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TRIMETHOBENZAMIDE

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Classification   |    Detailed evidence-based information

Substances Included Synonyms

Therapeutic Toxic Class

    A) Trimethobenzamide is antinausea and antiemetic that acts directly on the chemoreceptor trigger zone. A substituted benzamide, its structure is closest to the dimethylaminoethoxy antihistamines (it is chemically unrelated to phenothiazines).

Specific Substances

    1) Trimethobenzamide hydrochloride
    2) Ro 2-9578
    3) Molecular Formula: C21-H28-N2-05.Cl-H
    4) CAS 138-56-7 (trimethobenzamide)
    5) CAS 554-92-7 (trimethobenzamide hydrochloride)

Available Forms Sources

    A) FORMS
    1) Trimethobenzamide hydrochloride is available as 300 mg capsules (Prod Info TIGAN(R) oral capsules, 2007); and 100 mg/mL in 2 mL ampules for injection; 100 mg/mL in multiple-dose vials for injection (Prod Info TIGAN(R) oral capsules, IM injection, 2006).
    a) SUPPOSITORIES: As of 2007, the FDA has notified manufacturers to stop producing and distributing trimethobenzamide suppositories due to a lack of evidence of effectiveness. This announcement does not affect oral capsules and injectable products containing trimethobenzamide (US Food and Drug Administration, 2007).
    B) USES
    1) Trimethobenzamide is indicated for the treatment of postoperative nausea and vomiting and for nausea associated with gastroenteritis (Prod Info TIGAN(R) oral capsules, 2007; Prod Info TIGAN(R) oral capsules, IM injection, 2006).

Overview

Life Support

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

Clinical Effects

    0.2.1) SUMMARY OF EXPOSURE
    A) USES: Trimethobenzamide, a substituted benzamide, is used for the treatment of postoperative nausea and vomiting and for nausea associated with gastroenteritis.
    B) PHARMACOLOGY: Although the mechanism is not fully understood, it may involve the chemoreceptor trigger zone, an area in the medulla oblongata in which emetic impulses are conveyed to the vomiting center. Trimethobenzamide is related to phenothiazines and can produce both cardiovascular and CNS effects.
    C) EPIDEMIOLOGY: Exposure is uncommon; other agents are used more often to treat nausea and vomiting.
    D) WITH THERAPEUTIC USE
    1) ADVERSE EVENTS: Anticholinergic effects include central (ie, hyperactivity, disorientation, delirium, seizure activity, vomiting, coma) and peripheral (ie, mydriasis, tachycardia, hypo- or hypertension, hyperpyrexia, urinary retention) manifestations.
    2) ALPHA-ADRENERGIC BLOCKADE (ie, vasodilation, hypotension and miosis) may override anticholinergic effects. CNS depression can develop.
    3) CARDIAC DYSRHYTHMIAS can resemble those of quinidine toxicity (ie, may produce ventricular tachycardia and ventricular fibrillation) following a significant overdose. ECG changes may include: depression of A-V and intraventricular conduction resulting in a prolonged QT interval, notched T waves, decreasing sinoatrial rate, and widened QRS complexes.
    4) Trimethobenzamide may produce EXTRAPYRAMIDAL REACTIONS that may include a sudden onset of bizarre muscular spasms, especially of the head and neck; difficulties in speaking and swallowing (usually occurring within 48 hours of starting trimethobenzamide), akathisia and akinesia.
    5) PRODUCT WITHDRAWAL: As of 2007, the FDA notified manufacturers to stop producing and distributing trimethobenzamide suppositories due to a lack of efficacy. This notification did not affect oral capsules and injectable products containing trimethobenzamide.
    E) WITH POISONING/EXPOSURE
    1) OVERDOSE: Limited data. Signs and symptoms may mimic those of a phenothiazine overdose. It is anticipated that overdose may be an extension of adverse events including anticholinergic effects, alpha-adrenergic blockade and cardiac dysrhythmias.
    0.2.3) VITAL SIGNS
    A) WITH THERAPEUTIC USE
    1) RESPIRATORY ARREST may result from neuromuscular blockade. Hyper- or hypotension may be seen; often alpha blockade leads to hypotension. Hyperpyrexia and tachycardia may occur secondary to peripheral anticholinergic effects.
    0.2.20) REPRODUCTIVE
    A) Trimethobenzamide is in FDA Pregnancy Category C.

Laboratory Monitoring

    A) Monitor vital signs and CNS function (drowsiness is likely). Monitor electrolytes, liver enzymes, kidney function and CPK after a significant overdose.
    B) Obtain a baseline ECG and institute continuous cardiac monitoring after large overdose or in symptomatic patients. QRS and QT prolongation and ventricular dysrhythmias are theoretically possible.
    C) Monitor for hypersensitivity reactions that may develop with parenteral administration.

