the urinarytract, respiratory tract, skin, sinuses, ears, or teethshould be sought. Fever is unusual in diabeticketoacidosis and indicates infection when present. Ifinfection is suspected, antibiotics should be promptlyinitiated.
B. Omission of insulin doses is often a precipitating
factor. Myocardial infarction, ischemic stroke, and ab-dominal catastrophes may precipitate DKA.
Initiation of subcutaneous insulin
A. When the serum bicarbonate and anion gap levels
are normal, subcutaneous regular insulin can bestarted. B. Intravenous and subcutaneous administration of
insulin should overlap to avoid redevelopment ofketoacidosis. The intravenous infusion may bestopped 1 hour after the first subcutaneous injectionof insulin.
C. Estimation of subcutaneous insulin requirements
1. Multiply the final insulin infusion rate times 24
hours. Two-thirds of the total dose is given in themorning as two-thirds NPH and one-third regularinsulin. The remaining one-third of the total dose isgiven before supper as one-half NPH and one-halfregular insulin. 2. Subsequent doses should be adjusted according to
the patient's blood glucose response.
Acute Renal Failure
Acute renal failure is defined as a sudden decrease in renalfunction sufficient to increase the concentration of nitroge-nous wastes in the blood. It is characterized by an increas-ing BUN and creatinine.
I. Clinical presentation of acute renal failure
A. Oliguria is a common indicator of acute renal failure,
and it is marked by a decrease in urine output to lessthan 30 mL/h. Acute renal failure may be oliguric(<500 L/day) or nonoliguric (>30 mL/h). Anuria (<100mL/day) does not usually occur in renal failure, andits presence suggests obstruction or a vascularcause.
B. Acute renal failure may also be manifest by
encephalopathy, volume overload, pericarditis,bleeding, anemia, hyperkalemia, hyperphosphatemia,hypocalcemia, and metabolic acidemia.
II. Clinical causes of renal failure
A. Prerenal insult
1. Prerenal insult is the most common cause of acute
renal failure, accounting for 70% of cases.
Prerenal failure is usually caused by reduced renalperfusion secondary to extracellular fluid loss(diarrhea, diuresis, GI hemorrhage) or secondaryto extracellular fluid sequestration (pancreatitis,sepsis), inadequate cardiac output, renalvasoconstriction (sepsis, liver disease, drugs), orinadequate fluid intake or replacement.
2. Most patients with prerenal azotemia have
oliguria, a history of large fluid losses (vomiting,diarrhea, burns), and evidence of intravascularvolume depletion (thirst, weight loss, orthostatichypotension, tachycardia, flat neck veins, drymucous membranes). Patients with congestiveheart failure may have total body volume excess(distended neck veins, pulmonary and pedaledema) but still have compromised renal perfusionand prerenal azotemia because of diminishedcardiac output.
3. Causes of prerenal failure are usually reversible if
recognized and treated early; otherwise, pro-longed renal hypoperfusion can lead to acutetubular necrosis and permanent renal insuffi-ciency.
B. Intrarenal insult
1. Acute tubular necrosis (ATN) is the most com-
mon intrinsic renal disease leading to ARF.
a. Prolonged renal hypoperfusion is the most
common cause of ATN.
b. Nephrotoxic agents (aminoglycosides, heavy
metals, radiocontrast media, ethylene glycol)represent exogenous nephrotoxins. ATN mayalso occur as a result of endogenousnephrotoxins, such as intratubular pigments(hemoglobinuria), intratubular proteins(myeloma), and intratubular crystals (uric acid).
2. Acute interstitial nephritis (AIN) is an allergic
reaction secondary to drugs (NSAIDs, β-lactams).
3. Arteriolar injury occurs secondary to hyperten-
sion, vasculitis, microangiopathic disorders.
4. Glomerulonephritis secondary to immunologi-
cally mediated inflammation may cause intrarenaldamage.
C. Postrenal insult results from obstruction of urine
flow. Postrenal insult is the least common cause ofacute renal failure, accounting for 10%. Postrenalinsult may be caused by obstruction secondary toprostate cancer, benign prostatic hypertrophy, orrenal calculi. Postrenal insult may be caused byamyloidosis, uric acid crystals, multiple myeloma,methotrexate, or acyclovir.
III.Clinical evaluation of acute renal failure
A. Initial evaluation of renal failure should determine
whether the cause is decreased renal perfusion,obstructed urine flow, or disorders of the renal paren-chyma. Volume status (orthostatic pulse, bloodpressure, fluid intake and output, daily weights,hemodynamic parameters), nephrotoxic medications,and pattern of urine output should be assessed.
B. Prerenal azotemia is likely when there is a history of
heart failure or extracellular fluid volume loss ordepletion.
C. Postrenal azotemia is suggested by a history of
decreased size or force of the urine stream, anuria,flank pain, hematuria or pyuria, or cancer of thebladder, prostate or pelvis.
D. Intrarenal insult is suggested by a history of pro-
longed volume depletion (often post-surgical),pigmenturia, hemolysis, rhabdomyolysis, ornephrotoxins. Intrarenal insult is suggested by recentradiocontrast, aminoglycoside use, or vascularcatheterization. Interstitial nephritis may be implicatedby a history of medication rash, fever, or arthralgias.
E. Chronic renal failure is suggested by diabetes
mellitus, normochromic normocytic anemia,hypercalcemia, and hyperphosphatemia.
