Contact Us    Contact Us     |     Feedback
MOBILE VIEW  | 

CLINICAL APPROACH TO TOXIN-INDUCED TACHYARRHYTHMIAS

Export To Excel

Classification   |    Detailed evidence-based information

Substances Included Synonyms

Therapeutic Toxic Class

    A) This management will be limited to toxin-induced tachydysrhythmias of the unknown agent and the clinical features associated with these agent(s). Refer to the individual drug or chemical management(s) if the toxin is known or suspected.

Specific Substances

    1) Toxin-induced tachydysrhythmias

Overview

Life Support

    A) This overview assumes that basic life support measures have been instituted.

Clinical Effects

    0.2.1) SUMMARY OF EXPOSURE
    A) WITH POISONING/EXPOSURE
    1) Both supraventricular and ventricular tachydysrhythmias may occur in poisoning and often complicate the treatment of a patient with a toxic ingestion. Sinus tachycardia is the most common rhythm seen in the poisoned patient and may result from toxic effects associated with fever, stress, hypovolemia, catecholamine excess, or from the direct effects of the toxin on the sinoatrial node. Supraventricular tachycardias occur frequently in poisoned patients and the most common agents are medications or toxins with anticholinergic activity, antiarrrhythmics, and sympathomimetic drugs.
    2) Endocrine, hepatic, renal, and nervous system dysfunction might also arise secondary to poisoning from a toxin or drug that causes tachydysrhythmias. Electrolyte disturbances such as hypocalcemia, hypokalemia and hypomagnesemia often precede a cardiovascular event during poisoning.
    0.2.3) VITAL SIGNS
    A) WITH POISONING/EXPOSURE
    1) HYPERTHERMIA
    a) The presence of fever, in particular a temperature of 106 degrees F (of >41.1 degrees C), along with hemodynamic compromise or tachydysrhythmias may be an indication of a toxic ingestion. The following is a list of potential agents that may be associated with these clinical findings.
    1) Anticholinergics
    2) Antihistamines
    3) Antidepressants, tricyclic
    4) Ethanol
    5) Lithium
    6) Phenothiazine
    7) Detura species (Jimson weed and Moonflower)
    8) Stimulants
    9) Sympathomimetics
    10) Reference: (Hessler, 2002)
    2) HYPOTHERMIA
    a) Hypothermia, along with tachydysrhythmias or hemodynamic compromise, may occur with these agents: macrolide antibiotics, antidepressants and phenothiazines (Hessler, 2002).
    3) ALTERATIONS IN BLOOD PRESSURE
    a) Relatively rapid changes in blood pressure (ie, initial hypertension followed by hypotension) can occur following a toxic ingestion that also produces hemodynamic compromise or tachydysrhythmias. Some possible agents include: antihistamines, SSRIs, bretylium, jimson weed, and phenothiazines (Hessler, 2002).
    b) HYPOTENSION - Some drugs/toxins can produce a decrease in blood pressure, along with hemodynamic instability or tachydysrhythmias. Potential agents may include the following:
    1) Acotinium
    2) Antidepressants
    3) Antimalarials
    4) Arsenic
    5) Calcium channel blockers
    6) Disopyramide
    7) Haloperidol
    8) Macrolides
    9) Reference: (Hessler, 2002)
    c) HYPERTENSION - Some drugs/toxins can produce hypertension, along with hemodynamic instability or tachydysrhythmias. Potential agents may include the following:
    1) Antimigraine drugs (sumatriptan)
    2) Cardiac glycosides
    3) Stimulants
    4) Sympathomimetics
    5) Reference: (Hessler, 2002)
    4) ALTERATIONS IN RESPIRATORY RATE
    a) Any unexplained increase or decrease in respiratory rate may be an indicator of a toxic ingestion that can also produce hemodynamic instability or tachydysrhythmias. Potential agents may include the following:
    1) Antidepressants
    2) Baclofen
    3) Disopyramide
    4) Haloperidol
    5) Detura species (Jimson weed and Moonflower)
    6) Phenothiazine
    7) Reference: (Hessler, 2002)
    0.2.5) CARDIOVASCULAR
    A) WITH POISONING/EXPOSURE
    1) Supraventricular and ventricular tachycardias may develop after acute exposure.
    0.2.12) FLUID-ELECTROLYTE
    A) WITH POISONING/EXPOSURE
    1) Electrolyte abnormalities (eg, hypokalemia, hypomagnesemia, hypocalcemia) can be risk factors for drug-induced QT prolongation.

Laboratory Monitoring

    A) Obtain a baseline ECG and repeat as indicated. Institute continuous cardiac monitoring.
    B) Monitor vital signs including blood pressure frequently.
    C) Obtain a baseline CBC, electrolytes including potassium, calcium and magnesium levels, and ABGs in symptomatic patients.
    D) Monitor renal and hepatic function as indicated.
    E) Obtain drug levels if toxic agent is known or suspected.

Treatment Overview

    0.4.2) ORAL/PARENTERAL EXPOSURE
    A) Gastric lavage may be beneficial if performed soon after a potentially life threatening ingestion.
    B) Serials ECGs are indicated along with continuous cardiac monitoring. Monitor vital signs frequently. Monitor serum electrolytes including calcium, magnesium and potassium. Evaluate for other causes of tachycardia including dehydration, blood loss, hypoxia and fever. Obtain baseline renal and hepatic function tests; repeat as necessary.
    C) Hypotension may also occur in this setting, the primary treatment is to correct the underlying dysrhythmia. Fluids and vasopressors may be required temporarily to manage hypotension.
    1) HYPOTENSION: Infuse 10 to 20 mL/kg isotonic fluid. If hypotension persists, administer dopamine (5 to 20 mcg/kg/min) or norepinephrine (ADULT: begin infusion at 0.5 to 1 mcg/min; CHILD: begin infusion at 0.1 mcg/kg/min); titrate to desired response.
    D) Establish immediate intravenous access. For mild/moderate dysrhythmias, pharmacologic intervention may not be necessary (ie, sinus tachycardia). However, immediate and potentially aggressive supportive care is required in symptomatic patients and in patients with dysrhythmias likely to cause hemodynamic instability.
    E) SEIZURES (eg, sympathomimetic, tricyclic antidepressant exposure) - If present, treat aggressively as acidosis may worsen cardiovascular toxicity.
    1) SEIZURES: Administer a benzodiazepine; DIAZEPAM (ADULT: 5 to 10 mg IV initially; repeat every 5 to 20 minutes as needed. CHILD: 0.1 to 0.5 mg/kg IV over 2 to 5 minutes; up to a maximum of 10 mg/dose. May repeat dose every 5 to 10 minutes as needed) or LORAZEPAM (ADULT: 2 to 4 mg IV initially; repeat every 5 to 10 minutes as needed, if seizures persist. CHILD: 0.05 to 0.1 mg/kg IV over 2 to 5 minutes, up to a maximum of 4 mg/dose; may repeat in 5 to 15 minutes as needed, if seizures continue).
    a) Consider phenobarbital or propofol if seizures recur after diazepam 30 mg (adults) or 10 mg (children greater than 5 years).
    b) Monitor for hypotension, dysrhythmias, respiratory depression, and need for endotracheal intubation. Evaluate for hypoglycemia, electrolyte disturbances, and hypoxia.
    2) REFRACTORY SEIZURES: Consider continuous infusion of midazolam, propofol, and/or pentobarbital. Hyperthermia, lactic acidosis and muscle destruction may necessitate use of neuromuscular blocking agents with continuous EEG monitoring.
    F) CNS DEPRESSION and/or RESPIRATORY DEPRESSION: Early intubation is advised in patients with significant mental status changes or respiratory depression/insufficiency to protect the airway and provide adequate oxygenation and ventilation.
    G) VENTRICULAR DYSRHYTHMIAS
    1) LIDOCAINE: ADULT: LOADING DOSE: 1 to 1.5 milligram/kilogram via IV push. For refractory VT/VF an additional bolus of 0.5 to 0.75 milligram/kilogram can be given at 5 to 10 minute intervals to a maximum dose of 3 milligrams/kilogram. Only bolus therapy is recommended during cardiac arrest. INFUSION: Once circulation is restored begin an infusion of 1 to 4 mg/min. If dysrhythmias recur during infusion repeat 0.5 milligram/kilogram bolus and increase the infusion rate incrementally (maximal infusion rate is 4 milligrams/minute). PEDIATRIC: LOADING DOSE: 1 milligram/kilogram initial bolus IV/IO; followed by a continuous infusion of 20 to 50 micrograms/kilogram/minute. Monitor ECG continuously.

Range Of Toxicity

    A) Because of the numerous agents that may be associated with toxin-induced tachyarrhythmias, a minimum toxic dose cannot be delineated. Coadministration of multiple agents and potential risk factors (eg, electrolyte imbalances {ie, hypokalemia, hypocalcemia, hypomagnesemia}, cardiovascular disease, female gender, etc) may produce refractory symptoms or potentiate the clinical effects observed.
    B) Refer to a specific management if a toxin is known or suspected to determine potential toxicity.

Clinical Effects

Summary Of Exposure

    A) WITH POISONING/EXPOSURE
    1) Both supraventricular and ventricular tachydysrhythmias may occur in poisoning and often complicate the treatment of a patient with a toxic ingestion. Sinus tachycardia is the most common rhythm seen in the poisoned patient and may result from toxic effects associated with fever, stress, hypovolemia, catecholamine excess, or from the direct effects of the toxin on the sinoatrial node. Supraventricular tachycardias occur frequently in poisoned patients and the most common agents are medications or toxins with anticholinergic activity, antiarrrhythmics, and sympathomimetic drugs.
    2) Endocrine, hepatic, renal, and nervous system dysfunction might also arise secondary to poisoning from a toxin or drug that causes tachydysrhythmias. Electrolyte disturbances such as hypocalcemia, hypokalemia and hypomagnesemia often precede a cardiovascular event during poisoning.

