a) CASE REPORT: Torsades de pointes was reported in a 35-year-old woman following an overdose of an unknown amount of maprotiline. Plasma maprotiline concentration on admission was reported to be 1,080 nanograms/mL. On autopsy, toxicological analysis revealed a plasma thioridazine level of 4.45 mcg/mL (within therapeutic range). Analysis was negative for alcohol, barbiturates, ethchlorvynol, and benzodiazepines (Curtis et al, 1984).
b) CASE REPORT: Torsades de pointes has also been reported 1 to 2 days following an overdose with maprotiline, levothyroxine, tolbutamide, hydrochlorothiazide, and spironolactone. QTc prolongation preceded the episode of torsades de pointes. The patients survived after treatment with lidocaine, bretylium, and phenytoin (Hermann et al, 1983).

a) CASE SERIES: Eighteen of 43 episodes of maprotiline overdose were admitted with a heart rate in excess of 99 beats per minute (Knudsen & Heath, 1984).
b) CASE REPORT: A 44-year-old showed ECG changes of sinus tachycardia (140 beats/min), left anterior hemiblock, and right bundle branch block (QRS = 180 ms) following an ingestion of 3750 mg maprotiline (Fernandez-Quero et al, 1985).
c) CASE REPORT: A 14-month-old boy (weight: about 10 kg) presented with a 1-day history of lethargy, sleepiness, staring episodes with intermittent up-rolling of the eyes, a stiff neck, repeated back arching, 2 previous episodes of generalized tonic-clonic seizures, and a reduced urine output. His vital signs included a heart rate of 150 beats/min, blood pressure of 84/50 mmHg, and a respiratory rate of 48 breaths/min. He was also agitated and difficult to console during examination. He was treated with an IV dose of midazolam (1 mg) due to the suspicion of seizures. A 12-lead ECG revealed a first-degree heart block with an increased PR interval (0.176 msec), but QRS interval (67 msec) and the corrected QT interval (446 msec) were normal. All laboratory results, including his cerebrospinal fluid culture and viral PCR, were normal at this time, but a blood toxicological analysis 24 hours after presentation was positive for maprotiline (36.5 ng/mL). It was determined that the patient's grandmother was taking maprotiline for depression. Following supportive care, including IV sodium bicarbonate infusion to achieve alkalemia for 2 days, his PR interval and tachycardia resolved by day 3 of hospitalization. His blood maprotiline concentration decreased gradually and he was discharged on day 6 (Ahmad et al, 2014).

a) Maprotiline therapy has rarely been associated with heart block (Prod Info maprotiline hcl oral tablets, 2006).
b) CASE REPORT: A drug interaction between maprotiline and ritonavir and/or fluconazole in an AIDS patient resulted in toxic maprotiline plasma concentrations, anticholinergic side effects, and an ECG with prolonged PR interval (0.26 ms) and QRS complex (0.16 ms) (Hocqueloux et al, 2001).