Treatment Overview

    0.4.2) ORAL/PARENTERAL EXPOSURE
    A) MANAGEMENT OF MILD TO MODERATE TOXICITY
    1) Treatment is symptomatic and supportive. Monitor blood pressure, pulse rate and rhythm. Monitor neurologic function. Watch for hyper- or hypothermia and treat accordingly. Maintain hydration and monitor urine output. HYPOTENSION: Initially treat with isotonic IV fluids, followed by dopamine, norepinephrine as necessary. VOMITING: Administer IV fluids and electrolyte repletion, if significant vomiting occurs. Theoretically, alterations in cardiac rhythm including QT prolongation may occur. Institute continuous cardiac monitoring and obtain a baseline ECG in a patient with a significant overdose.
    B) MANAGEMENT OF SEVERE TOXICITY
    1) Treatment is symptomatic and supportive. Monitor CNS function. Institute continuous cardiac monitoring and obtain serial ECGs. Monitor serum electrolytes and arterial blood gases. HYPERTHERMIA: Hyperpyrexia may occur secondary to a peripheral anticholinergic action. Monitor core temperature and treat hyperthermia with aggressive benzodiazepine sedation to control agitation, external cooling. Neuromuscular paralysis and endotracheal intubation may be necessary in patients with severe hyperthermia. Monitor patient closely until symptoms resolve. SEIZURES: Initially treat with benzodiazepines. VENTRICULAR DYSRHYTHMIAS: Sodium bicarbonate may be effective in reversing QRS widening and treating ventricular dysrhythmias. Consider a starting dose of 1 to 2 mEq/kg IV bolus, repeat as needed. Maintain an arterial pH 7.45 to 7.55. Since trimethobenzamide may mimic a phenothiazine overdose which can produce "quinidine-like" effects on the myocardium, quinidine, procainamide, and disopyramide should be avoided. VENTRICULAR TACHYCARDIA/FIBRILLATION: Unstable rhythms require immediate cardioversion. Consider sodium bicarbonate and lidocaine as needed. Torsades has not been observed but is theoretically possible.
    C) DECONTAMINATION
    1) PREHOSPITAL: GI decontamination is not indicated due to the risk of CNS depression (ie, drowsiness, seizures).
    2) HOSPITAL: Administer activated charcoal if given soon after a significant ingestion, if the patient is alert and the airway is protected.
    D) AIRWAY MANAGEMENT
    1) Airway management is unlikely to be necessary following a mild to moderate exposure, but may be necessary if cardiac instability (ie, ventricular dysrhythmias) or CNS effects (ie, seizures, coma) develop.
    E) ANTIDOTE
    1) None.
    F) ENHANCED ELIMINATION
    1) There are no reports of enhanced elimination therapy following a trimethobenzamide overdose.
    G) PATIENT DISPOSITION
    1) HOME CRITERIA: An asymptomatic adult or child with an inadvertent minor exposure (eg, a single extra dose in a child) may be monitored at home.
    2) OBSERVATION CRITERIA: Patients with a significant or deliberate trimethobenzamide overdose should be observed for at least 10 hours after ingestion with continuous cardiac monitoring and serial ECGs. If no dysrhythmias or QT prolongation develop, the patient may be discharged following a mental health evaluation as needed.
    3) ADMISSION CRITERIA: A patient with dysrhythmias or QT prolongation on ECG should be admitted to an intensive care setting for continuous cardiac monitoring and therapy.
    4) CONSULT CRITERIA: Contact a medical toxicologist or Poison Center for assistance in managing patients with severe toxicity or in whom the diagnosis is unclear. Patients with a deliberate self-harm ingestion should be evaluated by a mental health specialist.
    H) PHARMACOKINETICS
    1) ORAL: The mean elimination half-life is 7 to 9 hours. Approximately, 30 to 50% of a single dose is excreted unchanged in the urine in about 48 to 72 hours. In healthy adult subjects, the maximum plasma concentration was approximately 15 minutes after receiving a single 300 mg trimethobenzamide oral dose. The apparent volume of distribution is 0.49 L/kg.
    I) PITFALLS
    1) Coingestion of other agents that may produce cardiac dysrhthymias.
    J) DIFFERENTIAL DIAGNOSIS
    1) Other agents that may produce cardiac dysrhthymias or QT prolongation. Avoid class 1a (eg, quinidine, disopyramide, procainamide), class 1c (eg, flecainide, encainide, propafenone) and most class lll antidysrhythmics (eg, N-acetylprocainamide, sotalol).