Vital Signs

    3.3.1) SUMMARY
    A) WITH POISONING/EXPOSURE
    1) HYPERTHERMIA
    a) The presence of fever, in particular a temperature of 106 degrees F (of >41.1 degrees C), along with hemodynamic compromise or tachydysrhythmias may be an indication of a toxic ingestion. The following is a list of potential agents that may be associated with these clinical findings.
    1) Anticholinergics
    2) Antihistamines
    3) Antidepressants, tricyclic
    4) Ethanol
    5) Lithium
    6) Phenothiazine
    7) Detura species (Jimson weed and Moonflower)
    8) Stimulants
    9) Sympathomimetics
    10) Reference: (Hessler, 2002)
    2) HYPOTHERMIA
    a) Hypothermia, along with tachydysrhythmias or hemodynamic compromise, may occur with these agents: macrolide antibiotics, antidepressants and phenothiazines (Hessler, 2002).
    3) ALTERATIONS IN BLOOD PRESSURE
    a) Relatively rapid changes in blood pressure (ie, initial hypertension followed by hypotension) can occur following a toxic ingestion that also produces hemodynamic compromise or tachydysrhythmias. Some possible agents include: antihistamines, SSRIs, bretylium, jimson weed, and phenothiazines (Hessler, 2002).
    b) HYPOTENSION - Some drugs/toxins can produce a decrease in blood pressure, along with hemodynamic instability or tachydysrhythmias. Potential agents may include the following:
    1) Acotinium
    2) Antidepressants
    3) Antimalarials
    4) Arsenic
    5) Calcium channel blockers
    6) Disopyramide
    7) Haloperidol
    8) Macrolides
    9) Reference: (Hessler, 2002)
    c) HYPERTENSION - Some drugs/toxins can produce hypertension, along with hemodynamic instability or tachydysrhythmias. Potential agents may include the following:
    1) Antimigraine drugs (sumatriptan)
    2) Cardiac glycosides
    3) Stimulants
    4) Sympathomimetics
    5) Reference: (Hessler, 2002)
    4) ALTERATIONS IN RESPIRATORY RATE
    a) Any unexplained increase or decrease in respiratory rate may be an indicator of a toxic ingestion that can also produce hemodynamic instability or tachydysrhythmias. Potential agents may include the following:
    1) Antidepressants
    2) Baclofen
    3) Disopyramide
    4) Haloperidol
    5) Detura species (Jimson weed and Moonflower)
    6) Phenothiazine
    7) Reference: (Hessler, 2002)

Heent

    3.4.3) EYES
    A) WITH POISONING/EXPOSURE
    1) Lacrimation and miosis suggest cholinergic poisoning. Mydriasis and visual hallucinations suggest anticholinergic poisoning. Nystagmus can develop with a variety of sedative agents and anticonvulsants. Visual disturbances can develop after quinine intoxication. These agent can cause hemodynamic compromise including tachydysrhythmias (Hessler, 2002).
    3.4.4) EARS
    A) WITH POISONING/EXPOSURE
    1) Tinnitus has been reported in agents (eg, salicylates) that can also cause hemodynamic instability including tachydysrhythmias (Hessler, 2002).

Cardiovascular

    3.5.1) SUMMARY
    A) WITH POISONING/EXPOSURE
    1) Supraventricular and ventricular tachycardias may develop after acute exposure.
    3.5.2) CLINICAL EFFECTS
    A) SINUS TACHYCARDIA
    1) WITH POISONING/EXPOSURE
    a) SINUS TACHYCARDIA is an increase in sinus rate to more than 100 beats per minute caused by drugs and toxins such as stimulants (eg, caffeine, alcohol, nicotine); certain medications (eg, salbutamol, aminophylline, atropine, catecholamines); and some recreational drugs (eg, amphetamines, cocaine, "ecstasy", cannabis). Sinus tachycardia results from physiological influences on individual pacemaker cells, and from an anatomical shift in the site of atrial depolarization superiorly within the sinus node (Anon, 2003).
    B) ATRIAL TACHYCARDIA
    1) WITH POISONING/EXPOSURE
    a) Atrial tachycardia is caused by sympathomimetics, anticholinergic drugs, and toxins. Digitalis is one of the most common drugs associated with the induction of atrial tachycardia, which is usually characterized by the development of a rapid atrial rate with atrioventricular (AV) block; hence the ventricular rate may not be excessively rapid. Serum digoxin levels are helpful for diagnosis (Anon, 2003).
    C) ATRIAL FIBRILLATION
    1) WITH POISONING/EXPOSURE
    a) ATRIAL FIBRILLATION is the most common sustained dysrhythmia of clinical significance that is characterized by chaotic, rapid, discontinuous atrial depolarizations, resulting in rapid oscillations that are recorded as irregular formed F waves (in contrast to uniform P waves associated with normal sinus rhythm). Atrial fibrillation can be caused by thyrotoxicosis and ethanol intoxication (Kasliwal et al, 2003).
    D) ATRIAL FLUTTER
    1) WITH POISONING/EXPOSURE
    a) Atrial flutter is somewhat similar to atrial fibrillation, characterized by a rapid atrial rate (approximately 300 beats per minute), but the atrial rhythm is more regular and organized. There may also be a corresponding increase in the ventricular rate (Sweetman, 2004).
    E) AV JUNCTIONAL (NODAL) TACHYCARDIA
    1) WITH POISONING/EXPOSURE
    a) FOCAL JUNCTIONAL TACHYCARDIA
    1) Focal junctional tachycardia is described as an abnormally rapid discharge from the junctional region (AV node or His bundle) that results in varying ECG manifestations because the dysrhythmia requires participation of neither the atrium nor the ventricle for its propagation. It is an uncommon phenomenon, which usually presents in young adulthood. The patient may have a structurally normal heart or have congenital abnormalities often associated with an atrial or ventricular septal defect. This dysrhythmia is usually exercise or stress related. Usually patients are quite symptomatic, and if left untreated, may develop heart failure, particularly if tachycardia is recurring (Anon, 2003).
    b) NONPAROXYSMAL JUNCTIONAL TACHYCARDIA
    1) Nonparoxysmal junctional tachycardia is a benign dysrhythmia characterized by a narrow complex tachycardia (rates of 70 to 120 beats per minute). This rhythm maybe a marker of a serious underlying condition such as digitalis toxicity (Anon, 2003).
    F) VENTRICULAR TACHYCARDIA
    1) WITH POISONING/EXPOSURE
    a) Ventricular tachycardia is a re-entry arrhythmia, which arises in the ventricles below the atrioventricular node (heart rate is about 120 to 250 beats per minute). Ventricular tachycardias can be caused by sympathomimetics, membrane depressant drugs and toxins, antidysrhythmics, diuretic use, anticholinergics, metal salts, cyclic antidepressants, botanicals and plants, cardiac glycosides (ie, digoxin toxicity), hydrocarbons and solvents, phosphodiesterase inhibitors, and sedative hypnotic agents (Hessler, 2002).
    G) TORSADES DE POINTES
    1) WITH POISONING/EXPOSURE
    a) Torsades de pointes is a unique type of polymorphic ventricular tachycardia in which the ECG resembles a sinusoidal wave of increasing magnitude, undulating above and below the baseline. Torsades is potentially a life-threatening ventricular dysrhythmia that occurs in the setting of a lengthened QT interval, reflecting delayed ventricular repolarization and prolongation of the action potential duration. It can be self-limiting, but can persist, and deteriorate to ventricular fibrillation, and lead to sudden death if not treated (Hessler, 2002; Tamargo, 2000).
    1) The clinical presentation is a prolonged QT interval and the emergence of other T or U wave abnormalities on ECG. The tachycardia is often non-sustained, but may persist enough to cause syncope or it can progress to ventricular fibrillation (Sweetman, 2004; Tamargo, 2000).
    2) Metabolic and electrolyte abnormalities, particularly hypocalcemia, hypomagnesemia, and hypokalemia, may interfere with the ion channel currents and may cause torsades de pointes. However, the most common cause is drug toxicity. Any drug (ie, cardiac or non-cardiac agents) that causes QT prolongation may cause torsades de pointes (Belardinelli et al, 2003).
    3) DRUGS THAT PRODUCE QT PROLONGATION
    1) ANTIARRHYTHMICS
    a) Adenosine
    b) Amiodarone
    c) Azimilide
    d) Dofetilide
    e) Ibutilide
    f) Quinidine
    g) Sotalol
    2) ANTIDEPRESSANTS, TRICYCLIC
    3) ANTIHISTAMINES
    a) Astemizole
    b) Terfenadine
    4) ANTIBIOTICS
    a) Erythromycin
    b) Clarithromycin
    5) IMMUNOSUPPRESSANTS
    6) CALCIUM CHANNEL BLOCKERS
    a) Diltiazem
    b) Verapamil
    c) Mibefradil
    d) Bepridil
    7) PSYCHOTHERAPEUTICS
    a) Droperidol
    b) Fluoxetine
    c) Sertindole
    8) MISCELLANEOUS
    a) Cisapride
    b) Cocaine (recreational use) - likely caused by potassium channel blockade
    c) Sodium pentobarbital
    d) Ketanserin
    e) Vasopressin
    9) REFERENCE: (Belardinelli et al, 2003; Bauman & DiDomenico , 2002)
    4) RISK FACTORS
    a) Potential risk factors have been identified with non-cardiac drugs that can lead to QT prolongation. Although QT prolongation with non-cardiac drugs is a rare occurrence, the list below may help to identify patients at risk for developing this condition(Zeltser et al, 2003 ):
    1) RISK FACTORS
    a) Female Gender - the most common risk factor for producing torsades de pointes
    b) Heart Disease
    c) Hypokalemia
    d) Drug Interactions - treatment with a medication that impairs the metabolism of a QT-prolonging drug or concomitant use of two QT prolonging therapies
    e) Excessive drug dose
    f) Long QT - a familial history of long QT syndrome
    H) DEAD - SUDDEN DEATH
    1) WITH POISONING/EXPOSURE
    a) Psychotropic drugs are one class of drugs that have been associated with QT prolongation. Overall, the development of clinically significant QT prolongation is relatively uncommon, and the onset of torsades is even more rare. However, within this class, the drugs most commonly associated with QT prolongation and the risk of sudden cardiac death (in some settings) includes tricyclic antidepressants (eg, imipramine and amitriptyline), tetracyclic antidepressants, (eg, maprotiline), phenothiazine derivative antipsychotics (especially thioridazine), and potentially some new atypical antipsychotics (eg, sertindole). In addition, agents used for movement disorders, including neuroleptics, antiepileptics, and antiparkinsonian agents have been associated with QT prolongation (Witchel et al, 2003).