A. Cardiac output, volume status, bladder size, and
systemic disease manifestations should be assessed.
B. Prerenal azotemia is suggested by impaired cardiac
output (neck vein distention, pulmonary rales, pedaledema). Volume depletion is suggested by orthostaticblood pressure changes, weight loss, low urineoutput, or diuretic use.
C. Flank, suprapubic, or abdominal masses may
indicate an obstructive cause.
D. Skin rash suggests drug-induced interstitial nephritis;
palpable purpura suggests vasculitis; nonpalpablepurpura suggests thrombotic thrombocytopenicpurpura or hemolytic-uremic syndrome.
E. Bladder catheterization is useful to rule out sus-
pected bladder outlet obstruction. A residual volumeof more than 100 mL suggests bladder outlet obstruc-tion.
F. Central venous monitoring is used to measure
cardiac output and left ventricular filling pressure ifprerenal failure is suspected.
V. Laboratory evaluation
A. Spot urine sodium concentration
1. Spot urine sodium can help distinguish between
prerenal azotemia and acute tubular necrosis.
2. Prerenal failure causes increased reabsorption of
salt and water and will manifest as a low spot urinesodium concentration <20 mEq/L and a low frac-tional sodium excretion <1%, and a urine/plasmacreatinine ration of >40. Fractional excretion ofsodium (%) = ([urine sodium/plasma sodium] ÷[urine creatinine/plasma creatinine] x 100).
3. If tubular necrosis is the cause, the spot urine
concentration will be >40 mEq/L, and fractionalexcretion of sodium will be >1%.
1. Normal urine sediment is a strong indicator of
prerenal azotemia or may be an indicator ofobstructive uropathy.
2. Hematuria, pyuria, or crystals may be asso-
ciated with postrenal obstructive azotemia.
3. Abundant cells, casts, or protein suggests an
4. Red cells alone may indicate vascular disorders.
RBC casts and abundant protein suggest glomeru-lar disease (glomerulonephritis).
5. White cell casts and eosinophilic casts indicate
6. Renal epithelial cell casts and pigmented
granular casts are associated with acute tubular
necrosis.
C. Ultrasound is useful for evaluation of suspected
postrenal obstruction (nephrolithiasis). The presenceof small (<10 cm in length), scarred kidneys is diag-nostic of chronic renal insufficiency.
Management of acute renal failure
A. Reversible disorders, such as obstruction, should be
excluded, and hypovolemia should be corrected withvolume replacement. Cardiac output should bemaintained. In critically ill patients, a pulmonary arterycatheter should be used for evaluation and monitor-ing.
B. Extracellular fluid volume expansion. Infusion of a
1-2 liter crystalloid fluid bolus may confirm suspectedvolume depletion.
C. If the patient remains oliguric despite euvolemia, IV
diuretics may be administered. A large single dose offurosemide (100-200 mg) may be administeredintravenously to promote diuresis. If urine flow is notimproved, the dose of furosemide may be doubled.
Furosemide may be repeated in 2 hours, or a contin-uous IV infusion of 10-40 mg/hr (max 1000 mg/day)may be used.
D. The dosage or dosing intervals of renally excreted
drugs should be modified.
E. Hyperkalemia is the most immediately life-threaten-
ing complication of renal failure. Serum potassiumvalues greater than 6.5 mEq/L may lead toarrhythmias and cardiac arrest. Potassium should beremoved from IV solutions. Hyperkalemia may betreated with sodium polystyrene sulfonate(Kayexalate), 30-60 gm PO/PR every 4-6 hours. F. Hyperphosphatemia can be controlled with alu-
minum hydroxide antacids (eg, Amphojel or Basaljel),15-30 ml or one to three capsules PO with meals,should be used.
G. Fluids. After normal volume has been restored, fluid
intake should be reduced to an amount equal to uri-nary and other losses plus insensible losses of 300-500 mL/day. In oliguric patients, daily fluid intake mayneed to be restricted to less than 1 L.
H. Nutritional therapy. A renal diet consisting of daily
high biologic value protein intake of 0.5 gm/kg/d,sodium 2 g, potassium 40-60 mg/day, and at least 35kcal/kg of nonprotein calories is recommended.
Phosphorus should be restricted to 800 mg/day I. Dialysis. Indications for dialysis include uremic
pericarditis, severe hyperkalemia, pulmonary edema,persistent severe metabolic acidosis (pH less than7.2), and symptomatic uremia.
Body potassium is 98% intracellular. Only 2% of total bodypotassium, about 70 mEq, is in the extracellular fluid, withthe normal concentration of 3.5-5 mEq/L.
I. Pathophysiology of potassium homeostasis
A. The normal upper limit of plasma K is 5-5.5 mEq/L,
with a mean K level of 4.3.
B. External potassium balance. Normal dietary K
intake is 1-1.5 mEq/kg in the form of vegetables andmeats. The kidney is the primary organ for preservingexternal K balance, excreting 90% of the daily Kburden.
C. Internal potassium balance. Potassium transfer to
and from tissues, is affected by insulin, acid-basestatus, catecholamines, aldosterone, plasmaosmolality, cellular necrosis, and glucagon.
II. Clinical disorders of external potassium balance
A. Chronic renal failure. The kidney is able to excrete
the dietary intake of potassium until the glomerularfiltration rate falls below 10 cc/minute or until urineoutput falls below 1 L/day. Renal failure is advancedbefore hyperkalemia occurs.