Range Of Toxicity

    A) TOXICITY: A toxic dose has not been established. Overdose events are very limited. An adult survived an overdose of 71 mg/kg. Based on animal studies, the minimum lethal dose would be about 25 mg/kg.
    B) THERAPEUTIC DOSE: ADULT: ORAL: 300 mg capsule taken 3 to 4 times daily as needed; PARENTERAL: 200 mg (2 mL) IM 3 or 4 times daily as needed. PEDIATRIC: ORAL and PARENTERAL is NOT recommended. PRODUCT WITHDRAWAL: RECTAL SUPPOSITORIES: As of 2007, the FDA notified manufacturers to stop producing and distributing trimethobenzamide suppositories due to a lack of evidence of efficacy.

Clinical Effects

Summary Of Exposure

    A) USES: Trimethobenzamide, a substituted benzamide, is used for the treatment of postoperative nausea and vomiting and for nausea associated with gastroenteritis.
    B) PHARMACOLOGY: Although the mechanism is not fully understood, it may involve the chemoreceptor trigger zone, an area in the medulla oblongata in which emetic impulses are conveyed to the vomiting center. Trimethobenzamide is related to phenothiazines and can produce both cardiovascular and CNS effects.
    C) EPIDEMIOLOGY: Exposure is uncommon; other agents are used more often to treat nausea and vomiting.
    D) WITH THERAPEUTIC USE
    1) ADVERSE EVENTS: Anticholinergic effects include central (ie, hyperactivity, disorientation, delirium, seizure activity, vomiting, coma) and peripheral (ie, mydriasis, tachycardia, hypo- or hypertension, hyperpyrexia, urinary retention) manifestations.
    2) ALPHA-ADRENERGIC BLOCKADE (ie, vasodilation, hypotension and miosis) may override anticholinergic effects. CNS depression can develop.
    3) CARDIAC DYSRHYTHMIAS can resemble those of quinidine toxicity (ie, may produce ventricular tachycardia and ventricular fibrillation) following a significant overdose. ECG changes may include: depression of A-V and intraventricular conduction resulting in a prolonged QT interval, notched T waves, decreasing sinoatrial rate, and widened QRS complexes.
    4) Trimethobenzamide may produce EXTRAPYRAMIDAL REACTIONS that may include a sudden onset of bizarre muscular spasms, especially of the head and neck; difficulties in speaking and swallowing (usually occurring within 48 hours of starting trimethobenzamide), akathisia and akinesia.
    5) PRODUCT WITHDRAWAL: As of 2007, the FDA notified manufacturers to stop producing and distributing trimethobenzamide suppositories due to a lack of efficacy. This notification did not affect oral capsules and injectable products containing trimethobenzamide.
    E) WITH POISONING/EXPOSURE
    1) OVERDOSE: Limited data. Signs and symptoms may mimic those of a phenothiazine overdose. It is anticipated that overdose may be an extension of adverse events including anticholinergic effects, alpha-adrenergic blockade and cardiac dysrhythmias.

Vital Signs

    3.3.1) SUMMARY
    A) WITH THERAPEUTIC USE
    1) RESPIRATORY ARREST may result from neuromuscular blockade. Hyper- or hypotension may be seen; often alpha blockade leads to hypotension. Hyperpyrexia and tachycardia may occur secondary to peripheral anticholinergic effects.
    3.3.2) RESPIRATIONS
    A) WITH THERAPEUTIC USE
    1) NEUROMUSCULAR BLOCKADE secondary to peripheral anticholinergic effects may lead to respiratory arrest (Prod Info Tigan(R), 2001).
    3.3.3) TEMPERATURE
    A) WITH THERAPEUTIC USE
    1) Hyperpyrexia may occur secondary to a peripheral anticholinergic action of trimethobenzamide (Prod Info Tigan(R), 2001).
    3.3.4) BLOOD PRESSURE
    A) WITH THERAPEUTIC USE
    1) HYPERTENSION/HYPOTENSION: Hypertension may occur due to peripheral anticholinergic action. However, alpha blockade, causing vasodilatation, often overrides the anticholinergic effect, resulting in hypotension (Prod Info Tigan(R), 2001).
    a) One study in anesthesia patients concluded that no significant changes in blood pressure occurred; however, some women given trimethobenzamide did experience somewhat higher blood pressure than a placebo group (Dobkin et al, 1968). Other studies of therapeutic use have found no change in blood pressure with a single dose of trimethobenzamide (Snow, 1967).