Respiratory

    3.6.2) CLINICAL EFFECTS
    A) RESPIRATORY FAILURE
    1) WITH POISONING/EXPOSURE
    a) Respiratory depression or respiratory failure can occur following overdose of various drugs and/or chemicals; however, in the presence of cardiovascular disturbances (ie, QT prolongation, atrial fibrillation (AF), ventricular fibrillation (VF), or junctional tachycardia) the following agents may be considered.
    1) Cholinomimetic agents (eg, organophosphates, carbamate insecticides, physostigmine, bethanecol, pilocarpine, neostigmine, pyridostgmine, nicotine)
    2) Opiates (AF)
    3) Fluoride (QT prolonged; VF)
    4) Reference (Benowitz & Goldschlager, 1998)

Neurologic

    3.7.2) CLINICAL EFFECTS
    A) NEUROLOGICAL FINDING
    1) WITH POISONING/EXPOSURE
    a) Alterations in consciousness, such as depressed mental status, confusion or agitation/anxiety can be associated with agents that can produce hemodynamic instability or tachydysrhythmias (eg, cardiac glycosides, opiates, cocaine, scorpions) (Hessler, 2002; Benowitz & Goldschlager, 1998).
    B) SEIZURE
    1) WITH POISONING/EXPOSURE
    a) Seizures can occur following overdose of various drugs and/or chemicals; however, in the presence of cardiovascular disturbances (ie, QT prolongation, atrial or junctional tachycardia) the following agents may be considered.
    1) Amphetamines (potential dysrhythmias)
    2) Cocaine (dysrhythmias)
    3) Lithium (ventricular ectopy; ST-T abnormalities)
    4) Opiates (atrial fibrillation)
    5) Scorpions (QT prolonged; atrial and/or ventricular arrhythmias)
    6) Reference (Benowitz & Goldschlager, 1998)

Gastrointestinal

    3.8.2) CLINICAL EFFECTS
    A) NAUSEA AND VOMITING
    1) WITH POISONING/EXPOSURE
    a) Nausea and vomiting are frequently observed following overdose of various drugs and/or chemicals; however, in the presence of cardiovascular disturbances (ie, QT prolongation, atrial or junctional tachycardia) the following agents may be considered.
    1) Arsenic (may also include abdominal pain and diarrhea, tachycardia and QT prolongation)
    2) Digitalis (atrial or junctional tachycardia)
    3) Fluoride (may also include diarrhea, QT prolongation, hypocalcemia, hypomagnesemia)
    4) Iron (may include diarrhea and GI bleeding, acidosis, sinus tachycardia)
    5) Mercury (organic) (may include metallic taste, diarrhea)
    6) Scorpion (usually only includes abdominal pain and rigidity, agitation, sinus tachycardia)
    7) Reference (Benowitz & Goldschlager, 1998)

Dermatologic

    3.14.2) CLINICAL EFFECTS
    A) DERMATOLOGICAL FINDING
    1) WITH POISONING/EXPOSURE
    a) The presence of dry mucous membranes and flushed skin suggests anticholinergic poisoning. Excessive salivation suggests cholinergic poisoning(Hessler, 2002). In the presence of cardiovascular disturbances (ie, QT prolongation, atrial or junctional tachycardia) the following agents may be considered.
    1) Any agents that may produce muscarinic or nicotinic effects
    2) Organophosphates
    3) Sympathomimetics
    4) Reference (Hessler, 2002)

Endocrine

    3.16.2) CLINICAL EFFECTS
    A) HYPOTHYROIDISM
    1) WITH POISONING/EXPOSURE
    a) Prolongation of the QT interval with rare cases of torsades de pointes have been reported in patients with severe hypothyroidism (Tamargo, 2000). Amiodarone has been widely used for the treatment of ventricular dysrhythmias and supraventricular tachycardias and its use has been associated with the frequent occurrence of thyroid dysfunction as an adverse event.

Laboratory Monitoring

Monitoring Parameters Levels

    4.1.1) SUMMARY
    A) Obtain a baseline ECG and repeat as indicated. Institute continuous cardiac monitoring.
    B) Monitor vital signs including blood pressure frequently.
    C) Obtain a baseline CBC, electrolytes including potassium, calcium and magnesium levels, and ABGs in symptomatic patients.
    D) Monitor renal and hepatic function as indicated.
    E) Obtain drug levels if toxic agent is known or suspected.
    4.1.2) SERUM/BLOOD
    A) Obtain a baseline CBC, electrolytes including potassium, calcium and magnesium levels. Obtain an ABG in patients with respiratory depression or acidosis.
    4.1.4) OTHER
    A) OTHER
    1) ECG
    a) Obtain baseline ECG and repeat as indicated. Institute continuous cardiac monitoring.
    2) ARTERIAL BLOOD GASES
    a) ABGs are indicated if dysrhythmias are associated with poor perfusion, acidosis or respiratory depression. Repeat as necessary.

Radiographic Studies

    A) CHEST RADIOGRAPHY
    1) Chest x-ray may be indicated to rule out potential non-toxic causes of dysrhythmias (ie, pneumothorax, pulmonary infection).

Treatment

Life Support

    A) Support respiratory and cardiovascular function.

Monitoring

    A) Obtain a baseline ECG and repeat as indicated. Institute continuous cardiac monitoring.
    B) Monitor vital signs including blood pressure frequently.
    C) Obtain a baseline CBC, electrolytes including potassium, calcium and magnesium levels, and ABGs in symptomatic patients.
    D) Monitor renal and hepatic function as indicated.
    E) Obtain drug levels if toxic agent is known or suspected.