B. Impaired renal tubular function. Renal diseases
may cause hyperkalemia, and the renal tubularacidosis caused by these conditions may worsenhyperkalemia.
C. Primary adrenal insufficiency (Addison's disease)
is now a rare cause of hyperkalemia. Diagnosis isindicated by the combination of hyperkalemia andhyponatremia and is confirmed by a low aldosteroneand a low plasma cortisol level that does not respondto adrenocorticotropic hormone treatment.
D. Drugs that may cause hyperkalemia include
nonsteroidal anti-inflammatory drugs, angiotensin-converting enzyme inhibitors, cyclosporine, andpotassium-sparing diuretics. Hyperkalemia is espe-cially common when these drugs are given to pa-tients at risk for hyperkalemia (diabetics, renal failure,advanced age).
E. Excessive potassium intake
1. Long-term potassium supplementation results in
hyperkalemia most often when an underlyingimpairment in renal excretion already exists.
2. Intravenous administration of 0.5 mEq/kg over 1
hour increases serum levels by 0.6 mEq/L.
Hyperkalemia often results when infusions ofgreater than 40 mEq/hour are given.
Clinical disorders of internal potassium balance
A. Diabetic patients are at particular risk for severe
hyperkalemia because of renal insufficiency andhyporeninemic hypoaldosteronism.
B. Systemic acidosis reduces renal excretion of
potassium and moves potassium out of cells, result-ing in hyperkalemia.
C. Endogenous potassium release from muscle injury,
tumor lysis, or chemotherapy may elevate serumpotassium.
Manifestations of hyperkalemia
A. Hyperkalemia, unless severe, is usually asymptom-
atic. The effect of hyperkalemia on the heart be-comes significant above 6 mEq/L. As levels increase,the initial ECG change is tall peaked T waves. TheQT interval is normal or diminished.
B. As K levels rise further, the PR interval becomes
prolonged, then the P wave amplitude decreases.
The QRS complex eventually widens into a sinewave pattern, with subsequent cardiac standstill.
C. At serum K is >7 mEq/L, muscle weakness may lead
to a flaccid paralysis. Sensory abnormalities, im-paired speech and respiratory arrest may follow.
V. Pseudohyperkalemia
A. Potassium may be falsely elevated by hemolysis
during phlebotomy, when K is released from ischemicmuscle distal to a tourniquet, and because of erythro-cyte fragility disorders.
B. Falsely high laboratory measurement of serum
potassium may occur with markedly elevated plateletcounts (>106 platelet/mm3) or white blood cell counts(>50,000/mm3). Diagnostic approach to hyperkalemia
A. The serum K level should be repeat tested to rule out
laboratory error. If significant thrombocytosis orleukocytosis is present, a plasma potassium levelshould be determined.
B. The 24-hour urine output, urinary K excretion, blood
urea nitrogen, and serum creatinine should bemeasured. Renal K retention is diagnosed whenurinary K excretion is less than 20 mEq/day.
C. High urinary K, excretion of >20 mEq/day, is indica-
tive of excessive K intake as the cause.
Renal hyperkalemia
A. If urinary K excretion is low and urine output is in the
oliguric range, and creatinine clearance is lower than20 cc/minute, renal failure is the probable cause.
Prerenal azotemia resulting from volume depletionmust be ruled out because the hyperkalemia willrespond to volume restoration.
B. When urinary K excretion is low, yet blood urea
nitrogen and creatinine levels are not elevated andurine volume is at least 1 L daily and renal sodium excretion is adequate (about 20 mEq/day), theneither a defect in the secretion of renin or aldosteroneor tubular resistance to aldosterone is likely. Lowplasma renin and aldosterone levels, will confirm thediagnosis of hyporeninemic hypoaldosteronism.
Addison's disease is suggested by a low serumcortisol, and the diagnosis is confirmed with a ACTH(Cortrosyn) stimulation test.
C. When inadequate K excretion is not caused by
hypoaldosteronism, a tubular defect in K clearance issuggested. Urinary tract obstruction, renal transplant,lupus, or a medication should be considered.
VIII. Extrarenal hyperkalemia
A. When hyperkalemia occurs along with high urinary K
excretion of >20 mEq/day, excessive intake of K isthe cause. Potassium excess in IV fluids, diet, ormedication should be sought. A concomitant underly-ing renal defect in K excretion is also likely to bepresent. B. Blood sugar should be measured to rule out insulin
deficiency; blood pH and serum bicarbonate shouldbe measured to rule out acidosis.
C. Endogenous sources of K, such as tissue necrosis,
hypercatabolism, hematoma, gastrointestinal bleed-ing, or intravascular hemolysis should be excluded.
Management of hyperkalemia
A. Acute treatment of hyperkalemia
1. Calcium
a. If the electrocardiogram shows loss of P waves
or widening of QRS complexes, calcium shouldbe given IV; calcium reduces the cell membranethreshold potential.
b. Calcium chloride (10%) 2-3 g should be given
over 5 minutes. In patients with circulatorycompromise, 1 g of calcium chloride IV shouldbe given over 3 minutes.
c. If the serum K level is greater than 7 mEq/L,
calcium should be given. If digitalis intoxicationis suspected, calcium must be given cautiously.
Coexisting hyponatremia should be treated withhypertonic saline.