Heent

    3.4.3) EYES
    A) WITH THERAPEUTIC USE
    1) Anticholinergic effects are generally dose-related and may include miosis or mydriasis. Peripheral anticholinergic action may cause mydriasis. However, this is often overruled by alpha blockade, which may result in miosis (Prod Info Tigan(R), 2001).
    2) Blurred vision has been reported with trimethobenzamide therapy (Prod Info TIGAN(R) oral capsules, 2007).
    3.4.6) THROAT
    A) WITH THERAPEUTIC USE
    1) A sensation of "dry throat" and thirst may occur secondary to the drug's peripheral anticholinergic action. dysphagia may also occur (Prod Info Tigan(R), 2001).

Cardiovascular

    3.5.2) CLINICAL EFFECTS
    A) ELECTROCARDIOGRAM ABNORMAL
    1) WITH THERAPEUTIC USE
    a) CARDIAC DEPRESSION, similar to signs of quinidine toxicity, may be seen with trimethobenzamide use. Depression of atrioventricular and intraventricular conduction may result in the following ECG findings: notched T waves; prolonged QT interval; decreased sinoatrial rate; widened QRS complexes; ventricular tachycardia; and ventricular fibrillation (Prod Info Tigan(R), 2001).
    B) VASODILATATION
    1) WITH THERAPEUTIC USE
    a) Hypertension may occur due to peripheral anticholinergic action. However, alpha blockade, causing vasodilatation, often overrides the anticholinergic effect, resulting in hypotension (Prod Info Tigan(R), 2001). Hypotension has been reported following parenteral administration to surgical patients (Prod Info TIGAN(R) oral capsules, IM injection, 2006).
    3.5.3) ANIMAL EFFECTS
    A) ANIMAL STUDIES
    1) HYPOTENSION
    a) DOGS: Intravenous administration of trimethobenzamide hydrochloride caused arterial blood pressure fall secondary to direct vasodilatory effects (including decreased total peripheral resistance) in dogs (Wang, 1961).

Respiratory

    3.6.2) CLINICAL EFFECTS
    A) APNEA
    1) WITH THERAPEUTIC USE
    a) RESPIRATORY ARREST may occur secondary to neuromuscular blockade (Prod Info Tigan(R), 2001).

Neurologic

    3.7.2) CLINICAL EFFECTS
    A) PARASYMPATHOLYTIC POISONING
    1) WITH THERAPEUTIC USE
    a) NEUROMUSCULAR BLOCKADE, secondary to peripheral anticholinergic effects, may lead to respiratory arrest (Prod Info Tigan(R), 2001). Seizures, hyperactivity, disorientation, dizziness, anxiety, delirium, hallucinations, coma, nausea, and vomiting are also centrally mediated anticholinergic effects (Prod Info TIGAN(R) oral capsules, 2007; Prod Info Tigan(R), 2001). Hypotension or hypertension, tachycardia, hyperpyrexia, decreased bodily secretions, decreased gastrointestinal motility, urinary retention, dysphagia, thirst, xerostomia, and mydriasis may occur secondary to peripheral anticholinergic action (Prod Info Tigan(R), 2001).
    B) EXTRAPYRAMIDAL DISEASE
    1) WITH THERAPEUTIC USE
    a) ACUTE DYSTONIC REACTION may occur with trimethobenzamide. Symptoms most often occur within 48 hours of first taking trimethobenzamide. Symptoms may include sudden onset of bizarre muscular spasms, especially in the head and neck. Involuntary spasms of the tongue and mouth may lead to difficulty in speaking and swallowing. Akathisia, manifested by initial muscular discomfort, may occur as well as akinesia, usually manifested by weakness and muscular fatigue, may occur with trimethobenzamide therapy (Prod Info Tigan(R), 2001).
    b) Extrapyramidal reactions are well known with virtually all of the antipsychotic drugs. Although a typical Parkinsonism Syndrome has not been reported with trimethobenzamide, weakness and muscle fatigue (akinesia) have been reported in 1 pediatric case (Schiele et al, 1973).
    2) WITH POISONING/EXPOSURE
    a) One case of decerebrate posturing with opisthotonos has been reported in an infant given 900 mg via suppositories in 24 hours (Holmes & Flaherty, 1976).
    C) DROWSY
    1) WITH THERAPEUTIC USE
    a) DROWSINESS is a commonly reported therapeutic adverse effect (Prod Info TIGAN(R) oral capsules, 2007; Prod Info TIGAN(R) oral capsules, IM injection, 2006; Prod Info Tigan(R), 2001; Dundee et al, 1966).
    D) PAIN
    1) WITH THERAPEUTIC USE
    a) PAIN at the site of injection has been reported with use of the parenteral formulation (Prod Info Tigan(R), 2001; Dundee et al, 1966).
    E) REYE'S SYNDROME
    1) WITH THERAPEUTIC USE
    a) It has been suggested that centrally acting antiemetics may contribute, in combination with viral illnesses to the development of Reye's syndrome. Although this has not been confirmed, the manufacturer recommends caution with use in children (Prod Info TIGAN(R) oral capsules, IM injection, 2006; Prod Info Tigan(R), 2001).

