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Suhail Allaqaband Sinai Samaritan Medical Center Milwaukee, WI

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... massive overdose can lead to hyperkalemia as inhibition of the Na-K-ATPase pump impairs potassium entry into cells Plasma digoxin levels are markedly elevated ... – PowerPoint PPT presentation

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Title: Suhail Allaqaband Sinai Samaritan Medical Center Milwaukee, WI


1
Suhail AllaqabandSinai Samaritan Medical
CenterMilwaukee, WI
Digitalis Intoxication
2
Digitalis Intoxication
  • Cardiac glycoside poisoning is a potentially
    life-threatening problem
  • In a series of 150 severely affected patients
  • 50 were receiving long-term digitalis therapy,
  • 10 had taken an accidental large overdose, and
  • 40 had ingested an overdose with suicidal
    intent
  • Treatment of 150 cases of life-threatening
    digitalis intoxication with digoxin-specific Fab
    antibody fragments. Final report of a multicenter
    study.
  • Circulation 1990 811744

3
Digitalis Intoxication
  • The mortality in different studies has ranged
    from 3 to 40 percent
  • Recent advances have considerably lowered the
    incidence of digitalis overdose in patients
    receiving chronic therapy. These include
  • A better understanding of pharmacokinetics,
    leading to more appropriate maintenance dosing
  • Increasing awareness of drugs that can affect
    digoxin metabolism
  • The development of radioimmunoassays for plasma
    digoxin levels

4
PHARMACOLOGY
  • Digitalis acts at the subcellular level by
    inhibiting the membrane-bound Na-K-ATPase pump
  • The net effect is the intracellular loss of
    potassium and the gain of sodium and calcium
  • Drug action depends on the tissue conc., which is
    relatively constant in relation to plasma levels
  • Thus, plasma levels can be used to monitor
    compliance and toxicity

5
PHARMACOLOGY
  • The two digitalis preparations used in clinical
    practice today are digoxin and digitoxin
  • The bioavailability of digoxin is about 80 and
    plasma half-life is 1.6 days
  • Major depot for digitalis in humans is skeletal
    muscle
  • As a result, dosage requirements and the
    likelihood of toxicity are related to muscle mass
    rather than total body weight
  • Approximately one-third of the body stores of
    digoxin is excreted per day 30 unchanged in
    the urine, and 3 as metabolites in stool

6
PREDISPOSING FACTORS TO TOXICITY
  • Drug Interactions
  • A number of drugs can raise digitalis levels by
    interfering with its metabolism or renal
    excretion
  • Renal insufficiency
  • End-stage renal disease, prolongs the half-life
    of digoxin and reduces its volume of distribution
  • There must be reductions both in the loading dose
    (by about 40 percent) and in the maintenance
    dose (by 50 to 75 percent) in this setting

7
PREDISPOSING FACTORS TO TOXICITY
  • Finally, there are a number of factors that can
    increase the sensitivity to digoxin and
    predispose to toxicity at plasma levels at the
    upper limits of normal
  • old age,
  • certain cardiac diseases - active ischemia,
    myocarditis, cardiomyopathy, cardiac amyloidosis,
    cor pulmonale
  • metabolic factors - hypokalemia, hypomagnesemia,
    hypoxemia, hypernatremia, hypercalcemia, and
    acid-base disturbances

8
CLINICAL MANIFESTATIONS
  • There are multiple, mostly nonspecific
    manifestations of digitalis toxicity
  • These include fatigue, blurred vision, disturbed
    color perception, anorexia, nausea, vomiting,
    diarrhea, abdominal pain, headache, dizziness,
    confusion, delirium, and occasionally
    hallucinations
  • Cardiac arrhythmias are responsible for mortality
    in this setting and may take almost any form

9
CLINICAL MANIFESTATIONS
  • The combination of SVT and AV block, for example,
    is highly suggestive of digitalis toxicity
  • Although hypokalemia predisposes to digitalis
    toxicity, massive overdose can lead to
    hyperkalemia as inhibition of the Na-K-ATPase
    pump impairs potassium entry into cells
  • Plasma digoxin levels are markedly elevated in
    these patients, usually being above 10 ng/mL
    Other signs of toxicity can occur at lower levels
    of 3 to 5 ng/mL

10
PLASMA DIGOXIN LEVELS
  • Plasma digoxin levels should be measured at least
    6 hours after the last dose, since this is
    the time required for attainment of the steady
    state
  • The plasma digoxin concentration should be used
    only as a guide to appropriate therapeutic dosing
  • Several factors (importantly hypokalemia) can
    predispose to toxicity at levels below 2 ng/mL,
    which is considered the upper limit of normal
  • On the other hand, clearly elevated levels (above
    3 ng/mL) can be seen in asymptomatic patients

11
PLASMA DIGOXIN LEVELS
  • False positive elevations of plasma digoxin can
    occur in newborns, pregnant women, and patients
    with chronic renal failure or hepatobiliary
    disease
  • This problem is thought to result from increased
    levels of endogenous digoxin-like substances
  • The highest values (up to 4 ng/mL) are seen in
    neonates
  • Smaller errors of 0.6 to 1.8 ng/mL have been
    described in the third trimester of pregnancy,
    renal failure, and combined hepatic and renal
    failure
  • Large doses of steroid derivatives, such as
    spironolactone and methylprednisolone, can cross
    react with the digoxin radioimmunoassay