2. Insulin: If the only ECG abnormalities are peaked
T waves and the serum level is under 7 mEq/L,treatment should begin with insulin (regular insulin,5-10 U by IV push) with 50% dextrose water(D50W) 50 mL IV push. Repeated insulin doses of10 U and glucose can be given every 15 minutesfor maximal effect.
3. Sodium bicarbonate promotes cellular uptake of
K. It should be given as 1-2 vials (50-mEq/vials) IVpush.
4. Potassium elimination measures
a. Sodium polystyrene sulfonate (Kayexalate) is a
cation exchange resin which binds to potassiumin the lower GI tract. Dosage is 30-60 gm pre-mixed with sorbitol 20% PO/PR.
b. Furosemide (Lasix) 100 mg IV should be given
to promote kaliuresis.
c. Emergent hemodialysis for hyperkalemia is
rarely necessary except when refractory meta-bolic acidosis is present.
Hypokalemia is characterized by a serum potassiumconcentration of less than 3.5 mEq/L. Ninety-eight percentof K is intracellular.
I. Pathophysiology of hypokalemia
A. Cellular redistribution of potassium. Hypokalemia
may result from the intracellular shift of potassium byinsulin, beta-2 agonist drugs, stress inducedcatecholamine release, thyrotoxic periodic paralysis,and alkalosis-induced shift (metabolic or respiratory).
B. Nonrenal potassium loss
1. Gastrointestinal loss can be caused by diarrhea,
laxative abuse, villous adenoma, biliary drainage,enteric fistula, clay ingestion, potassium bindingresin ingestion, or nasogastric suction.
2. Sweating, prolonged low-potassium diet,
hemodialysis and peritoneal dialysis may alsocause nonrenal potassium loss.
C. Renal potassium loss
1. Hypertensive high renin states. Malignant
hypertension, renal artery stenosis, renin-produc-ing tumors.
2. Hypertensive low renin, high aldosterone
states. Primary hyperaldosteronism (adenoma or
hyperplasia).
3. Hypertensive low renin, low aldosterone states.
Congenital adrenal hyperplasia (11 or 17 hydroxy-lase deficiency), Cushing's syndrome or disease,exogenous mineralocorticoids (Florinef, licorice,chewing tobacco), Liddle's syndrome.
4. Normotensive states
a. Metabolic acidosis. Renal tubular acidosis
b. Metabolic alkalosis (urine chloride <10
c. Metabolic alkalosis (urine chloride >10
mEq/day). Bartter's syndrome, diuretics, mag-
nesium depletion, normotensive hyperaldo-
steronism
5. Drugs associated with potassium loss include
amphotericin B, ticarcillin, piperacillin, and loopdiuretics.
II. Clinical effects of hypokalemia
A. Cardiac effects. The most lethal consequence of
h y p o k a l e m i a i s c a r d i a c a r r h y t h m i a .
Electrocardiographic effects include a depressed STsegment, decreased T-wave amplitude, U waves,and a prolonged QT-U interval.
B. Musculoskeletal effects. The initial manifestation of
K depletion is muscle weakness, which can lead toparalysis. In severe cases, respiratory muscle paraly-sis may occur.
C. Gastrointestinal effects. Nausea, vomiting, consti-
pation, and paralytic ileus may develop.
A. The 24-hour urinary potassium excretion should be
measured. If >20 mEq/day, excessive urinary K lossis the cause. If <20 mEq/d, low K intake, or non-urinary K loss is the cause.
B. In patients with excessive renal K loss and hyperten-
sion, plasma renin and aldosterone should be mea-sured to differentiate adrenal from non-adrenalcauses of hyperaldosteronism.
C. If hypertension is absent and serum pH is acidotic,
renal tubular acidosis should be considered. If hyper-tension is absent and serum pH is normal to alkalotic,a high urine chloride (>10 mEq/d) suggestshypokalemia secondary to diuretics or Bartter'ssyndrome. A low urine chloride (<10 mEq/d) suggestsvomiting.
Emergency treatment of hypokalemia
A. Indications for urgent replacement.
Electrocardiographic abnormalities, myocardialinfarction, hypoxia, digitalis intoxication, markedmuscle weakness, or respiratory muscle paralysis.
B. Intravenous potassium therapy
1. Intravenous KCL is usually used unless concomi-
tant hypophosphatemia is present, where potas-sium phosphate is indicated.
2. The maximal rate of intravenous K replacement is
30 mEq/hour. The K concentration of IV fluidsshould be 80 mEq/L or less if given via a periph-eral vein. Frequent monitoring of serum K andconstant electrocardiographic monitoring is recom-mended when potassium levels are being re-placed.
V.Non-emergent treatment of hypokalemia
A. Attempts should be made to normalize K levels if
<3.5 mEq/L.
B. Oral supplementation is significantly safer than IV.
Liquid formulations are preferred due to rapid oral
absorption, compared to sustained release formula-
tions, which are absorbed over several hours.
1. KCL elixir 20-40 mEq qd-tid PO after meals.
2. Micro-K, 10 mEq tabs, 2-3 tabs tid PO after meals
(40-100 mEq/d).
Magnesium deficiency occurs in up to 11% of hospitalizedpatients. The normal range of serum magnesium is 1.5 to2.0 mEq/L, which is maintained by the kidney, intestine,and bone.