a) CASE REPORT: A 14-month-old boy (weight: about 10 kg) presented with a 1-day history of lethargy, sleepiness, staring episodes with intermittent up-rolling of the eyes, a stiff neck, repeated back arching, 2 previous episodes of generalized tonic-clonic seizures, and a reduced urine output. His vital signs included a heart rate of 150 beats/min, blood pressure of 84/50 mmHg, and a respiratory rate of 48 breaths/min. He was also agitated and difficult to console during examination. He was treated with an IV dose of midazolam (1 mg) due to the suspicion of seizures. A 12-lead ECG revealed a first-degree heart block with an increased PR interval (0.176 msec), but QRS interval (67 msec) and the corrected QT interval (446 msec) were normal. All laboratory results, including his cerebrospinal fluid culture and viral PCR, were normal at this time, but a blood toxicological analysis 24 hours after presentation was positive for maprotiline (36.5 ng/mL). It was determined that the patient's grandmother was taking maprotiline for depression. Following supportive care, including IV sodium bicarbonate infusion to achieve alkalemia for 2 days, his PR interval and tachycardia resolved by day 3 of hospitalization. His blood maprotiline concentration decreased gradually and he was discharged on day 6 (Ahmad et al, 2014).
b) CASE REPORT: Right bundle branch block (QRS=0.18 seconds), left anterior hemiblock, and sinus tachycardia (140 bpm) were reported in a 44-year-old patient following an overdose of 3750 mg maprotiline (Fernandez-Quero et al, 1985; Bergman & Watson, 1983).
c) CASE REPORT: QRS widening with a right bundle branch block configuration was reported in an 11-month-old (Betremieux et al, 1990).
d) CASE SERIES: QRS interval widening was associated with a decreased level of consciousness. In three severe poisonings, progressive widening of the QRS interval and bradycardia was observed prior to asystole (Knudsen & Heath, 1984; Bergman & Watson, 1983).
e) CASE REPORT: Bolognesi et al (1997) reported a case of maprotiline, perphenazine and benzodiazepine overdose resulting in abnormal repolarization mimicking myocardial infarction. Marked QRS widening, ST elevation in the right precordial leads mimicking a current of injury, and a slight QT interval prolongation were recorded in this 39-year-old woman (Bolognesi et al, 1997).

a) CASE REPORT: Ventricular tachycardia was reported in a 6-year-old child following maprotiline overdose (Peverini et al, 1988).

a) CASE REPORT: A drug interaction between maprotiline and ritonavir and/or fluconazole in an AIDS patient resulted in toxic maprotiline plasma concentrations, anticholinergic adverse effects, and including severe orthostatic hypotension (blood pressure drop from 130/85 to 70/30 mmHg) (Hocqueloux et al, 2001).

a) CASE SERIES: Hypotension (systolic blood pressure less than 90 mmHg) was reported in 8 of 43 episodes of maprotiline overdose in one case series (Knudsen & Heath, 1984). In another series 2 of 41 patients developed hypotension (Crome & Newman, 1977).

a) Maprotiline therapy has rarely been associated with dysrhythmias (Prod Info maprotiline hcl oral tablets, 2006).
b) CASE REPORT: A case of atrial flutter with a 2:1 block at a ventricular rate of 144 with left axis deviation was reported in an 80-year-old woman following 10 days of therapeutic maprotiline. The atrial dysrhythmia resolved on discontinuation of maprotiline, but returned on rechallenge (Tollefson et al, 1984).

a) Hypertension has rarely been reported with maprotiline therapy (Prod Info maprotiline hcl oral tablets, 2006).

a) CASE SERIES: In a series of 41 patients with maprotiline overdose, 3 developed significant bradycardia (Crome & Newman, 1977).

a) CASE REPORT: Sudden cardiac arrest is reported in a 76-year-old woman with end stage renal disease after 9 days of maprotiline therapy. Resuscitation was successful. Even though maprotiline dose was in the normal range, other factors may have contributed to cardiac arrest: past history of cardiac dysrhythmias, age, and drug accumulation as a result of renal failure (Fukunishi et al, 1998).

a) CASE SERIES: In a series of 41 patients with maprotiline overdose, 3 developed cardiac arrest (Crome & Newman, 1977).

a) RABBITS: In rabbits, maprotiline was equipotent to amitriptyline and imipramine in causing hypotension (Hughes & Radwan, 1979).

a) RABBITS: Maprotiline toxicity has caused impaired myocardial contractility (Pedersen et al, 1982). In rabbits, it has increased left ventricular pressure (Desager & Harvengt, 1983).
b) CATS: In anesthetized cats given 35 mg/kg maprotiline, mean arterial pressure fell, left ventricular end diastolic pressure increased, and cardiac performance (dP/dt) decreased. There was also a decrease in contractility, stroke volume, cardiac output, and total peripheral resistance (Boeck et al, 1984).

a) CASE SERIES: Intubation and assisted ventilation was required for a mean of 36 hours in 6 of 43 episodes of maprotiline overdose (Knudsen & Heath, 1984). Coingestants were not reported in these patients.