Gastrointestinal

    3.8.2) CLINICAL EFFECTS
    A) NAUSEA AND VOMITING
    1) WITH THERAPEUTIC USE
    a) Nausea and vomiting may result from centrally mediated anticholinergic effects. Dysphagia and difficulty swallowing may be seen secondary to peripheral anticholinergic effects (Prod Info Tigan(R), 2001).
    B) DIARRHEAL DISORDER
    1) WITH THERAPEUTIC USE
    a) Diarrhea has been reported during trimethobenzamide therapy (Prod Info TIGAN(R) oral capsules, IM injection, 2006).

Hepatic

    3.9.2) CLINICAL EFFECTS
    A) TOXIC HEPATITIS
    1) WITH THERAPEUTIC USE
    a) Jaundice has occurred with therapeutic use (Prod Info TIGAN(R) oral capsules, 2007).
    b) Signs of hepatitis in one case of therapeutic oral administration included: clinical jaundice; dark colored urine; anorexia; and epigastric discomfort. Histological findings on biopsy included focal hepatic necrosis, inflammatory cell infiltrates, and centrilobular cholestasis (Borda & Jick, 1967).

Genitourinary

    3.10.2) CLINICAL EFFECTS
    A) RETENTION OF URINE
    1) WITH THERAPEUTIC USE
    a) Urinary retention may be a dose-related effect of trimethobenzamide ingestion (Prod Info Tigan(R), 2001).

Musculoskeletal

    3.15.2) CLINICAL EFFECTS
    A) INJECTION SITE PAIN
    1) WITH THERAPEUTIC USE
    a) Intramuscular administration of trimethobenzamide may cause pain, burning, redness, and swelling at the injection site (Prod Info Tigan(R), 2001).
    B) CRAMP
    1) WITH POISONING/EXPOSURE
    a) Muscle cramps have been reported with therapy (Prod Info TIGAN(R) oral capsules, 2007).

Immunologic

    3.19.2) CLINICAL EFFECTS
    A) HYPERSENSITIVITY REACTION
    1) WITH THERAPEUTIC USE
    a) Hypersensitivity reactions have been reported with trimethobenzamide therapy (Prod Info TIGAN(R) oral capsules, IM injection, 2006).

Reproductive

    3.20.1) SUMMARY
    A) Trimethobenzamide is in FDA Pregnancy Category C.
    3.20.3) EFFECTS IN PREGNANCY
    A) PREGNANCY CATEGORY
    TRIMETHOBENZAMIDEC
    Reference: Briggs et al, 1998.

Carcinogenicity

    3.21.3) HUMAN STUDIES
    A) LACK OF INFORMATION
    1) No information is available on which to base a judgement of carcinogenicity.

Genotoxicity

    A) No information is available on which to base a judgement of genotoxicity.

Laboratory Monitoring

Monitoring Parameters Levels

    4.1.1) SUMMARY
    A) Monitor vital signs and CNS function (drowsiness is likely). Monitor electrolytes, liver enzymes, kidney function and CPK after a significant overdose.
    B) Obtain a baseline ECG and institute continuous cardiac monitoring after large overdose or in symptomatic patients. QRS and QT prolongation and ventricular dysrhythmias are theoretically possible.
    C) Monitor for hypersensitivity reactions that may develop with parenteral administration.
    4.1.2) SERUM/BLOOD
    A) BLOOD/SERUM CHEMISTRY
    1) Monitor hepatic function, especially direct and indirect bilirubin levels.
    2) Monitor CBC, urinalysis, liver enzymes and kidney function tests in patients with significant exposure.
    B) COAGULATION STUDIES
    1) If hepatitis is suspected, monitor prothrombin time or INR (Borda & Jick, 1967).
    C) LABORATORY INTERFERENCE
    1) CROSS-REACTION: Trimethobenzamide in urine has been found to cross-react with amphetamine and methamphetamine in the following assays: Roche MA, EMIT, FPIA. Cross-reactivity was found to be less than 1% based on dilution of the sample (Jones et al, 1993). Trimethobenzamide is probably sufficiently similar to amphetamine derivatives used in these assays to be able to react with the antibodies on which the assays are based (Colbert, 1994).
    2) INTERFERENCE: Phenothiazines in general, and possibly trimethobenzamide, are reported to interfere with the following tests: they may cause a false negative 5HIAA test; a false positive test for 17 ketogenic steroids; and they may unpredictably alter test results for protein bound iodine (Prod Info, 1977).