A. Decreased magnesium intake. Protein-calorie
malnutrition, prolonged parenteral fluid administration,and catabolic illness are common causes ofhypomagnesemia.
B. Gastrointestinal losses of magnesium may result
from prolonged nasogastric suction, laxative abuse,and pancreatitis.
C. Renal losses of magnesium
1. Renal loss of magnesium may occur secondary to
renal tubular acidosis, glomerulonephritis, interstitialnephritis, or acute tubular necrosis.
hypophosphatemia may cause magnesium loss.
3. Agents that enhance renal magnesium excretion
include alcohol, loop and thiazide diuretics,amphotericin B, aminoglycosides, cisplatin, andpentamidine.
D. Alterations in magnesium distribution
1. Redistribution of circulating magnesium occurs by
extracellular to intracellular shifts, sequestration,hungry bone syndrome, or by acute administrationof glucose, insulin, or amino acids.
2. Magnesium depletion can be caused by large
quantities of parenteral fluids and pancreatitis-induced sequestration of magnesium.
II.Clinical manifestations of hypomagnesemia
A. Neuromuscular findings may include positive
Chvostek's and Trousseau's signs, tremors, myoclonicjerks, seizures, and coma.
B. Cardiovascular. Ventricular tachycardia, ventricular
fibrillation, atrial fibrillation, multifocal atrial tachycar-dia, ventricular ectopic beats, hypertension, enhance-ment of digoxin-induced dysrhythmias, and cardio-myopathies.
C. ECG changes include ventricular arrhythmias (extra-
systoles, tachycardia) and atrial arrhythmias (atrialfibrillation, supraventricular tachycardia, torsades dePointes). Prolonged PR and QT intervals, ST segmentdepression, T-wave inversions, wide QRS complexes,and tall T-waves may occur.
A. Hypomagnesemia is diagnosed when the serum
magnesium is less than 0.7-0.8 mmol/L. Symptoms ofmagnesium deficiency occur when the serum magne-sium concentration is less than 0.5 mmol/L. A 24-hoururine collection for magnesium is the first step in theevaluation of hypomagnesemia. Hypomagnesiacaused by renal magnesium loss is associated withmagnesium excretion that exceeds 24 mg/day.
B. Low urinary magnesium excretion (<1 mmol/day), with
concomitant serum hypomagnesemia, suggestsmagnesium deficiency due to decreased intake,nonrenal losses, or redistribution of magnesium.
IV. Treatment of hypomagnesemia
A. Asymptomatic magnesium deficiency
1. In hospitalized patients, the daily magnesium
requirements can be provided through either abalanced diet, as oral magnesium supplements(0.36-0.46 mEq/kg/day), or 16-30 mEq/day in aparenteral nutrition formulation.
2. Magnesium oxide is better absorbed and less likely
to cause diarrhea than magnesium sulfate. Magne-sium oxide preparations include Mag-Ox 400 (240mg elemental magnesium per 400 mg tablet), Uro-Mag (84 mg elemental magnesium per 400 mgtablet), and magnesium chloride (Slo-Mag) 64mg/tab, 1-2 tabs bid.
B. Symptomatic magnesium deficiency
1. Serum magnesium <0.5 mmol/L requires IV magne-
sium repletion with electrocardiographic and respi-ratory monitoring.
2. Magnesium sulfate 1-6 gm in 500 mL of D5W can
be infused IV at 1 gm/hr. An additional 6-9 gm ofMgSO should be given by continuous infusion over the next 24 hours.
Serum magnesium has a normal range of 0.8-1.2 mmol/L.
Magnesium homeostasis is regulated by renal and gastro-intestinal mechanisms. Hypermagnesemia is usuallyiatrogenic and is frequently seen in conjunction with renalinsufficiency.
I. Clinical evaluation of hypermagnesemia
A. Causes of hypermagnesemia
1. Renal. Creatinine clearance <30 mL/minute.
2. Nonrenal. Excessive use of magnesium cathartics,
especially with renal failure; iatrogenicovertreatment with magnesium sulfate.
hypermagnesemia
1. Hypermagnesemia <10 mEq/L. Delayed
interventricular conduction, first-degree heart block,prolongation of the Q-T interval.
2. Levels greater than 10 mEq/L. Low-grade heart
block progressing to complete heart block andasystole occurs at levels greater than 12.5 mmol/L(>6.25 mmol/L).
C. Neuromuscular effects
1. Hyporeflexia occurs at a magnesium level >4
mEq/L (>2 mmol/L); diminution of deep tendonreflexes is an early sign of magnesium toxicity.
2. Respiratory depression due to respiratory muscle
paralysis, somnolence and coma occur at levels>13 mEq/L (6.5 mmol/L). 3. Hypermagnesemia should always be considered
when these symptoms occur in patients with renalfailure, in those receiving therapeutic magnesium,and in laxative abuse. II.Treatment of hypermagnesemia
A. Asymptomatic, hemodynamically stable patients.
Moderate hypermagnesemia can be managed byelimination of intake.
B. Severe hypermagnesemia
1. Furosemide 20-40 mg IV q3-4h should be given as
needed. Saline diuresis should be initiated with0.9% saline, infused at 120 cc/h to replace urineloss.
2. If ECG abnormalities (peaked T waves, loss of P
waves, or widened QRS complexes) or if respira-tory depression is present, IV calcium gluconateshould be given as 1-3 ampules (10% solution, 1gm per 10 mL amp), added to saline infusate.