12
GENERAL PRINCIPLES OF THERAPY
  • Gastrointestinal decontamination
  • ipecac-induced emesis or lavage is carried out
    with care to avoid vagal stimulation which may
    worsen existing conduction block
  • activated charcoal effectively adsorbs digitalis,
    if ingestion has occurred within 6-8 hours
  • repeated doses can be given to adsorb active
    metabolites as they are excreted by the biliary
    tract
  • cholestyramine is an alternative to activated
    charcoal

13
GENERAL PRINCIPLES OF THERAPY
  • Correction of electrolyte imbalances
  • Hypokalemia, hypomagnesemia, and other
    electrolyte disorders should be corrected
  • Potassium replacement should be given carefully,
    since raising the plasma potassium concentration
    can increase atrioventricular block
  • Some acutely intoxicated patients present with
    severe hyperkalemia, requiring therapy with
    glucose and insulin and sodium bicarbonate

14
GENERAL PRINCIPLES OF THERAPY
  • Management of cardiac arrythmias
  • Severe bradyarrhythmias are treated with
    atropine, electrical pacing is used in
    unresponsive patients
  • Therapy of cardiac ectopy is reserved for more
    complex forms
  • Lidocaine and phenytoin are antiarrhythmic drugs
    of first choice
  • Verapamil is useful for SVTs
  • Cardioversion should be limited to patients with
    life-threatening arrhythmias and used at the
    lowest effective energy level

15
DIGOXIN-SPECIFIC ANTIBODY FRAGMENTS
  • Digoxin-specific antibody Fab fragments
    (Digibind), purified from sheep IgG, rapidly
    bind to circulating digoxin and are indicated in
  • Ingestion of more than 10 mg of digoxin in adults
    or 4 mg in children
  • Plasma digoxin concentration above 10 ng/mL
  • A plasma potassium concentration above 5 meq/L in
    the presence of life-threatening arrhythmia
    ventricular tachycardia or fibrillation,
    progressive bradycardia, or high degree AV nodal
    block

16
Mechanism of action of Digibind
  • The proposed sequence of events that occurs after
    infusion of Fab fragments begins with rapid
    binding of intravascular digoxin and is followed
    by diffusion of the fragments into the
    interstitial space to bind free digoxin at that
    site
  • The affinity of the fragments for digoxin is
    greater than the affinity of digoxin for Na-K
    ATPase
  • The Fab fragments are relatively small (mol wt
    50,000) which allows them and bound digoxin to be
    rapidly excreted by glomerular filtration in
    patients with near-normal renal function
  • The elimination half-life of the fragments is 15
    to 20 hours in this setting

17
Digibind
  • Digibind can also be successfully in patients
    with renal insufficiency, including those on
    maintenance dialysis
  • In the largest study, 18 patients had a
    pretreatment plasma creatinine concentration of
    more than 5 mg/dL, including five who were
    on dialysis
  • These patients responded to Digibind in a manner
    similar to patients with normal renal function

18
Efficacy of Digibind
  • In the largest series of 150 patients with
    life-threatening digitalis toxicity,
  • 80 percent had resolution of all signs and
    symptoms,
  • 10 percent improved, and
  • 10 percent showed no response
  • The median time to initial response was 19
    minutes and the time to complete response was 88
    minutes
  • Of the patients who experienced cardiac arrest,
    54 percent survived hospitalization

19
  • Several factors which contribute to partial
    responses or resistance include,
  • underlying heart disease that was the true cause
    of some of the presumed manifestations of
    digitalis toxicity,
  • too low a dose of Fab, and
  • treatment of patients who were already moribund
  • A dramatic fall in the plasma potassium
    concentration can occur after digibind therapy
  • The decline in the plasma potassium concentration
    begins within one hour and is complete within 4
    hrs
  • Thus, monitoring of the plasma potassium
    concentration should be performed in all patients
    receiving this therapy

20
Side effects of digibind therapy
  • Despite the improvement induced by digibind,
    potentially important side effects can occur
  • exacerbation of congestive heart failure,
  • increased ventricular response in patients with
    A-fib.
  • hypokalemia
  • Idiosyncratic allergic manifestations are very
    rare, occurring in less than one percent of cases
  • Plasma digoxin measurements are unreliable for
    one to two weeks after fragment therapy

21
Dosing regimen for digoxin-specific antibody
fragments
  • Total body load of digitalis (TBL, in mg)
    SDC (serum digitalis concentration) x volume of
    distribution x weight (kg)
  • The serum digitalis concentration is measured in
    ng/mL and for digoxin, the volume of distribution
    is 5.6 L/kg, therefore
  • TBL (SDC x 5.6 x weight) 1000
  • One vial of digibind contains 40 mg, which
    neutralizes approximately 0.6 mg of digoxin

22
Dosing regimen for digoxin-specific antibody
fragments
  • Number of vials TBL 0.6
  • Or
  • Number of vials (SDC x weight) 100

23
  • If the amount ingested is known, then the TBL can
    be calculated directly
  • TBL Dose ingested (mg) x 0.8 for digoxin
    which has 80 percent bioavailability
  • If the SDC and the amount ingested are not known,
    then digibind is given empirically according to
    the following regimen
  • For an acute overdose in adults
  • Give 10 vials repeat with another 10 vials if
    indicated
  • With chronic toxicity
  • Give 6 vials to an adult, one vial to a child

24
EXTRACORPOREAL TECHNIQUES
  • Hemodialysis or hemoperfusion can help control
    hyperkalemia or volume overload in patients with
    concurrent renal failure
  • They are, however, of limited utility in removal
    of digoxin because of its extensive tissue
    binding and very large volume of distribution
    (5.6 L/kg)
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