Treatment

Life Support

    A) Support respiratory and cardiovascular function.

Patient Disposition

    6.3.1) DISPOSITION/ORAL EXPOSURE
    6.3.1.1) ADMISSION CRITERIA/ORAL
    A) A patient with dysrhythmias or QT prolongation on ECG should be admitted to an intensive care setting for continuous cardiac monitoring and therapy.
    6.3.1.2) HOME CRITERIA/ORAL
    A) An asymptomatic adult or child with an inadvertent minor exposure (eg, a single extra dose in a child) maybe monitored at home.
    6.3.1.3) CONSULT CRITERIA/ORAL
    A) Contact a medical toxicologist or Poison Center for assistance in managing patients with severe toxicity or in whom the diagnosis is unclear. Patients with a deliberate self-harm ingestion should be evaluated by a mental health specialist.
    6.3.1.5) OBSERVATION CRITERIA/ORAL
    A) Patients with significant or deliberate trimethobenzamide overdose should be observed for a least 10 hours after ingestion with continuous cardiac monitoring and serial ECGs. If no dysrhythmias or QT prolongation develop the patient may be discharged following a mental health evaluation as needed.

Monitoring

    A) Monitor vital signs and CNS function (drowsiness is likely). Monitor electrolytes, liver enzymes, kidney function and CPK after a significant overdose.
    B) Obtain a baseline ECG and institute continuous cardiac monitoring after large overdose or in symptomatic patients. QRS and QT prolongation and ventricular dysrhythmias are theoretically possible.
    C) Monitor for hypersensitivity reactions that may develop with parenteral administration.

Oral Exposure

    6.5.1) PREVENTION OF ABSORPTION/PREHOSPITAL
    A) SUMMARY
    1) GI decontamination is not indicated due to the risk of CNS depression (ie, drowsiness, seizures) or cardiac instability.
    6.5.2) PREVENTION OF ABSORPTION
    A) SUMMARY
    1) Consider decontamination even with delayed presentation, since this agent is known to cause decreased gastrointestinal motility.
    B) 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.
    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).
    6.5.3) TREATMENT
    A) SUPPORT
    1) Treatment is symptomatic and supportive.
    B) MONITORING OF PATIENT
    1) Monitor vital signs and CNS function.
    2) Monitor electrolytes, liver enzymes, kidney function and CPK after a significant overdose.
    3) Obtain a baseline ECG and institute continuous cardiac monitoring as indicated. QT prolongation and ventricular dysrhythmias are theoretically possible.
    4) Monitor arterial blood gases as indicated.
    C) 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).
    D) HYPOTENSIVE EPISODE
    1) Initially treat with isotonic IV fluids at 10 to 20 mL/kg. If the patient is unresponsive to these measures, administer dopamine or norepinephrine. Theoretically, norepinephrine may be more effective in counteracting hypotension secondary to trimethobenzamide-induced alpha blockade.
    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).
    E) VENTRICULAR ARRHYTHMIA
    1) PROLONGED QT: Phenothiazine overdose, particularly thioridazine, may produce prolongation of the QT interval, decreased T wave amplitude, and prominent U waves (Ellenhorn & Barceloux, 1988).
    a) Sodium bicarbonate may be effective in reversing QRS widening and treating ventricular dysrhythmias. A reasonable starting dose is 1 to 2 mEq/kg IV bolus repeat as needed. Maintain arterial pH 7.45 to 7.55. Institute continuous cardiac monitoring and follow frequent serial ECGs, serum electrolytes and arterial blood gases. Since phenothiazines produce "quinidine-like" effects on the myocardium, quinidine, procainamide, and disopyramide should be avoided.
    2) VENTRICULAR TACHYCARDIA/FIBRILLATION: Treat with cardioversion, sodium bicarbonate, and lidocaine as needed.
    a) Cardioversion is often required for ventricular tachycardia, and is the initial treatment for ventricular fibrillation, but the arrhythmias are often resistant. A pacing wire may be the only effective treatment, especially if atrioventricular block is present (Burgess et al, 1979).
    b) Fowler et al (1976) recommend that ventricular tachyarrhythmias due to phenothiazine toxicity be managed like quinidine-induced ventricular tachycardia: administration of lidocaine, followed by pacing if needed (Fowler et al, 1976).
    c) Tri & Combs (1975) report a case of thioridazine-induced ventricular tachycardia which initially responded to lidocaine, but subsequently necessitated the use of procainamide (which is not recommended by most authors) and direct current cardioversion (Tri & Combs, 1975).
    d) 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).
    e) 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).
    f) LIDOCAINE/MONITORING PARAMETERS
    1) Monitor ECG continuously; plasma concentrations as indicated (Prod Info Lidocaine HCl intravenous injection solution, 2006).
    F) ATRIOVENTRICULAR BLOCK
    1) If a high grade atrioventricular block develops, attempt external pacing and insert transvenous pacing wire if needed.
    G) TORSADES DE POINTES
    1) There are no reports of torsades de pointes following trimethobenzamide exposure, but it is theoretically possible.
    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.
    H) BODY TEMPERATURE ABOVE REFERENCE RANGE
    1) Hyperpyrexia may occur secondary to a peripheral anticholinergic action of trimethobenzamide (Prod Info Tigan(R), 2001).
    2) Monitor vital signs.
    3) Minimize physical activity. Aggressively control agitation with IV benzodiazepines. Remove the patient's clothes, keep skin damp with tepid to cool water, and use fans to maximize evaporative heat loss.
    4) Place patient on a hypothermia blanket.
    5) Large doses of benzodiazepines may be needed to control neuromuscular hyperactivity. In severe cases sedation, neuromuscular paralysis and orotracheal intubation may be necessary.
    6) Immersion in ice water makes monitoring and resuscitation more difficult. It should be reserved for severe hyperthermia not responding to the above therapies.
    I) DRUG-INDUCED DYSTONIA
    1) ADULT
    a) BENZTROPINE: 1 to 4 mg once or twice daily intravenously or intramuscularly; maximum dose: 6 mg/day; 1 to 2 mg of the injection will usually provide quick relief in emergency situations (Prod Info benztropine mesylate IV, IM injection, 2009).
    b) DIPHENHYDRAMINE: 10 to 50 mg intravenously at a rate not exceeding 25 mg/minute or deep intramuscularly; maximum dose: 100 mg/dose; 400 mg/day (Prod Info diphenhydramine hcl injection, 2006).
    2) CHILDREN
    a) DIPHENHYDRAMINE: 5 mg/kg/day or 150 mg/m(2)/day intravenously divided into 4 doses at a rate not to exceed 25 mg/min, or deep intramuscularly; maximum dose: 300 mg/day. Not recommended in premature infants and neonates (Prod Info diphenhydramine hcl injection, 2006).