Calcium gluconate can be infused to reverse acutecardiovascular toxicity or respiratory failure as 15mg/kg over a 4-hour period.
3. Parenteral insulin and glucose can be given to shift
magnesium into cells. Dialysis is necessary forpatients who have severe hypermagnesemia.
Disorders of Water and Sodium Bal-
ance
I. Pathophysiology of water and sodium balance
A. Volitional intake of water is regulated by thirst. Mainte-
nance intake of water is the amount of water sufficientto offset obligatory losses. B. Maintenance water needs
100 mL/kg for first 10 kg of body weight + 50 mL/kg for next 10 kg+ 20 mL/kg for weight greater than 20 kg C. Clinical signs of hyponatremia. Confusion, agita-
tion, lethargy, seizures, and coma.
1. Elevation of blood glucose may creates an osmotic
gradient that pulls water from cells into theextracellular fluid, diluting the extracellular sodium.
The contribution of hyperglycemia to hyponatremiacan be estimated using the following formula: Expected change in serum sodium = (serumglucose - 100) x 0.016 2. Marked elevation of plasma lipids or protein can
also result in erroneous hyponatremia because oflaboratory inaccuracy. The percentage of plasmawater can be estimated with the following formula:% plasma water = 100 - [0.01 x lipids (mg/dL)] -[0.73 x protein (g/dL)] II.Diagnostic evaluation of hyponatremia
A. Pseudohyponatremia should be excluded by repeat
testing. The cause of the hyponatremia should bedetermined based on history, physical exam, urineosmolality, serum osmolality, urine sodium andchloride. An assessment of volume status shoulddetermine if the patient is volume contracted, normalvolume, or volume expanded.
B. Classification of hyponatremic patients based on
urine osmolality
1. Low-urine osmolality (50-180 mOsm/L) indicates
primary excessive water intake (psychogenic waterdrinking).
2. High-urine osmolality (urine osmolality >serum
High-urine sodium (>40 mEq/L) and volume
contraction indicates a renal source of sodium
loss and fluid loss (excessive diuretic use, salt-
wasting nephropathy, Addison's disease,
osmotic diuresis).
High-urine sodium (>40 mEq/L) and normal
volume is most likely caused by water reten-
tion due to a drug effect, hypothyroidism, or the
syndrome of inappropriate antidiuretic hor-
mone secretion. In SIADH, the urine sodium
level is usually high. SIADH is found in the
presence of a malignant tumor or a disorder of
the pulmonary or central nervous system.
Low-urine sodium (<20 mEq/L) and volume
contraction, dry mucous membranes, de-
creased skin turgor, and orthostatic
hypotension indicate an extrarenal source of
fluid loss (gastrointestinal disease, burns).
Low-urine sodium (<20 mEq/L) and volume-
expansion, and edema is caused by conges-
tive heart failure, cirrhosis with ascites, or
nephrotic syndrome. Effective arterial blood
volume is decreased. Decreased renal perfu-
sion causes increased reabsorption of water.
Drugs Associated with SIADH
III. Treatment of water excess hyponatremia
A. Determine the volume of water excess
Water excess = total body water x ([140/measuredsodium] -1) B. Treatment of asymptomatic hyponatremia. Water
intake should be restricted to 1,000 mL/day. Foodalone in the diet contains this much water, so noliquids should be consumed. If an intravenoussolution is needed, an isotonic solution of 0.9%sodium chloride (normal saline) should be used.
Dextrose should not be used in the infusion becausethe dextrose is metabolized into water.
C. Treatment of symptomatic hyponatremia
1. If neurologic symptoms of hyponatremia are
present, the serum sodium level should be cor-rected with hypertonic saline. Excessively rapidcorrection of sodium may result in a syndrome ofcentral pontine demyelination.
2. The serum sodium should be raised at a rate of 1
mEq/L per hour. If hyponatremia has beenchronic, the rate should be limited to 0.5 mEq/Lper hour. The goal of initial therapy is a serumsodium of 125-130 mEq/L, then water restrictionshould be continued until the level normalizes.
3. The amount of hypertonic saline needed is esti-
mated using the following formula: Sodium needed (mEq) = 0.6 x wt in kg x (desired sodium -measured sodium) 4. Hypertonic 3% sodium chloride contains 513
mEq/L of sodium. The calculated volume requiredshould be administered over the period requiredto raise the serum sodium level at a rate of 0.5-1mEq/L per hour. Concomitant administration offurosemide may be required to lessen the risk offluid overload. A. Clinical manifestations of hypernatremia: Clinical
manifestations include tremulousness, irritability,ataxia, spasticity, mental confusion, seizures, andcoma.
B. Causes of hypernatremia
1. Net sodium gain or net water loss will cause
2. Failure to replace obligate water losses may
cause hypernatremia, as in patients unable toobtain water because of an altered mental statusor severe debilitating disease.
3. Diabetes insipidus: If urine volume is high but
urine osmolality is low, diabetes insipidus is themost likely cause.
Drugs Associated with Diabetes Insipidus
C. Diagnosis of hypernatremia
1. Assessment of urine volume and osmolality are
essential in the evaluation of hyperosmolality. Theusual renal response to hypernatremia is theexcretion of the minimum volume (<500 mL/day)of maximally concentrated urine (urine osmolality>800 mOsm/kg). These findings suggestextrarenal water loss.