a) Aspiration syndrome has been reported (Knudsen & Heath, 1984).
b) CASE REPORT: Aspiration pneumonia and adult respiratory distress syndrome were reported in a patient following an ingestion of 3.1 to 4.2 grams maprotiline (North et al, 1983).

a) CASE REPORT: One case of exercise-induced bronchospasm caused by maprotiline use (Dubrovsky & Freed, 1988) has been reported as has pulmonary alveolitis associated with dyspnea and hypoxia (Salmeron et al, 1988).

a) Grand mal seizures have been reported in patients receiving therapeutic doses of maprotiline chronically (Prod Info maprotiline hcl oral tablets, 2006; Hoffman & Wachsmuth, 1982).

a) Seizures are more common following an overdose with maprotiline than an overdose with tricyclic antidepressants. The risk of seizure activity increases with higher doses of maprotiline (S Sweetman , 2001).
b) CASE REPORT: A 14-month-old boy (weight: about 10 kg) presented with a 1-day history of lethargy, sleepiness, staring episodes with intermittent up-rolling of the eyes, a stiff neck, repeated back arching, 2 previous episodes of generalized tonic-clonic seizures, and a reduced urine output. His vital signs included a heart rate of 150 beats/min, blood pressure of 84/50 mmHg, and a respiratory rate of 48 breaths/min. He was also agitated and difficult to console during examination. He was treated with an IV dose of midazolam (1 mg) due to the suspicion of seizures. A 12-lead ECG revealed a first-degree heart block with an increased PR interval (0.176 msec), but QRS interval (67 msec) and the corrected QT interval (446 msec) were normal. All laboratory results, including his cerebrospinal fluid culture and viral PCR, were normal at this time, but a blood toxicological analysis 24 hours after presentation was positive for maprotiline (36.5 ng/mL). It was determined that the patient's grandmother was taking maprotiline for depression. Following supportive care, including IV sodium bicarbonate infusion to achieve alkalemia for 2 days, his PR interval and tachycardia resolved by day 3 of hospitalization. His blood maprotiline concentration decreased gradually and he was discharged on day 6 (Ahmad et al, 2014).
c) CASE SERIES: In a study of 43 consecutive episodes of maprotiline overdose, 15 patients had seizures. Fourteen of 15 had grand mal seizures which occurred within the first 24 hours postadmission. Seizures were reported in 46% of patients with widened QRS interval greater than or equal to 0.10 seconds. Seizures were also reported to occur in approximately 13% of patients with a QRS interval less than 0.10 seconds. Not all reported seizures responded to diazepam (North et al, 1983). Seizures may be less frequent if diazepam is ingested with maprotiline (Knudsen & Heath, 1984).
d) CASE SERIES: In another series of 41 patients with maprotiline overdose, 8 developed seizures (Crome & Newman, 1977).
e) CASE SERIES: In a retrospective case series, Serena et al (1994) reported the severity of poisoning and probability of seizures to be dose-dependent. Of 67 patients with severe maprotiline overdose, 77% developed seizures .

a) Maprotiline and doxepin were equally sedating in human volunteers (Stromberg et al, 1988).

a) Patients may remain comatose beyond 24 hours following a maprotiline overdose (Hayes & Kristoff, 1986; Knudsen & Heath, 1984).
b) CASE SERIES: In a series of 41 patients with maprotiline overdose, 7 were comatose and 24 were drowsy (Crome & Newman, 1977).
c) CASE SERIES: In one study of 43 consecutive episodes of maprotiline overdose, 17 patients were still comatose 24 hours postadmission; seven patients were still comatose at 48 hours and three patients at 72 hours postadmission (Knudsen & Heath, 1984).

a) CASE REPORT: A tremor of a patient's hands and unsteadiness on her feet were reported following an increase in the dosage of maprotiline hydrochloride from 75 mg once daily at bedtime to 300 mg once daily at bedtime. Seven days following the increase in dosage the patient had two grand mal seizures. There was no family history or past history of epilepsy. She was taking an oral contraceptive pill concurrently (Hall & Russell, 1978).