Oral Exposure

    6.5.1) PREVENTION OF ABSORPTION/PREHOSPITAL
    A) SUMMARY
    1) Prehospital care should include IV access, cardiac monitoring, and immediate transport to a healthcare facility.
    B) ACTIVATED CHARCOAL
    1) PREHOSPITAL ACTIVATED CHARCOAL ADMINISTRATION
    a) Consider prehospital administration of activated charcoal as an aqueous slurry in patients with a potentially toxic ingestion who are awake and able to protect their airway. Activated charcoal is most effective when administered within one hour of ingestion. Administration in the prehospital setting has the potential to significantly decrease the time from toxin ingestion to activated charcoal administration, although it has not been shown to affect outcome (Alaspaa et al, 2005; Thakore & Murphy, 2002; Spiller & Rogers, 2002).
    1) In patients who are at risk for the abrupt onset of seizures or mental status depression, activated charcoal should not be administered in the prehospital setting, due to the risk of aspiration in the event of spontaneous emesis.
    2) The addition of flavoring agents (cola drinks, chocolate milk, cherry syrup) to activated charcoal improves the palatability for children and may facilitate successful administration (Guenther Skokan et al, 2001; Dagnone et al, 2002).
    2) CHARCOAL DOSE
    a) Use a minimum of 240 milliliters of water per 30 grams charcoal (FDA, 1985). Optimum dose not established; usual dose is 25 to 100 grams in adults and adolescents; 25 to 50 grams in children aged 1 to 12 years (or 0.5 to 1 gram/kilogram body weight) ; and 0.5 to 1 gram/kilogram in infants up to 1 year old (Chyka et al, 2005).
    1) Routine use of a cathartic with activated charcoal is NOT recommended as there is no evidence that cathartics reduce drug absorption and cathartics are known to cause adverse effects such as nausea, vomiting, abdominal cramps, electrolyte imbalances and occasionally hypotension (None Listed, 2004).
    b) ADVERSE EFFECTS/CONTRAINDICATIONS
    1) Complications: emesis, aspiration (Chyka et al, 2005). Aspiration may be complicated by acute respiratory failure, ARDS, bronchiolitis obliterans or chronic lung disease (Golej et al, 2001; Graff et al, 2002; Pollack et al, 1981; Harris & Filandrinos, 1993; Elliot et al, 1989; Rau et al, 1988; Golej et al, 2001; Graff et al, 2002). Refer to the ACTIVATED CHARCOAL/TREATMENT management for further information.
    2) Contraindications: unprotected airway (increases risk/severity of aspiration) , nonfunctioning gastrointestinal tract, uncontrolled vomiting, and ingestion of most hydrocarbons (Chyka et al, 2005).
    6.5.2) PREVENTION OF ABSORPTION
    A) ACTIVATED CHARCOAL
    1) CHARCOAL ADMINISTRATION
    a) Consider administration of activated charcoal after a potentially toxic ingestion (Chyka et al, 2005). Administer charcoal as an aqueous slurry; most effective when administered within one hour of ingestion.
    B) CHARCOAL DOSE
    1) Use a minimum of 240 milliliters of water per 30 grams charcoal (FDA, 1985). Optimum dose not established; usual dose is 25 to 100 grams in adults and adolescents; 25 to 50 grams in children aged 1 to 12 years (or 0.5 to 1 gram/kilogram body weight) ; and 0.5 to 1 gram/kilogram in infants up to 1 year old (Chyka et al, 2005).
    a) Routine use of a cathartic with activated charcoal is NOT recommended as there is no evidence that cathartics reduce drug absorption and cathartics are known to cause adverse effects such as nausea, vomiting, abdominal cramps, electrolyte imbalances and occasionally hypotension (None Listed, 2004).
    2) ADVERSE EFFECTS/CONTRAINDICATIONS
    a) Complications: emesis, aspiration (Chyka et al, 2005). Aspiration may be complicated by acute respiratory failure, ARDS, bronchiolitis obliterans or chronic lung disease (Golej et al, 2001; Graff et al, 2002; Pollack et al, 1981; Harris & Filandrinos, 1993; Elliot et al, 1989; Rau et al, 1988; Golej et al, 2001; Graff et al, 2002). Refer to the ACTIVATED CHARCOAL/TREATMENT management for further information.
    b) Contraindications: unprotected airway (increases risk/severity of aspiration) , nonfunctioning gastrointestinal tract, uncontrolled vomiting, and ingestion of most hydrocarbons (Chyka et al, 2005).
    C) GASTRIC LAVAGE
    1) Gastric lavage is indicated if it can be performed soon after ingestion, and a significant exposure is suspected.
    2) INDICATIONS: Consider gastric lavage with a large-bore orogastric tube (ADULT: 36 to 40 French or 30 English gauge tube {external diameter 12 to 13.3 mm}; CHILD: 24 to 28 French {diameter 7.8 to 9.3 mm}) after a potentially life threatening ingestion if it can be performed soon after ingestion (generally within 60 minutes).
    a) Consider lavage more than 60 minutes after ingestion of sustained-release formulations and substances known to form bezoars or concretions.
    3) PRECAUTIONS:
    a) SEIZURE CONTROL: Is mandatory prior to gastric lavage.
    b) AIRWAY PROTECTION: Place patients in the head down left lateral decubitus position, with suction available. Patients with depressed mental status should be intubated with a cuffed endotracheal tube prior to lavage.
    4) LAVAGE FLUID:
    a) Use small aliquots of liquid. Lavage with 200 to 300 milliliters warm tap water (preferably 38 degrees Celsius) or saline per wash (in older children or adults) and 10 milliliters/kilogram body weight of normal saline in young children(Vale et al, 2004) and repeat until lavage return is clear.
    b) The volume of lavage return should approximate amount of fluid given to avoid fluid-electrolyte imbalance.
    c) CAUTION: Water should be avoided in young children because of the risk of electrolyte imbalance and water intoxication. Warm fluids avoid the risk of hypothermia in very young children and the elderly.
    5) COMPLICATIONS:
    a) Complications of gastric lavage have included: aspiration pneumonia, hypoxia, hypercapnia, mechanical injury to the throat, esophagus, or stomach, fluid and electrolyte imbalance (Vale, 1997). Combative patients may be at greater risk for complications (Caravati et al, 2001).
    b) Gastric lavage can cause significant morbidity; it should NOT be performed routinely in all poisoned patients (Vale, 1997).
    6) CONTRAINDICATIONS:
    a) Loss of airway protective reflexes or decreased level of consciousness if patient is not intubated, following ingestion of corrosive substances, hydrocarbons (high aspiration potential), patients at risk of hemorrhage or gastrointestinal perforation, or trivial or non-toxic ingestion.
    6.5.3) TREATMENT
    A) SUPPORT
    1) Treatment should be initiated as clinically indicated. The causative agent may often be unknown at the start of therapy.
    2) Correct any underlying electrolyte or metabolic disturbances, hypoxia, and treat any concomitant condition (eg, seizures).
    3) If the agent is known or suspected, refer to the specific topic for further information.
    B) MONITORING OF PATIENT
    1) Serial ECGs should be obtained, along with continuous cardiac monitoring. Supportive care and removal of the suspected agent may be the only treatment required in some cases.
    a) SINUS TACHYCARDIA
    1) Identify the cause and eliminate or treat it. Usually, supportive care and correction of underlying metabolic or hemodynamic abnormalities are recommended. The tachycardia will resolve as the toxin is metabolized or removed from the body (Anon, 2003; Hessler, 2002).
    2) In a situation where there is an extremely fast tachycardia (greater than 150 beats/minute), or tachycardia associated with agitation, as can occur with a stimulant or sympathomimetic acute exposure, treatment with benzodiazepines will usually control the tachycardia effectively (Hessler, 2002).
    b) ECTOPIC ATRIAL TACHYCARDIA
    1) Monitor patient, no treatment may be required. If a 2:1 AV conduction ratio is present, suspect digitalis toxicity (treatment is digitalis immune Fab). If hemodynamic insufficiency is present and digitalis toxicity is ruled out, treatment may include: beta-blockade (short acting agent such as esmolol preferred), sotalol, amiodarone, or calcium channel blockade (short acting agent such as diltiazem preferred) (Benowitz & Goldschlager, 1998).
    c) JUNCTIONAL TACHYCARDIA
    1) If rate is rapid (and no variation in rate occurs with respiration or exercise), beta-blockade, pace termination, or direct current cardioversion may be appropriate. Physostigmine should be avoided if JT is associated with membrane-depressant drug overdose (Benowitz & Goldschlager, 1998). Focal junctional tachycardia can be slowed or terminated with IV flecainide (Anon, 2003).
    C) ATRIAL FIBRILLATION AND FLUTTER
    1) ATRIAL FLUTTER: If the QRS rhythm is regular and slow (less than 100 bpm), AV block may be due to digitalis toxicity and/or beta and calcium entry blocker overdose. Treatment may include the following:
    1) Direct cardioversion (low energy levels are usually sufficient);
    2) pace termination;
    3) IV esmolol, diltiazem or metoprolol will slow ventricular rate;
    4) digitalis and quinidine or procainamide, or IV ibutilide for pharmacologic conversion, although this is not generally necessary in the setting of an overdose
    2) ATRIAL FIBRILLATION: Treatment may include: intravenous digitalis, diltiazem, verapamil, esmolol and/or metoprolol or amiodarone to slow ventricular response, if necessary. Short acting titratable agents are generally preferred if atrial fibrillation develops in the setting of drug toxicity. Direct current cardioversion may be indicated if the patient is hemodynamically unstable (Kasliwal et al, 2003; Benowitz & Goldschlager, 1998). Anticoagulation may also be necessary to prevent thromboembolic episodes in the setting of long standing atrial fibrillation (Sweetman, 2004).
    D) VENTRICULAR ARRHYTHMIA