2. Diabetes insipidus generally presents with
polyuria and hypotonic urine (urine osmolality<250 mOsm/kg).
V. Management of hypernatremia
A. If there is evidence of hemodynamic compromise
(eg, orthostatic hypotension, marked oliguria), fluiddeficits should be corrected initially with isotonicsaline. Once hemodynamic stability is achieved, theremaining free water deficit should be corrected with5% dextrose water or 0.45% NaCl.
B. The water deficit can be estimated using the follow-
Water deficit = 0.6 x wt in kg x (1 - [140/measuredsodium]). C. The change in sodium concentration should not
exceed 1 mEq/liter/hour. One-half of the calculatedwater deficit can be administered in the first 24hours, followed by correction of the remaining deficitover the next 1-2 days. The serum sodium concen- tration and ECF volume status should be evaluatedevery 6 hours. Excessively rapid correction ofhypernatremia may lead to lethargy and seizuressecondary to cerebral edema.
D. Maintenance fluid needs from ongoing renal and
insensible losses must also be provided. If thepatient is conscious and able to drink, water shouldbe given orally or by nasogastric tube.
E. Treatment of diabetes insipidus
1. Vasopressin (Pitressin) 5-10 U IV/SQ q6h; fast
onset of action with short duration.
2. Desmopressin (DDAVP) 2-4 mcg IV/SQ q12h;
slow onset of action with long duration of effect.
A. Water excess and saline deficit occurs when
severe vomiting and diarrhea occur in a patient whois given only water. Clinical signs of volume contrac-tion and a low serum sodium are present. Salinedeficit is replaced and free water intake restricteduntil the serum sodium level has normalized.
B. Water and saline excess often occurs with heart
failure, manifesting as edema and a low serumsodium. An increase in the extracellular fluid volume,as evidenced by edema, is a saline excess. Amarked excess of free water expands theextracellular fluid volume, causing apparent hypo-natremia. However, the important derangement inedema is an excess of sodium. Sodium and waterrestriction and use of furosemide are usually indi-cated in addition to treatment of the underlyingdisorder.
C. Water and saline deficit is frequently caused by
vomiting and high fever and is characterized by signsof volume contraction and an elevated serum so-dium. Saline and free water should be replaced inaddition to maintenance amounts of water.
Hypercalcemic crisis is defined as an elevation in serumcalcium that is associated with volume depletion, mentalstatus changes, and life-threatening cardiac arrhythmias.
Hypercalcemic crisis is most commonly caused by malig-nancy-associated bone resorption.
I. Diagnosis
A. Hypercalcemic crisis is often complicated by nausea,
vomiting, hypovolemia, mental status changes, andhypotension.
B. A correction for the low albumin level must be made
because ionized calcium is the physiologically impor-tant form of calcium.
Corrected serum calcium (mg/dL) = serum calcium +0.8 x (4.0 - albumin [g/dL]) C. Most patients in hypercalcemic crisis have a cor-
rected serum calcium level greater than 13 mg/dL.
D. The ECG often demonstrates a short QT interval.
Bradyarrhythmias, heart blocks, and cardiac arrestmay also occur.
II. Treatment of hypercalcemic crisis
A. Normal saline should be administered until the
patient is normovolemic. If signs of fluid overloaddevelop, furosemide (Lasix) can be given to promotesodium and calcium diuresis. Thiazide diuretics,vitamin D supplements and antacids containingsodium bicarbonate should be discontinued.
B. Pamidronate disodium (Aredia) is the agent of choice
for long-term treatment of hypercalcemia. A singledose of 90-mg infused IV over 24 hours shouldnormalize calcium levels in 4 to 7 days. Thepamidronate dose of 30- to 90-mg IV infusion may berepeated 7 days after the initial dose. Smaller doses(30 or 60 mg IV over 4 hours) are given every fewweeks to maintain normal calcium levels.
C. Calcitonin (Calcimar, Miacalcin) has the advantage of
decreasing serum calcium levels within hours; 4 to 8U/kg SQ/IM q12h. Calcitonin should be used inconjunction with pamidronate in severelyhypercalcemic patients.
Clinical manifestations of hypophosphatemia include heartfailure, muscle weakness, tremor, ataxia, seizures, coma,respiratory failure, delayed weaning from ventilator,hemolysis, and rhabdomyolysis.
I. Differential diagnosis of hypophosphatemia
A. Increased urinary excretion: Hyperparathyroidism,
renal tubular defects, diuretics.
B. Decrease in GI absorption: Malnutrition,
malabsorption, phosphate binding minerals(aluminum-containing antacids).
C. Abnormal vitamin D metabolism: Vitamin D defi-
ciency, familial hypophosphatemia, tumor-associatedhypercalcemia.
D. Intracellular shifts of phosphate: Diabetic
ketoacidosis, respiratory alkalosis, alcohol with-drawal, recovery phase of starvation.
II. Labs: Phosphate, SMA 12, LDH, magnesium, calcium,
albumin, PTH, urine electrolytes. 24-hr urine phosphate,and creatinine.
Diagnostic approach to hypophosphatemia
A. 24-hr urine phosphate
1. If 24-hour urine phosphate is less than 100
mg/day, the cause is gastrointestinal losses(emesis, diarrhea, NG suction, phosphate bind-ers), vitamin D deficit, refeeding, recovery fromburns, alkalosis, alcoholism, or DKA.