a) Delirium has been reported following a maprotiline overdose (Hayes & Kristoff, 1986).

a) Hypnopompic hallucinations, including visual, tactile, auditory or a combination of these types of hallucinations have been reported on awakening while patients were receiving maprotiline (Albala et al, 1983).

a) Hallucinations have been reported during recovery from maprotiline overdose (Knudsen & Heath, 1984).

a) Myoclonus and hypotonia have been reported (Betremieux et al, 1990; Parker & Lahmeyer, 1984).

a) Isolated cases of stroke with maprotiline therapy have been reported (Prod Info maprotiline hcl oral tablets, 2006).

a) Isolated cases of peripheral neuropathy with maprotiline therapy have been reported (Prod Info maprotiline hcl oral tablets, 2006).

a) In studies, dizziness was reported in 8% of patients receiving maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) In studies, weakness was reported in 4% of patients receiving maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) In studies, headache was reported in 4% of patients receiving maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) In studies, nervousness was reported in 6% of maprotiline patients (Prod Info maprotiline hcl oral tablets, 2006).

a) Restlessness and agitation may occur with overdose (Prod Info maprotiline hcl oral tablets, 2006).
b) CASE REPORT: A 14-month-old boy (weight: about 10 kg) presented with a 1-day history of lethargy, sleepiness, staring episodes with intermittent up-rolling of the eyes, a stiff neck, repeated back arching, 2 previous episodes of generalized tonic-clonic seizures, and a reduced urine output. His vital signs included a heart rate of 150 beats/min, blood pressure of 84/50 mmHg, and a respiratory rate of 48 breaths/min. He was also agitated and difficult to console during examination. He was treated with an IV dose of midazolam (1 mg) due to the suspicion of seizures. A 12-lead ECG revealed a first-degree heart block with an increased PR interval (0.176 msec), but QRS interval (67 msec) and the corrected QT interval (446 msec) were normal. All laboratory results, including his cerebrospinal fluid culture and viral PCR, were normal at this time, but a blood toxicological analysis 24 hours after presentation was positive for maprotiline (36.5 ng/mL). It was determined that the patient's grandmother was taking maprotiline for depression. Following supportive care, including IV sodium bicarbonate infusion to achieve alkalemia for 2 days, his PR interval and tachycardia resolved by day 3 of hospitalization. His blood maprotiline concentration decreased gradually and he was discharged on day 6 (Ahmad et al, 2014).

a) CASE REPORT: A 14-month-old boy (weight: about 10 kg) presented with a 1-day history of lethargy, sleepiness, staring episodes with intermittent up-rolling of the eyes, a stiff neck, repeated back arching, 2 previous episodes of generalized tonic-clonic seizures, and a reduced urine output. His vital signs included a heart rate of 150 beats/min, blood pressure of 84/50 mmHg, and a respiratory rate of 48 breaths/min. He was also agitated and difficult to console during examination. He was treated with an IV dose of midazolam (1 mg) due to the suspicion of seizures. A 12-lead ECG revealed a first-degree heart block with an increased PR interval (0.176 msec), but QRS interval (67 msec) and the corrected QT interval (446 msec) were normal. All laboratory results, including his cerebrospinal fluid culture and viral PCR, were normal at this time, but a blood toxicological analysis 24 hours after presentation was positive for maprotiline (36.5 ng/mL). It was determined that the patient's grandmother was taking maprotiline for depression. Following supportive care, including IV sodium bicarbonate infusion to achieve alkalemia for 2 days, his PR interval and tachycardia resolved by day 3 of hospitalization. His blood maprotiline concentration decreased gradually and he was discharged on day 6 (Ahmad et al, 2014).

a) Extrapyramidal symptoms have rarely been reported in patients receiving maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) Dysarthria has rarely been reported in patients receiving maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) In studies, fatigue was reported in 4% of patients receiving maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) Ataxia may occur with overdose (Prod Info maprotiline hcl oral tablets, 2006).