    1) Institute continuous cardiac monitoring, obtain an ECG, and administer oxygen. Evaluate for hypoxia, acidosis, and electrolyte disorders. In the more stable patient, intravenous drug therapy (lidocaine, amiodarone) may be employed for acute termination of the tachycardia. Unstable patients require cardioversion(Sweetman, 2004; Haddad et al, 1998). Depending on the toxin involved, several agents may be initially useful (ie, sodium bicarbonate, magnesium, lidocaine, amiodarone) to treat dysrhythmias. The list below is a brief example of agents that can produce VT and possible drug therapies to use. (If an agent is known or suspected, please refer to that topic.)
    1) POSSIBLE AGENTS TO TREAT VT
    a) Sympathomimetic overdose: Sedate with benzodiazepines, beta-blockers may be indicated
    b) Digitalis overdose: Digitalis antibodies
    c) Quinidine-like agent overdose: Magnesium and isoproterenol for polymorphous VT with a long QT interval
    d) Tricyclic antidepressant (or other membrane-depressant agents) overdose: Sodium bicarbonate is first line, if unresponsive use lidocaine or amiodarone
    2) MAGNESIUM SULFATE
    a) Adult Dose: Administer 1 to 2 grams (8 to 16 mEq) mixed in 50 to 100 milliliters D5W intravenously over 5 minutes. Pediatric Dose: 25 to 50 milligrams/kilogram diluted to 10 milligrams/milliliter for intravenous infusion over 5 to 15 minutes.
    3) LIDOCAINE
    a) VENTRICULAR DYSRHYTHMIAS SUMMARY
    1) Obtain an ECG, institute continuous cardiac monitoring and administer oxygen. Evaluate for hypoxia, acidosis, and electrolyte disorders (particularly hypokalemia, hypocalcemia, and hypomagnesemia). Lidocaine and amiodarone are generally first line agents for stable monomorphic ventricular tachycardia, particularly in patients with underlying impaired cardiac function. Amiodarone should be used with caution if a substance that prolongs the QT interval and/or causes torsades de pointes is involved in the overdose. Unstable rhythms require immediate cardioversion.
    b) LIDOCAINE/INDICATIONS
    1) Ventricular tachycardia or ventricular fibrillation (Prod Info Lidocaine HCl intravenous injection solution, 2006; Neumar et al, 2010; Vanden Hoek et al, 2010).
    c) LIDOCAINE/DOSE
    1) ADULT: 1 to 1.5 milligrams/kilogram via intravenous push. For refractory VT/VF an additional bolus of 0.5 to 0.75 milligram/kilogram can be given at 5 to 10 minute intervals to a maximum dose of 3 milligrams/kilogram (Neumar et al, 2010). Only bolus therapy is recommended during cardiac arrest.
    a) Once circulation has been restored begin a maintenance infusion of 1 to 4 milligrams per minute. If dysrhythmias recur during infusion repeat 0.5 milligram/kilogram bolus and increase the infusion rate incrementally (maximal infusion rate is 4 milligrams/minute) (Neumar et al, 2010).
    2) CHILD: 1 milligram/kilogram initial bolus IV/IO; followed by a continuous infusion of 20 to 50 micrograms/kilogram/minute (de Caen et al, 2015).
    d) LIDOCAINE/MAJOR ADVERSE REACTIONS
    1) Paresthesias; muscle twitching; confusion; slurred speech; seizures; respiratory depression or arrest; bradycardia; coma. May cause significant AV block or worsen pre-existing block. Prophylactic pacemaker may be required in the face of bifascicular, second degree, or third degree heart block (Prod Info Lidocaine HCl intravenous injection solution, 2006; Neumar et al, 2010).
    e) LIDOCAINE/MONITORING PARAMETERS
    1) Monitor ECG continuously; plasma concentrations as indicated (Prod Info Lidocaine HCl intravenous injection solution, 2006).
    4) SODIUM BICARBONATE
    a) If the QRS or QT interval is prolonged, the dysrhythmia should be presumed to be secondary to sodium channel blockade, and sodium bicarbonate should be administered (Hessler, 2002).
    b) Sodium bicarbonate may be useful in the treatment of QRS widening and ventricular dysrhythmias associated with various agents (eg, cocaine). A reasonable starting dose is 1 to 2 mEq/kg repeated, as needed. Monitor arterial blood gases, target pH 7.45 to 7.55.
    E) TORSADES DE POINTES
    1) Treatment begins with the recognition and immediate withdrawal of any potentially offending drug or toxin and the correction of any known risk factors. The goal of therapy is to shorten the action potential duration (APD) prolongation, reduce QT dispersion and suppress early after depolarization (EADs) (Winters et al, 1997).
    2) SUMMARY
    a) Withdraw the causative agent. Hemodynamically unstable patients with Torsades de pointes (TdP) require electrical cardioversion. Emergent treatment with magnesium (first-line agent) or atrial overdrive pacing is indicated. Detect and correct underlying electrolyte abnormalities (ie, hypomagnesemia, hypokalemia, hypocalcemia). Correct hypoxia, if present (Drew et al, 2010; Neumar et al, 2010; Keren et al, 1981; Smith & Gallagher, 1980).
    b) Polymorphic VT associated with acquired long QT syndrome may be treated with IV magnesium. Overdrive pacing or isoproterenol may be successful in terminating TdP, particularly when accompanied by bradycardia or if TdP appears to be precipitated by pauses in rhythm (Neumar et al, 2010). In patients with polymorphic VT with a normal QT interval, magnesium is unlikely to be effective (Link et al, 2015).
    3) MAGNESIUM SULFATE
    a) Magnesium is recommended (first-line agent) for the prevention and treatment of drug-induced torsades de pointes (TdP) even if the serum magnesium concentration is normal. QTc intervals greater than 500 milliseconds after a potential drug overdose may correlate with the development of TdP (Charlton et al, 2010; Drew et al, 2010). ADULT DOSE: No clearly established guidelines exist; an optimal dosing regimen has not been established. Administer 1 to 2 grams diluted in 10 milliliters D5W IV/IO over 15 minutes (Neumar et al, 2010). Followed if needed by a second 2 gram bolus and an infusion of 0.5 to 1 gram (4 to 8 mEq) per hour in patients not responding to the initial bolus or with recurrence of dysrhythmias (American Heart Association, 2005; Perticone et al, 1997). Rate of infusion may be increased if dysrhythmias recur. For persistent refractory dysrhythmias, a continuous infusion of up to 3 to 10 milligrams/minute in adults may be given (Charlton et al, 2010).
    b) PEDIATRIC DOSE: 25 to 50 milligrams/kilogram diluted to 10 milligrams/milliliter for intravenous infusion over 5 to 15 minutes up to 2 g (Charlton et al, 2010).
    c) PRECAUTIONS: Use with caution in patients with renal insufficiency.
    d) MAJOR ADVERSE EFFECTS: High doses may cause hypotension, respiratory depression, and CNS toxicity (Neumar et al, 2010). Toxicity may be observed at magnesium levels of 3.5 to 4.0 mEq/L or greater (Charlton et al, 2010).
    e) MONITORING PARAMETERS: Monitor heart rate and rhythm, blood pressure, respiratory rate, motor strength, deep tendon reflexes, serum magnesium, phosphorus, and calcium concentrations (Prod Info magnesium sulfate heptahydrate IV, IM injection, solution, 2009).
    4) OVERDRIVE PACING
    a) Institute electrical overdrive pacing at a rate of 130 to 150 beats per minute, and decrease as tolerated. Rates of 100 to 120 beats per minute may terminate torsades (American Heart Association, 2005). Pacing can be used to suppress self-limited runs of TdP that may progress to unstable or refractory TdP, or for override refractory, persistent TdP before the potential development of ventricular fibrillation (Charlton et al, 2010). In a case series overdrive pacing was successful in terminating TdP associated with bradycardia and drug-induced QT prolongation (Neumar et al, 2010).
    5) POTASSIUM REPLETION
    a) Potassium supplementation, even if serum potassium is normal, has been recommended by many experts (Charlton et al, 2010; American Heart Association, 2005). Supplementation to supratherapeutic potassium concentrations of 4.5 to 5 mmol/L has been suggested, although there is little evidence to determine the optimal range in dysrhythmia (Drew et al, 2010; Charlton et al, 2010).
    6) ISOPROTERENOL
    a) Isoproterenol has been successful in aborting torsades de pointes that was resistant to magnesium therapy in a patient in whom transvenous overdrive pacing was not an option (Charlton et al, 2010) and has been successfully used to treat torsades de pointes associated with bradycardia and drug induced QT prolongation (Keren et al, 1981; Neumar et al, 2010). Isoproterenol may have a limited role in pharmacologic overdrive pacing in select patients with drug-induced torsades de pointes and acquired long QT syndrome (Charlton et al, 2010; Neumar et al, 2010). Isoproterenol should be avoided in patients with polymorphic VT associated with familial long QT syndrome (Neumar et al, 2010).
    b) DOSE: ADULT: 2 to 10 micrograms/minute via a continuous monitored intravenous infusion; titrate to heart rate and rhythm response (Neumar et al, 2010).
    c) PRECAUTIONS: Correct hypovolemia before using; contraindicated in patients with acute cardiac ischemia (Prod Info Isuprel(TM) intravenous injection, intramuscular injection, subcutaneous injection, intracardiac injection, 2013).
    1) Contraindicated in patients with preexisting dysrhythmias; tachycardia or heart block due to digitalis toxicity; ventricular dysrhythmias that require inotropic therapy; and angina. Use with caution in patients with coronary insufficiency (Prod Info Isuprel(TM) intravenous injection, intramuscular injection, subcutaneous injection, intracardiac injection, 2013).
    d) MAJOR ADVERSE EFFECTS: Tachycardia, cardiac dysrhythmias, palpitations, hypotension or hypertension, nervousness, headache, dizziness, and dyspnea (Prod Info Isuprel(TM) intravenous injection, intramuscular injection, subcutaneous injection, intracardiac injection, 2013).
    e) MONITORING PARAMETERS: Monitor heart rate and rhythm, blood pressure, respirations and central venous pressure to guide volume replacement (Prod Info Isuprel(TM) intravenous injection, intramuscular injection, subcutaneous injection, intracardiac injection, 2013).
    7) OTHER DRUGS
    a) Mexiletine, verapamil, propranolol, and labetalol have also been used to treat TdP, but results have been inconsistent (Khan & Gowda, 2004).
    8) AVOID