Enhanced Elimination

    A) LACK OF INFORMATION
    1) There are no reports of enhanced elimination therapy following a trimethobenzamide overdose.

Abstracts

Case Reports

    A) ADULT
    1) A 50-year-old woman with an unremarkable hepatic history developed acute hepatitis within 6 days of beginning a therapeutic regimen of oral trimethobenzamide hydrochloride. Total dose was 4 g over 6 days; signs included moderate jaundice and epigastric tenderness, dark urine, and anorexia. Hepatic biopsy revealed focal cellular necrosis, centrilobular cholestasis, and inflammatory cell infiltrate (Borda & Jick, 1967).
    B) PEDIATRIC
    1) One case of decerebrate posturing with opisthotonos has been reported in an infant given 900 mg via suppositories in 24 hours. The infant's mother had an extrapyramidal reaction with dystonic posturing a few years earlier after taking perchlorperazine (Holmes & Flaherty, 1976).

Range Of Toxicity

Summary

    A) TOXICITY: A toxic dose has not been established. Overdose events are very limited. An adult survived an overdose of 71 mg/kg. Based on animal studies, the minimum lethal dose would be about 25 mg/kg.
    B) THERAPEUTIC DOSE: ADULT: ORAL: 300 mg capsule taken 3 to 4 times daily as needed; PARENTERAL: 200 mg (2 mL) IM 3 or 4 times daily as needed. PEDIATRIC: ORAL and PARENTERAL is NOT recommended. PRODUCT WITHDRAWAL: RECTAL SUPPOSITORIES: As of 2007, the FDA notified manufacturers to stop producing and distributing trimethobenzamide suppositories due to a lack of evidence of efficacy.