a) Athetoid movements may occur with overdose (Prod Info maprotiline hcl oral tablets, 2006).

a) In rabbits, maprotiline followed amitriptyline and imipramine in seizure frequency (Hughes & Radwan, 1979). In the cat model, maprotiline was equivalent to imipramine and amitriptyline in seizure onset at 20 mg/kg doses (Koella et al, 1979).

a) In an acute rat toxicity study of maprotiline, doses of 300 mg/kg resulted in decreased nocturnal home cage activity over the first five days of the study, indicative of a CNS depressive effect (Darcy et al, 1999).

a) The anticholinergic action of maprotiline frequently results in decreased GI motility and delayed gastric emptying as well as dry mouth, nausea and vomiting.
b) CASE SERIES: In a series of 41 patients with maprotiline overdose, 5 developed anticholinergic effects (Crome & Newman, 1977).

a) Nausea and vomiting have been reported with maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) Diarrhea has been reported with maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) In studies, constipation occurred in 6% of patients receiving maprotiline(Prod Info maprotiline hcl oral tablets, 2006).

a) Isolated cases of paralytic ileus with maprotiline therapy have been reported (Prod Info maprotiline hcl oral tablets, 2006).

a) In studies, dry mouth occurred in 22% of patients receiving maprotiline (Prod Info maprotiline hcl oral tablets, 2006).

a) Dysphagia has rarely been reported with maprotiline therapy (Prod Info maprotiline hcl oral tablets, 2006).

a) Elevated liver enzymes has rarely been reported with maprotiline therapy (Prod Info maprotiline hcl oral tablets, 2006).
b) Elevations in transaminases and alkaline phosphatase have been reported to decrease several days following the discontinuation of the drug (Wells & Gelenberg, 1981). ALT peaked at 5 days after discontinuation of drug; AST peaked prior to that in another report (Weinstein & Gosselin, 1988).

a) Jaundice has rarely been reported with maprotiline therapy (Prod Info maprotiline hcl oral tablets, 2006).

a) Urinary retention has rarely been reported with maprotiline therapy (Prod Info maprotiline hcl oral tablets, 2006).

a) CASE SERIES: Two of 6 patients in one study reported urinary retention following an overdose of maprotiline. Both were male patients with a stated dose ingested of 2.25 g and 3.2 g. The four patients without urinary retention were all females with stated ingestions of 0.75 g, 0.85, 2.25 g, and 3.2 g (Park & Proudfoot, 1977).

a) Isolated cases of bone marrow depression with maprotiline therapy, including agranulocytosis, eosinophilia, purpura and thrombocytopenia, have been reported (Prod Info maprotiline hcl oral tablets, 2006).

a) There is one case report of transient granulocytopenia associated with a maculopapular rash (Wells & Gelenberg, 1981)

a) Increases in the WBC count have been reported during therapeutic maprotiline dosing.

a) Rashes have been reported to occur twice as frequently with maprotiline than with amitriptyline or imipramine. Maprotiline rashes have been reported as both a generalized exanthema and localized eruption. Occasionally, the rash may be pruritic. Discontinuation of the drug has led to resolution of the rash (S Sweetman , 2001; Wells & Gelenberg, 1981).

a) Rhabdomyolysis may occur if seizures are severe and recurrent following overdose.

a) Muscle rigidity may occur with overdose (Prod Info maprotiline hcl oral tablets, 2006).

a) CASE REPORT: Hypoglycemia has been reported in a 39-year-old woman with type I diabetes mellitus. The patient was started on maprotiline due to depressive symptoms. Ten days after initiation of maprotiline therapy, her blood sugar fell to 3.6 mmol/L. The drug was discontinued and her blood sugar rose to 15.3 mmol/L. Her insulin regimen was never changed (Isotani & Kameoka, 1999).

a) Obtain an ECG and institute continuous cardiac monitoring in all substantial overdose cases due to reports of torsades de pointes, sinus tachycardia, bundle branch blocks, QRS widening, and ventricular dysrhythmias (Curtis et al, 1984; Hermann et al, 1983; Fernandez-Quero et al, 1985; Betremieux et al, 1990; Bergman & Watson, 1983; Peverini et al, 1988).

a) Monitor pulse oximetry or arterial blood gases in patients with coma, respiratory depression or ARDS.