    a) Avoid class Ia antidysrhythmics (eg, quinidine, disopyramide, procainamide, aprindine), class Ic (eg, flecainide, encainide, propafenone) and most class III antidysrhythmics (eg, N-acetylprocainamide, sotalol) since they may further prolong the QT interval and have been associated with TdP.
    F) HYPOTENSIVE EPISODE
    1) SUMMARY
    a) Infuse 10 to 20 milliliters/kilogram of isotonic fluid and keep the patient supine. If hypotension persists, administer dopamine or norepinephrine. Consider central venous pressure monitoring to guide further fluid therapy.
    2) DOPAMINE
    a) DOSE: Begin at 5 micrograms per kilogram per minute progressing in 5 micrograms per kilogram per minute increments as needed (Prod Info dopamine hcl, 5% dextrose IV injection, 2004). If hypotension persists, dopamine may need to be discontinued and a more potent vasoconstrictor (eg, norepinephrine) should be considered (Prod Info dopamine hcl, 5% dextrose IV injection, 2004).
    b) CAUTION: If ventricular dysrhythmias occur, decrease rate of administration (Prod Info dopamine hcl, 5% dextrose IV injection, 2004). Extravasation may cause local tissue necrosis, administration through a central venous catheter is preferred (Prod Info dopamine hcl, 5% dextrose IV injection, 2004).
    3) NOREPINEPHRINE
    a) PREPARATION: 4 milligrams (1 amp) added to 1000 milliliters of diluent provides a concentration of 4 micrograms/milliliter of norepinephrine base. Norepinephrine bitartrate should be mixed in dextrose solutions (dextrose 5% in water, dextrose 5% in saline) since dextrose-containing solutions protect against excessive oxidation and subsequent potency loss. Administration in saline alone is not recommended (Prod Info norepinephrine bitartrate injection, 2005).
    b) DOSE
    1) ADULT: Dose range: 0.1 to 0.5 microgram/kilogram/minute (eg, 70 kg adult 7 to 35 mcg/min); titrate to maintain adequate blood pressure (Peberdy et al, 2010).
    2) CHILD: Dose range: 0.1 to 2 micrograms/kilogram/minute; titrate to maintain adequate blood pressure (Kleinman et al, 2010).
    3) CAUTION: Extravasation may cause local tissue ischemia, administration by central venous catheter is advised (Peberdy et al, 2010).
    G) SEIZURE
    1) SUMMARY
    a) Attempt initial control with a benzodiazepine (eg, diazepam, lorazepam). If seizures persist or recur, administer phenobarbital or propofol.
    b) Monitor for respiratory depression, hypotension, and dysrhythmias. Endotracheal intubation should be performed in patients with persistent seizures.
    c) Evaluate for hypoxia, electrolyte disturbances, and hypoglycemia (or, if immediate bedside glucose testing is not available, treat with intravenous dextrose).
    2) DIAZEPAM
    a) ADULT DOSE: Initially 5 to 10 mg IV, OR 0.15 mg/kg IV up to 10 mg per dose up to a rate of 5 mg/minute; may be repeated every 5 to 20 minutes as needed (Brophy et al, 2012; Prod Info diazepam IM, IV injection, 2008; Manno, 2003).
    b) PEDIATRIC DOSE: 0.1 to 0.5 mg/kg IV over 2 to 5 minutes; up to a maximum of 10 mg/dose. May repeat dose every 5 to 10 minutes as needed (Loddenkemper & Goodkin, 2011; Hegenbarth & American Academy of Pediatrics Committee on Drugs, 2008).
    c) Monitor for hypotension, respiratory depression, and the need for endotracheal intubation. Consider a second agent if seizures persist or recur after repeated doses of diazepam .
    3) NO INTRAVENOUS ACCESS
    a) DIAZEPAM may be given rectally or intramuscularly (Manno, 2003). RECTAL DOSE: CHILD: Greater than 12 years: 0.2 mg/kg; 6 to 11 years: 0.3 mg/kg; 2 to 5 years: 0.5 mg/kg (Brophy et al, 2012).
    b) MIDAZOLAM has been used intramuscularly and intranasally, particularly in children when intravenous access has not been established. ADULT DOSE: 0.2 mg/kg IM, up to a maximum dose of 10 mg (Brophy et al, 2012). PEDIATRIC DOSE: INTRAMUSCULAR: 0.2 mg/kg IM, up to a maximum dose of 7 mg (Chamberlain et al, 1997) OR 10 mg IM (weight greater than 40 kg); 5 mg IM (weight 13 to 40 kg); INTRANASAL: 0.2 to 0.5 mg/kg up to a maximum of 10 mg/dose (Loddenkemper & Goodkin, 2011; Brophy et al, 2012). BUCCAL midazolam, 10 mg, has been used in adolescents and older children (5-years-old or more) to control seizures when intravenous access was not established (Scott et al, 1999).
    4) LORAZEPAM
    a) MAXIMUM RATE: The rate of intravenous administration of lorazepam should not exceed 2 mg/min (Brophy et al, 2012; Prod Info lorazepam IM, IV injection, 2008).
    b) ADULT DOSE: 2 to 4 mg IV initially; repeat every 5 to 10 minutes as needed, if seizures persist (Manno, 2003; Brophy et al, 2012).
    c) PEDIATRIC DOSE: 0.05 to 0.1 mg/kg IV over 2 to 5 minutes, up to a maximum of 4 mg/dose; may repeat in 5 to 15 minutes as needed, if seizures continue (Brophy et al, 2012; Loddenkemper & Goodkin, 2011; Hegenbarth & American Academy of Pediatrics Committee on Drugs, 2008; Sreenath et al, 2009; Chin et al, 2008).
    5) PHENOBARBITAL
    a) ADULT LOADING DOSE: 20 mg/kg IV at an infusion rate of 50 to 100 mg/minute IV. An additional 5 to 10 mg/kg dose may be given 10 minutes after loading infusion if seizures persist or recur (Brophy et al, 2012).
    b) Patients receiving high doses will require endotracheal intubation and may require vasopressor support (Brophy et al, 2012).
    c) PEDIATRIC LOADING DOSE: 20 mg/kg may be given as single or divided application (2 mg/kg/minute in children weighing less than 40 kg up to 100 mg/min in children weighing greater than 40 kg). A plasma concentration of about 20 mg/L will be achieved by this dose (Loddenkemper & Goodkin, 2011).
    d) REPEAT PEDIATRIC DOSE: Repeat doses of 5 to 20 mg/kg may be given every 15 to 20 minutes if seizures persist, with cardiorespiratory monitoring (Loddenkemper & Goodkin, 2011).
    e) MONITOR: For hypotension, respiratory depression, and the need for endotracheal intubation (Loddenkemper & Goodkin, 2011; Manno, 2003).
    f) SERUM CONCENTRATION MONITORING: Monitor serum concentrations over the next 12 to 24 hours. Therapeutic serum concentrations of phenobarbital range from 10 to 40 mcg/mL, although the optimal plasma concentration for some individuals may vary outside this range (Hvidberg & Dam, 1976; Choonara & Rane, 1990; AMA Department of Drugs, 1992).
    6) OTHER AGENTS
    a) If seizures persist after phenobarbital, propofol or pentobarbital infusion, or neuromuscular paralysis with general anesthesia (isoflurane) and continuous EEG monitoring should be considered (Manno, 2003). Other anticonvulsants can be considered (eg, valproate sodium, levetiracetam, lacosamide, topiramate) if seizures persist or recur; however, there is very little data regarding their use in toxin induced seizures, controlled trials are not available to define the optimal dosage ranges for these agents in status epilepticus (Brophy et al, 2012):
    1) VALPROATE SODIUM: ADULT DOSE: An initial dose of 20 to 40 mg/kg IV, at a rate of 3 to 6 mg/kg/minute; may give an additional dose of 20 mg/kg 10 minutes after loading infusion. PEDIATRIC DOSE: 1.5 to 3 mg/kg/minute (Brophy et al, 2012).
    2) LEVETIRACETAM: ADULT DOSE: 1000 to 3000 mg IV, at a rate of 2 to 5 mg/kg/min IV. PEDIATRIC DOSE: 20 to 60 mg/kg IV (Brophy et al, 2012; Loddenkemper & Goodkin, 2011).
    3) LACOSAMIDE: ADULT DOSE: 200 to 400 mg IV; 200 mg IV over 15 minutes (Brophy et al, 2012). PEDIATRIC DOSE: In one study, median starting doses of 1.3 mg/kg/day and maintenance doses of 4.7 mg/kg/day were used in children 8 years and older (Loddenkemper & Goodkin, 2011).
    4) TOPIRAMATE: ADULT DOSE: 200 to 400 mg nasogastric/orally OR 300 to 1600 mg/day orally divided in 2 to 4 times daily (Brophy et al, 2012).
    7) RECURRING SEIZURES
    a) If seizures are not controlled by the above measures, patients will require endotracheal intubation, mechanical ventilation, continuous EEG monitoring, a continuous infusion of an anticonvulsant, and may require neuromuscular paralysis and vasopressor support. Consider continuous infusions of the following agents:
    1) MIDAZOLAM: ADULT DOSE: An initial dose of 0.2 mg/kg slow bolus, at an infusion rate of 2 mg/minute; maintenance doses of 0.05 to 2 mg/kg/hour continuous infusion dosing, titrated to EEG (Brophy et al, 2012). PEDIATRIC DOSE: 0.1 to 0.3 mg/kg followed by a continuous infusion starting at 1 mcg/kg/minute, titrated upwards every 5 minutes as needed (Loddenkemper & Goodkin, 2011).
    2) PROPOFOL: ADULT DOSE: Start at 20 mcg/kg/min with 1 to 2 mg/kg loading dose; maintenance doses of 30 to 200 mcg/kg/minute continuous infusion dosing, titrated to EEG; caution with high doses greater than 80 mcg/kg/minute in adults for extended periods of time (ie, longer than 48 hours) (Brophy et al, 2012); PEDIATRIC DOSE: IV loading dose of up to 2 mg/kg; maintenance doses of 2 to 5 mg/kg/hour may be used in older adolescents; avoid doses of 5 mg/kg/hour over prolonged periods because of propofol infusion syndrome (Loddenkemper & Goodkin, 2011); caution with high doses greater than 65 mcg/kg/min in children for extended periods of time; contraindicated in small children (Brophy et al, 2012).
    3) PENTOBARBITAL: ADULT DOSE: A loading dose of 5 to 15 mg/kg at an infusion rate of 50 mg/minute or lower; may administer additional 5 to 10 mg/kg. Maintenance dose of 0.5 to 5 mg/kg/hour continuous infusion dosing, titrated to EEG (Brophy et al, 2012). PEDIATRIC DOSE: A loading dose of 3 to 15 mg/kg followed by a maintenance dose of 1 to 5 mg/kg/hour (Loddenkemper & Goodkin, 2011).
    4) THIOPENTAL: ADULT DOSE: 2 to 7 mg/kg, at an infusion rate of 50 mg/minute or lower. Maintenance dose of 0.5 to 5 mg/kg/hour continuous infusing dosing, titrated to EEG (Brophy et al, 2012)
    b) Endotracheal intubation, mechanical ventilation, and vasopressors will be required (Brophy et al, 2012) and consultation with a neurologist is strongly advised.
    c) Neuromuscular paralysis (eg, rocuronium bromide, a short-acting nondepolarizing agent) may be required to avoid hyperthermia, severe acidosis, and rhabdomyolysis. If rhabdomyolysis is possible, avoid succinylcholine chloride, because of the risk of hyperkalemic-induced cardiac dysrhythmias. Continuous EEG monitoring is mandatory if neuromuscular paralysis is used (Manno, 2003).