Therapeutic Dose

    7.2.1) ADULT
    A) ROUTE OF ADMINISTRATION
    1) INTRAMUSCULAR: 2 mL (200 mg) 3 or 4 times a day (Prod Info trimethobenzamide HCl intramuscular injection, 2012).
    2) ORAL: 300 mg 3 or 4 times a day (Prod Info Tigan(R) oral capsules, 2011).
    3) PARENTERAL: Usual adult dosage of 200 mg (2 mL) intramuscularly 3 or 4 times daily as needed; a deep injection into the upper outer quadrant of gluteal region is recommended to avoid pain and burning at the site (Prod Info TIGAN(R) oral capsules, IM injection, 2005).
    4) RECTAL: PRODUCT WITHDRAWAL: As of 2007, the FDA notified manufacturers to stop producing and distributing trimethobenzamide suppositories due to a lack of evidence of efficacy. This notification did not affect oral capsules and injectable products containing trimethobenzamide (US Food and Drug Administration, 2007).
    7.2.2) PEDIATRIC
    A) ROUTE OF ADMINISTRATION
    1) INTRAMUSCULAR: Safety and efficacy have not been established in pediatric or adolescent patients (Prod Info trimethobenzamide HCl intramuscular injection, 2012).
    2) ORAL: Safety and efficacy have not been established in pediatric or adolescent patients (Prod Info Tigan(R) oral capsules, 2011).
    3) RECTAL: PRODUCT WITHDRAWAL: As of 2007, the FDA notified manufacturers to stop producing and distributing trimethobenzamide suppositories due to a lack of evidence of efficacy. This notification did not affect oral capsules and injectable products containing trimethobenzamide (US Food and Drug Administration, 2007).

Minimum Lethal Exposure

    A) SUMMARY
    1) Minimum lethal dose, based on animal studies, would be approximately 25 mg/kg (Prod Info, 1977).

Maximum Tolerated Exposure

    A) SUMMARY
    1) Reported maximum survived dose in an adult was 71 mg/kg (Prod Info, 1977).

Serum Plasma Blood Concentrations

    7.5.1) THERAPEUTIC CONCENTRATIONS
    A) THERAPEUTIC CONCENTRATION LEVELS
    1) ROUTE OF ADMINISTRATION
    a) PARENTERAL: In healthy adult subjects, the maximum plasma concentration was approximately 30 minutes after receiving a single 200 mg trimethobenzamide IM injection (Prod Info TIGAN(R) oral capsules, 2007).
    b) ORAL: In healthy adult subjects, the maximum plasma concentration was approximately 15 minutes after receiving a single 300 mg trimethobenzamide oral dose (Prod Info TIGAN(R) oral capsules, 2007).
    2) ADULT
    a) Expected peak trimethobenzamide serum levels in an adult taking 200 mg intramuscularly 3 times daily: 4.5 mcg/mL. Expected peak trimethobenzamide serum levels in an adult taking 250 mg orally 3 times daily: 3.1 mcg/mL (Prod Info, 1977).
    3) PEDIATRIC
    a) Trimethobenzamide levels in the serum of a group of children given one 200 mg suppository an hour previously ranged between 0.38 and 7.88 mcg/mL (mean, 2.12 mcg/mL). Children who failed to retain the suppository for the whole hour had significantly lower levels (mean, 0.58 mcg/mL) than those who had retained the suppository (mean, 2.67 mcg/mL) (Ginsburg & Clahsen, 1980).
    7.5.2) TOXIC CONCENTRATIONS
    A) TOXIC CONCENTRATION LEVELS
    1) CASE REPORTS
    a) ADULT
    1) An adult woman who died of a mixed overdose of diphenhydramine and trimethobenzamide had a blood trimethobenzamide level of 155 mcg/mL (the dose taken was extrapolated to be about 180 mg/kg) (Prod Info, 1977).

Toxicity Information

    7.7.1) TOXICITY VALUES
    A) LD50- (INTRAPERITONEAL)MOUSE:
    1) 350 mg/kg ((RTECS, 2000))
    B) LD50- (ORAL)MOUSE:
    1) 1600 mg/kg ((RTECS, 2000))
    C) LD50- (SUBCUTANEOUS)MOUSE:
    1) 564 mg/kg ((RTECS, 2000))

Pharmacology Toxicology

Pharmacologic Mechanism

    A) The mechanism is not fully understood; however, in animals, trimethobenzamide may act directly and specifically on the chemoreceptor trigger zone in the medulla oblongata by which emetic impulses are passed along to the vomiting center. It does not appear that direct impulses in the vomiting center are similarly inhibited (Prod Info TIGAN(R) oral capsules, IM injection, 2006) (Shalleck et al, 1959).

Toxicologic Mechanism

    A) Trimethobenzamide has anticholinergic action, both central and peripheral, in large doses. It also causes alpha receptor blockade, which leads to cardiovascular signs.

Physicochemical

Physical Characteristics

    A) Trimethobenzamide hydrochloride is a white crystalline powder, with a slight phenolic odor, that is moderately soluble in water, but slightly soluble in alcohol, chloroform, and ether (JEF Reynolds , 2000).

Molecular Weight

    A) 424.93 (Prod Info Tigan(R), trimethobenzamide hydrochloride, 2000)

References

General Bibliography

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    36) 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.
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    40) Product Information: TIGAN(R) oral capsules, IM injection, trimethobenzamide hcl oral capsules, IM injection. Monarch Pharmaceuticals,Inc, Bristol, TN, 2005.
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