1) If the patient remains symptom-free, and there are no anticholinergic signs present including tachycardia, then the patient may be discharged after undergoing appropriate GI decontamination. A repeat ECG should be done prior to discharge.

1) Seizures, hypotension, and dysrhythmias must be treated promptly and aggressively. Do not discharge until the patient remains asymptomatic and dysrhythmia-free for at least 24 hours.
2) Rapid catastrophic deterioration may occur in patients presenting with trivial signs of poisoning (Callaham & Kassel, 1985).

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.

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).
b) ADVERSE EFFECTS/CONTRAINDICATIONS

a) Failure to remove unabsorbed drug may result in prolonged symptoms.
b) After absorption and metabolism, up to 30% of maprotiline is excreted in bile and gastric secretions, then reabsorbed in the intestines (Swartz & Sherman, 1984); however, multiple dose activated charcoal has not been shown to improve outcome after overdose. Consider administration of a second dose of activated charcoal in patients with severe toxicity or large ingestions.

a) Mild to moderate toxicity on presentation may progress to severe toxicity over minutes to hours. For patients with mild to moderate effects on presentation, activated charcoal should be considered in patients presenting less than 2 hours postingestion. Aggressive symptomatic and supportive care includes airway protection, blood pressure support, QRS monitoring and narrowing, and seizure control.

a) Activated charcoal should be considered in patients presenting less than 2 hours postingestion (protect airway first). Aggressive symptomatic and supportive care is essential, including airway protection, blood pressure support, QRS monitoring, and seizure control. Treat severe hypotension with IV 0.9% NaCl at 10 to 20 mL/kg. Add norepinephrine if unresponsive to fluids. Dopamine and dobutamine may not be effective. Treat seizures with IV benzodiazepines; barbiturates or propofol may be needed if seizures persist or recur. Therapeutic doses of maprotiline may cause prolongation of the QT interval. Concomitant use of maprotiline and other drugs that prolong the QT interval may increase the risk of torsades de pointes. Treat torsades de pointes with IV magnesium sulfate, and correct electrolyte abnormalities, overdrive pacing may be necessary. Treat QRS widening with sodium bicarbonate, treat ventricular dysrhythmias using ACLS protocols. Consider intravenous lipid therapy early for patients with ventricular dysrhythmias or hypotension.

a) The use of physostigmine to treat maprotiline-induced toxicity is NOT recommended because of the potential for physostigmine to induce seizures. Six of seven patients treated with physostigmine in one series developed seizures (Knudsen & Heath, 1984).

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).

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 .

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).

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).

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).

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):

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:
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).

a) DOSE: 1 to 2 milliequivalents/kilogram as needed to achieve an arterial pH of 7.45 to 7.55 (Nattel et al, 1984).

a) There are case reports of maprotiline toxicity responding to alkalinization (Betremieux et al, 1990; Colpart et al, 1986; Kulig, 1986).

a) Quinidine, disopyramide, and procainamide are contraindicated as their effects on myocardial conduction are similar to that of the antidepressants.

a) In a patient with a mixed metabolic acidosis and respiratory alkalosis (pH 7.36) due to hyperventilation, careful administration of sodium bicarbonate successfully terminated ventricular tachycardia on 3 occasions.
b) Extreme care should be taken to monitor acid-base status in such patients.

a) ADULT: LOADING DOSE: 50 to 100 milligrams (0.70 to 1.4 milligrams/kilogram) under ECG monitoring over one minute. A second bolus may be injected in 20 minutes. No more than 200 to 300 milligrams should be administered during a 1 hour period.
b) INFUSION: Following a bolus, an infusion at 1 to 4 milligrams/minute (0.014 to 0.057 milligram/kilogram/minute) may be used.
c) PEDIATRIC: BOLUS: 1 milligram/kilogram. INFUSION: 3 micrograms/kilogram/minute.

a) Maprotiline and propranolol together may lead to potentiation of the B-blocker effects of propranolol and should be avoided, if possible (Wells & Gelenberg, 1981).
b) In one case, propranolol treatment of ventricular ectopics led to hemodynamically significant bradycardia (Hermann et al, 1983).