Range Of Toxicity

Summary

    A) Because of the numerous agents that may be associated with toxin-induced tachyarrhythmias, a minimum toxic dose cannot be delineated. Coadministration of multiple agents and potential risk factors (eg, electrolyte imbalances {ie, hypokalemia, hypocalcemia, hypomagnesemia}, cardiovascular disease, female gender, etc) may produce refractory symptoms or potentiate the clinical effects observed.
    B) Refer to a specific management if a toxin is known or suspected to determine potential toxicity.

Pharmacology Toxicology

Toxicologic Mechanism

    A) Toxins can affect the electrical activity of the heart or can affect the sympathetic and parasympathetic nervous system and are related to three mechanisms: spontaneous depolarization, after depolarization, or reentry pathways.
    B) HUMAN
    1) Toxins that affect the electrical activity of the heart may be mediated by the sympathetic and parasympathetic nervous system or the toxin may act directly on the myocardial conduction system or other myocardial cells resulting in an alteration in the functioning of the myocardial cellular membrane (Hessler, 2002).
    a) Sympathetic actions can result in beta-adrenergic stimulation which accelerates spontaneous diastolic depolarization, and results in an increased sinus rate. Enhancement of automaticity in other pacemaker tissues (atrial, atrioventricular (AV) junctional, Purkinje's) can result in acceleration of ectopic rhythms. Beta-adrenergic stimulation can also increase conduction velocity in slow channel fibers, which can lead to more rapid sinoatrial and AV nodal conduction of impulses, thus shortening the action potential and refractory period. Lastly, beta-adrenergic stimulation enhances afterdepolarization magnitude, thereby increasing the potential for triggered tachyarrhythmias (Benowitz & Goldschlager, 1998).
    b) Parasympathetic stimulation slows the rate of spontaneous diastolic depolarization, which results in slowing of the firing of pacemaker tissues. Slowing of the sinus rate can produce an emergent escape rhythm that originates in the supraventricular or ventricular tissue. Any delay in impulse through the AV node can result in AV block. Conversely, the effects of cholinergic stimulation on ventricular conduction tissue include the raised electric threshold that is necessary for induction of ventricular fibrillation, particularly in the presence of high sympathetic activity. Increased parasympathetic tone can result in tachyarrhythmias due to increased vagal tone. Drugs like digitalis, or beta-adrenergic blocking agents can worsen the tachyarrhythmias observed (Benowitz & Goldschlager, 1998).
    1) CHOLINOMIMETIC TOXINS AND DRUGS
    a) The most common type of cholinomimetic poisoning is due to organophosphate or carbamate insecticide exposure which can result in cholinesterase inhibition. The cardiac effects can be unpredictable but can include the following dysrhythmias: atrial or junctional ventricular bradycardia, AV block, sinus tachycardia, and ventricular tachycardia, along with QT prolongation. Other agents/toxins can include:
    1) Bethanecol
    2) Nicotine
    3) Physostigmine
    4) Pilocarpine
    5) Pyridostigmine
    c) MEMBRANE DEPRESSION - Following overdose some agents can produce a direct effect on myocardial membranes which can induce dysrhythmias. Quinidine is an example of an agent that has depressant effects on membrane responsiveness, which results in a slowing of impulse conduction. Inhibition of the fast sodium current results in a reduced rate of voltage change and a reduced maximum achieved voltage resulting in a slowed impulse conduction. Also, membrane depressants can shift the threshold potential toward 0, thus requiring stimuli of greater intensity to initiate the action potential thus producing a slowed action potential. These electrophysiologic effects can produce slowed repolarization and depolarization times (especially in the His-Purkinje tissue), and are reflected on the ECG as a prolongation of the QT interval. If the intoxication is severe, the clinical features show a failure to respond to cardiac pacing at high-pacing stimulus voltage (Benowitz & Goldschlager, 1998).
    1) MEMBRANE DEPRESSANT DRUGS
    1) Didopyramide
    2) Encainide
    3) Flecainide
    4) Phenothiazines and related neuroleptics
    5) Propanolol (and other beta-blocking agetns)
    6) Quinidine
    7) Tricyclic antidepressants
    8) Reference: (Benowitz & Goldschlager, 1998)
    2) For some medications such as calcium channel blockers and some antidysrhythmic agents, cardiovascular toxicity results from the same mechanism as their therapeutic effects. For toxins, the mechanism seems to be an entirely unrelated effect on the cellular electrophysiology (Hessler, 2002).
    a) TOXIN-INDUCED MECHANISMS
    1) SPONTANEOUS DEPOLARIZATION (automaticity): Toxins can cause myocardial pacemaker cells and cardiac muscle cells to depolarize more rapidly than usual. Often seen in cardiac glycoside and catecholamine toxicity (Hessler, 2002).
    2) AFTER DEPOLARIZATION (triggered automaticity): This results from oscillations and instability in the membrane potential during phase 4 of the action potential where an oscillation reaches the threshold potential causing the membrane to depolarize and another action is generated. The initial normal action potential acts as a 'trigger' for the abnormal oscillations (Hessler, 2002).
    3) REENTRY PATHWAYS: This is considered the most common mechanism and is usually generated when early impulse reaches a branch point with a partial block to conduction in one of the branches resulting in retrograde conduction of impulse and depolarization of the heart with each passage. The initial impulse does not die out but continues to propagate and reactivate the heart. Reentry mechanisms appear to be responsible for most of the dysrhythmias attributable to overdose of antidysrhythmic agents (Hessler, 2002).