2. If 24-hour urine phosphate is greater than 100
mg/day, the cause is renal losses,hyperparathyroidism, hypomagnesemia, hypo-kalemia, acidosis, diuresis, renal tubular defects,or vitamin D deficiency.
A. Mild hypophosphatemia (1.0-2.5 mEq/dL)
1. Na or K phosphate 0.25 mMol/kg IV infusion at the
rate of 10 mMol/hr (in NS or D5W 150-250 mL),may repeat as needed.
2. Neutral phosphate (Nutra-Phos), 2 packs PO bid-
tid (250 mg elemental phosphorus/pack.
B. Severe hypophosphatemia (<1.0 mEq/dL)
1. Administer Na or K phosphate 0.5 m Moles/Kg IV
infusion at the rate of 10 mMoles/hr (NS or D5W150-250 mL), may repeat as needed.
2. Add potassium phosphate to IV solution in place
of KCl (max 80 mEq/L infused at 100-150 mL/h).
Max IV dose 7.5 mg phosphorus/kg/6h OR 2.5-5
mg elemental phosphorus/kg IV over 6h. Give as
potassium or sodium phosphate (93 mg phos-
phate/mL and 4 mEq Na+ or K+/mL). Do not mix
calcium and phosphorus in same IV.
I. Clinical manifestations of hyperphosphatemia:
Hypotension, bradycardia, arrhythmias, bronchospasm,apnea, laryngeal spasm, tetany, seizures, weakness,psychosis, confusion.
II. Clinical evaluation of hyperphosphatemia
A. Exogenous phosphate administration: Enemas,
laxatives, diphosphonates, vitamin D excess.
B. Endocrine disturbances: Hypoparathyroidism,
acromegaly, PTH resistance.
C. Labs: Phosphate, SMA 12, calcium, parathyroid
hormone. 24-hr urine phosphate, creatinine.
III. Therapy: Correct hypocalcemia, restrict dietary
phosphate, saline diuresis.
A. Moderate hyperphosphatemia
1. Aluminum hydroxide (Amphojel) 5-10 mL or 1-2
tablets PO ac tid; aluminum containing agents
bind to intestinal phosphate, and decreases
absorption OR
2. Aluminum carbonate (Basaljel) 5-10 mL or 1-2
tablets PO ac tid OR
3. Calcium carbonate (Oscal) (250 or 500 mg
elemental calcium/tab) 1-2 gm elemental cal-cium PO ac tid. Keep calcium-phosphate product<70; start only if phosphate <5.5.
B. Severe hyperphosphatemia
1. Volume expansion with 0.9% saline 1 L over 1h
if the patient is not azotemic.
2. Dialysis is recommended for patients with renal
References may be obtained at www.ccspublishing.com.
Commonly Used Drug Levels
Amikacin . . . . . . . Peak 25-30; trough <10 mc-g/mLAmiodarone . . . . . . 1.0-3.0 mcg/mLAmitriptyline . . . . . . 100-250 ng/mLCarbamazepine . . . . 4-10 mcg/mLChloramphenicol . . . . Peak 10-15; trough <5 mcg/mLDesipramine . . . . . . 150-300 ng/mLDigoxin . . . . . . . . 0.8-2.0 ng/mLDisopyramide . . . . . 2-5 mcg/mLDoxepin . . . . . . . 75-200 ng/mLFlecainide . . . . . . . 0.2-1.0 mcg/mLGentamicin . . . . . . Peak 6.0-8.0; trough <2.0mcg/mL Imipramine . . . . . . 150-300 ng/mLLidocaine . . . . . . . 2-5 mcg/mLLithium . . . . . . . . 0.5-1.4 mEq/LNortriptyline . . . . . . 50-150 ng/mLPhenobarbital . . . . . 10-30 mEq/mLPhenytoin** . . . . . . 8-20 mcg/mLProcainamide . . . . . 4.0-8.0 mcg/mLQuinidine . . . . . . . 2.5-5.0 mcg/mLSalicylate . . . . . . . 15-25 mg/dLTheophylline . . . . . . 8-20 mcg/mLValproic acid . . . . . . 50-100 mcg/mLVancomycin . . . . . . Peak 30-40; trough <10 mc-g/mL * The therapeutic range of some drugs may vary depend-ing on the reference lab used.
** Therapeutic range of phenytoin is 4-10 mcg/mL inpresence of significant azotemia and/or hypoalbuminemia.
Drugs that Prolong the QT-Interval
Source: http://drstuff.net/wp-content/uploads/2013/03/crirical_care_USA.pdf
Psychiatrist beats suit blaming him for patient's killing mom
Psychiatrist Beats Suit Blaming Him for Patient's Killing Mom Milton Satcher and Laura Strong defended a psychiatrist accused of breaching the standard of care bycutting a patient's medications.John Disney/Daily Report After 10 years and two appeals, the guardians of a mental y disabled man who kil ed his mother weeks after hisdoctor took him off anti-psychotic medications have walked away with nothing from their medical malpractice suit.
Sljim cover.ai
Volume 01 Number 02 Page 51 - 99 December 2011 ISSN 2012 – 9238 Sri Lanka Journal of Indigenous Medicine Peer reviewed research publication of the INSTITUTE OF INDIGENOUS MEDICINE University of Colombo, Rajagiriya, Sri Lanka Sri Lanka Journal of Indigenous Medicine (SLJIM)