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).

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).

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).

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).

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).
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).

a) Mexiletine, verapamil, propranolol, and labetalol have also been used to treat TdP, but results have been inconsistent (Khan & Gowda, 2004).

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.

a) Initial intravenous bolus of 1.5 mL/kg 20% lipid emulsion (eg, Intralipid) over 2 to 3 minutes. Asystolic patients or patients with pulseless electrical activity may have a repeat dose, if there is no response to the initial bolus.
b) Follow with an intravenous infusion of 0.25 mL/kg/min of 20% lipid emulsion (eg, Intralipid). Evaluate the patient's response after 3 minutes at this infusion rate. The infusion rate may be decreased to 0.025 mL/kg/min (ie, 1/10 the initial rate) in patients with a significant response. This recommendation has been proposed because of possible adverse effects from very high cumulative rates of lipid infusion. Monitor blood pressure, heart rate, and other hemodynamic parameters every 15 minutes during the infusion.
c) If there is an initial response to the bolus followed by the re-emergence of hemodynamic instability during the lowest-dose infusion, the infusion rate may be increased back to 0.25 mL/kg/min or, in severe cases, the bolus could be repeated. A maximum dose of 10 mL/kg has been recommended by some sources.
d) Where possible, LRT should be terminated after 1 hour or less, if the patient's clinical status permits. In cases where the patient's stability is dependent on continued lipid infusion, longer treatment may be appropriate.

a) Dopamine and dobutamine may not be effective (Peverini et al, 1988).
b) Intraaortic balloons have been used successfully when pressors have failed.

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.

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

a) Seizures have been reported at serum concentrations of 237 to 317 ng/mL (Baselt, 2000).
b) Maprotiline plasma concentrations of 449 ng/mL and 800 ng/mL have been reported in 2 patients who survived an overdose of maprotiline (Baselt, 2000).
c) Two patients survived overdoses with levels of 830 ng/mL and 1500 ng/mL (Northup et al, 1984).

a) Maprotiline plasma concentrations rose from a therapeutic level (166 ng/mL) to a toxic level (266 ng/mL) after the addition of risperidone to a patient's treatment regimen. The patient developed anticholinergic adverse effects which subsided following dose reductions of both drugs (Normann et al, 2002).

a) A postmortem maprotiline blood level of 1300 ng/mL was reported in a 37-year-old man taking 200 mg maprotiline at bedtime for 5 weeks. He was found seizing and was transported to a health care facility. Cardiopulmonary resuscitation was unsuccessful. He had also been prescribed pentazocine several months earlier for analgesia (Okoye et al, 1985).

a) CASE REPORT: A 14-month-old boy (weight: about 10 kg) who ingested an unknown amount of maprotiline, had a maprotiline blood concentration of 36.5 ng/mL 24 hours after presentation. He presented with a 1-day history of lethargy, sleepiness, staring episodes with intermittent up-rolling of the eyes, a stiff neck, repeated back arching, 2 previous episodes of generalized tonic-clonic seizures, and a reduced urine output. His vital signs included a heart rate of 150 beats/min, blood pressure of 84/50 mmHg, and a respiratory rate of 48 breaths/min. A 12-lead ECG revealed a first-degree heart block with an increased PR interval (0.176 msec), but QRS interval (67 msec) and the corrected QT interval (446 msec) were normal. Following supportive care, including IV sodium bicarbonate infusion to achieve alkalemia for 2 days, his PR interval and tachycardia resolved by day 3 of hospitalization. His blood maprotiline concentration decreased gradually and he was discharged on day 6 (Ahmad et al, 2014).

a) 660 mg/kg (RTECS , 2001)

a) 760 mg/kg (RTECS , 2001)