References

General Bibliography

    1) AMA Department of DrugsAMA Department of Drugs: AMA Evaluations Subscription, American Medical Association, Chicago, IL, 1992.
    2) Alaspaa AO, Kuisma MJ, Hoppu K, et al: Out-of-hospital administration of activated charcoal by emergency medical services. Ann Emerg Med 2005; 45:207-12.
    3) Alings M & Wilde A: "Brugada" syndrome clinical data and suggested pathophysiological mechanisms. Circulation 1999; 99:666-673.
    4) American Heart Association: 2005 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation 2005; 112(24 Suppl):IV 1-203. Available from URL: http://circ.ahajournals.org/content/vol112/24_suppl/. As accessed 12/14/2005.
    5) Anon: Guidelines for the management of patients with supraventricular arrhythmias. American College of Cardiology/American Heart Association Task Force on Practice Guidelines and the European Soc of Caridology Committee for Practice Guidelines. Circulation 2003; 108:1871.
    6) Bauman JL & DiDomenico RJ: Cocaine-induced channelopathies: emerging evidence on the mu mechanisms of sudden death. J Cardiovas Pharmacol Ther 2002; 7(3) :195-202.
    7) Belardinelli L, Antzelevitch C, & Vos M: Assessing predictors of drug-induced torsade de pointes. TRENDS in Pharmacol Sci 2003; 24(12):619-625.
    8) Benowitz NL & Goldschlager N: Cardiac Disturbances. In: Clinical Management of Poisoning and Drug Overdose 3rd Ed. Editors: Haddad LM, Shannon MW & Winchester JF, W.B. Saunders Company, Philadelphia, PA, 1998, pp 90-119.
    9) Bigger JT & Sahar DI: Clinical types of proarrhythmic response to antiarrhythmic drugs. Am J Cardiol 1987; 59:2E-9E.
    10) Brophy GM, Bell R, Claassen J, et al: Guidelines for the evaluation and management of status epilepticus. Neurocrit Care 2012; 17(1):3-23.
    11) Caravati EM, Knight HH, & Linscott MS: Esophageal laceration and charcoal mediastinum complicating gastric lavage. J Emerg Med 2001; 20:273-276.
    12) Chamberlain JM, Altieri MA, & Futterman C: A prospective, randomized study comparing intramuscular midazolam with intravenous diazepam for the treatment of seizures in children. Ped Emerg Care 1997; 13:92-94.
    13) Charlton NP , Lawrence DT , Brady WJ , et al: Termination of drug-induced torsades de pointes with overdrive pacing. Am J Emerg Med 2010; 28(1):95-102.
    14) Chin RF , Neville BG , Peckham C , et al: Treatment of community-onset, childhood convulsive status epilepticus: a prospective, population-based study. Lancet Neurol 2008; 7(8):696-703.
    15) Choonara IA & Rane A: Therapeutic drug monitoring of anticonvulsants state of the art. Clin Pharmacokinet 1990; 18:318-328.
    16) Chvilicek JP, Hurlbert BJ, & Hill GE: Diuretic-induced hypokalaemia inducing torsades de pointes. Can J Anaesth 1995; 42(12):1137-1139.
    17) Chyka PA, Seger D, Krenzelok EP, et al: Position paper: Single-dose activated charcoal. Clin Toxicol (Phila) 2005; 43(2):61-87.
    18) Dagnone D, Matsui D, & Rieder MJ: Assessment of the palatability of vehicles for activated charcoal in pediatric volunteers. Pediatr Emerg Care 2002; 18:19-21.
    19) Drew BJ, Ackerman MJ, Funk M, et al: Prevention of torsade de pointes in hospital settings: a scientific statement from the American Heart Association and the American College of Cardiology Foundation. J Am Coll Cardiol 2010; 55(9):934-947.
    20) Elliot CG, Colby TV, & Kelly TM: Charcoal lung. Bronchiolitis obliterans after aspiration of activated charcoal. Chest 1989; 96:672-674.
    21) FDA: Poison treatment drug product for over-the-counter human use; tentative final monograph. FDA: Fed Register 1985; 50:2244-2262.
    22) Feely J & Guy E: Lack of effect of ranitidine on the disposition of lignocaine. Br J Clin Pharmacol 1983; 15:378-379.
    23) Golej J, Boigner H, Burda G, et al: Severe respiratory failure following charcoal application in a toddler. Resuscitation 2001; 49:315-318.
    24) Graff GR, Stark J, & Berkenbosch JW: Chronic lung disease after activated charcoal aspiration. Pediatrics 2002; 109:959-961.
    25) Guenther Skokan E, Junkins EP, & Corneli HM: Taste test: children rate flavoring agents used with activated charcoal. Arch Pediatr Adolesc Med 2001; 155:683-686.
    26) Haddad LM, Shannon MW, & Winchester JF: Clinical Management of Poisoning and Drug Overdose (3rd ed), W.B.Saunders Company, Philadelphia, PA, 1998.
    27) Harris CR & Filandrinos D: Accidental administration of activated charcoal into the lung: aspiration by proxy. Ann Emerg Med 1993; 22:1470-1473.
    28) Hegenbarth MA & American Academy of Pediatrics Committee on Drugs: Preparing for pediatric emergencies: drugs to consider. Pediatrics 2008; 121(2):433-443.
    29) Hessler R: Cardiovascular Principles In: Goldfrank LR, Flomenbaum NE, Lewin NA, et al (Eds): Goldfrank's Toxicologic Emergencies, 7th. McGraw-Hill, New York, NY, USA, 2002, pp 315-334.
    30) Hvidberg EF & Dam M: Clinical pharmacokinetics of anticonvulsants. Clin Pharmacokinet 1976; 1:161.
    31) Jackson JE, Bentley JB, Glass SJ, et al: Effects of histamine-2 receptor blockade on lidocaine kinetics. Clin Pharmacol Ther 1985; 37:544-548.
    32) Kasliwal RR, Mukesh S, Manohar G, et al: Pharmacotherapy of atrial fibrillation.. Asian Cardiovasc Thorac Ann 2003; 11:364-374.
    33) Keren A, Tzivoni D, & Gavish D: Etiology, warning signs and therapy of torsade de pointes: a study of 10 patients. Circulation 1981; 64:1167-1174.
    34) Khan IA & Gowda RM: Novel therapeutics for treatment of long-QT syndrome and torsade de pointes. Int J Cardiol 2004; 95(1):1-6.
    35) Kleinman ME, Chameides L, Schexnayder SM, et al: 2010 American Heart Association guidelines for cardiopulmonary resuscitation and emergency cardiovascular care. Part 14: pediatric advanced life support. Circulation 2010; 122(18 Suppl.3):S876-S908.
    36) Lambic IS: Antiarrhythmic therapy for atrial tachyarrhythmias. Medicine & Biol 1999; 6(1):1-10.
    37) Link MS, Berkow LC, Kudenchuk PJ, et al: Part 7: Adult Advanced Cardiovascular Life Support: 2015 American Heart Association Guidelines Update for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation 2015; 132(18 Suppl 2):S444-S464.
    38) Loddenkemper T & Goodkin HP: Treatment of Pediatric Status Epilepticus. Curr Treat Options Neurol 2011; Epub:Epub.
    39) Manno EM: New management strategies in the treatment of status epilepticus. Mayo Clin Proc 2003; 78(4):508-518.
    40) Neumar RW , Otto CW , Link MS , et al: Part 8: adult advanced cardiovascular life support: 2010 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation 2010; 122(18 Suppl 3):S729-S767.
    41) None Listed: Position paper: cathartics. J Toxicol Clin Toxicol 2004; 42(3):243-253.
    42) Onagawa T, Ohkuchi A, Ohki R, et al: Woman with postpartum ventricular tachycardia and hypomagnesemia. J Obstet Gynaecol Res 2003; 29(2):92-95.
    43) Peberdy MA , Callaway CW , Neumar RW , et al: 2010 American Heart Association guidelines for cardiopulmonary resuscitation and emergency cardiovascular care science. Part 9: post–cardiac arrest care. Circulation 2010; 122(18 Suppl 3):S768-S786.
    44) Pentel P: Toxicity of over-the-counter stimulants. JAMA 1984; 252(14):1898-1903.
    45) Perticone F, Ceravolo R, & Cuccurullo O: Prolonged magnesium sulfate infusion in the treatment of ventricular tachycardia in acquired long QT syndrome. Clin Drug Inverst 1997; 13:229-236.
    46) Pollack MM, Dunbar BS, & Holbrook PR: Aspiration of activated charcoal and gastric contents. Ann Emerg Med 1981; 10:528-529.
    47) Product Information: Isuprel(TM) intravenous injection, intramuscular injection, subcutaneous injection, intracardiac injection, isoproterenol HCl intravenous injection, intramuscular injection, subcutaneous injection, intracardiac injection. Hospira, Inc. (per FDA), Lake Forest, IL, 2013.
    48) Product Information: Lidocaine HCl intravenous injection solution, lidocaine HCl intravenous injection solution. Hospira (per manufacturer), Lake Forest, IL, 2006.
    49) Product Information: diazepam IM, IV injection, diazepam IM, IV injection. Hospira, Inc (per Manufacturer), Lake Forest, IL, 2008.
    50) Product Information: dopamine hcl, 5% dextrose IV injection, dopamine hcl, 5% dextrose IV injection. Hospira,Inc, Lake Forest, IL, 2004.
    51) Product Information: lorazepam IM, IV injection, lorazepam IM, IV injection. Akorn, Inc, Lake Forest, IL, 2008.
    52) Product Information: magnesium sulfate heptahydrate IV, IM injection, solution, magnesium sulfate heptahydrate IV, IM injection, solution. Hospira, Inc. (per DailyMed), Lake Forest, IL, 2009.
    53) Product Information: norepinephrine bitartrate injection, norepinephrine bitartrate injection. Sicor Pharmaceuticals,Inc, Irvine, CA, 2005.
    54) Rau NR, Nagaraj MV, Prakash PS, et al: Fatal pulmonary aspiration of oral activated charcoal. Br Med J 1988; 297:918-919.
    55) Roden DM: Mechanism and management of proarrhythmia. Am J Cardiol 1998; 82:491-571.
    56) S Sweetman: Martindale: The Complete Drug Reference. Pharmaceutical Press. London, UK (Internet Version). Edition expires 2004; provided by Truven Health Analytics Inc., Greenwood Village, CO.
    57) Scott R, Besag FMC, & Neville BGR: Buccal midazolam and rectal diazepam for treatment of prolonged seizures in childhood and adolescence: a randomized trial. Lancet 1999; 353:623-626.
    58) Smith WM & Gallagher JJ: "Les torsades de pointes": an unusual ventricular arrhythmia. Ann Intern Med 1980; 93:578-584.
    59) Spiller HA & Rogers GC: Evaluation of administration of activated charcoal in the home. Pediatrics 2002; 108:E100.
    60) Sreenath TG, Gupta P, Sharma KK, et al: Lorazepam versus diazepam-phenytoin combination in the treatment of convulsive status epilepticus in children: A randomized controlled trial. Eur J Paediatr Neurol 2009; Epub:Epub.
    61) Tamargo J: Drug-induced torsades de pointes: From molecular biology to bedside. Jpn J Pharmacol 2000; 83:1-19.
    62) Thakore S & Murphy N: The potential role of prehospital administration of activated charcoal. Emerg Med J 2002; 19:63-65.
    63) Vale JA, Kulig K, American Academy of Clinical Toxicology, et al: Position paper: Gastric lavage. J Toxicol Clin Toxicol 2004; 42:933-943.
    64) Vale JA: Position Statement: gastric lavage. American Academy of Clinical Toxicology; European Association of Poisons Centres and Clinical Toxicologists. J Toxicol Clin Toxicol 1997; 35:711-719.
    65) Vanden Hoek TL, Morrison LJ, Shuster M, et al: Part 12: cardiac arrest in special situations: 2010 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation 2010; 122(18 Suppl 3):S829-S861.
    66) Wall TS & Freedman RA: Ventricular tachycardia in structurally normal hearts. Curr Cardiol Reports 2002; 4:388-395.
    67) Winters SL, Sachs RG, & Curwin JH: Nonsustained polymorphous ventricular tachycardia during amiodarone therapy for atrial fibrillation complicating cardiomyopathy. Management with intravenous magnesium sulfate. Chest 1997; 111(5):1454-1457.
    68) Witchel HJ, Hancox JC, Nutt DJ, et al: Psychotropic drugs, cardiac arrhythmia, and sudden death. J Clin Psychopharmacol 2003; 23:58-77.
    69) Woosley RL & Roden DM: Pharmacologic causes of arrhythmogenic actions of antiarrhythmic drugs. Am J Cardiol 1987; 59:19E-25E.
    70) Yap YG & Camm JA: Drug induced QT prolongation and torsades de pointes. Heart 2003; 89:1363-1372.
    71) Zeltser D, Justo D, Halkin A, et al: Torsade de pointes due to noncardiac drugs most patients have easily identifiable risk factors. Medicine 2003 ; 82(4):282-290.
    72) de Caen AR, Berg MD, Chameides L, et al: Part 12: Pediatric Advanced Life Support: 2015 American Heart Association Guidelines Update for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation 2015; 132(18 Suppl 2):S526-S542.