Zinc phosphide poisoning
Background
- Zinc phosphide (Zn₃P₂) poisoning is a potentially lethal toxicity caused by ingestion of a widely available rodenticide.
- Upon contact with gastric acid, zinc phosphide is hydrolyzed into phosphine gas (PH₃), which inhibits mitochondrial cytochrome C oxidase and causes multiorgan cellular hypoxia and death.[1] There is no specific antidote; mortality ranges from 37-100% in severe cases.[2]
- Zinc phosphide is a dark gray/black crystalline powder used as a rodenticide against mice, rats, gophers, and squirrels
- Registered for pesticide use in the United States since 1947; widely available in developing countries[3]
- Most cases of significant poisoning are intentional (self-harm) in adults, particularly in the Indian subcontinent, Iran, Thailand, and Mexico[4]
- Accidental ingestion occurs in children (attracted to bait formulations) and through contaminated food
- Toxic dose: symptoms may occur with >40 mg/dose; lethal dose estimated at 4-5 g in adults (approximately 40-80 mg/kg)[5]
Mechanism of toxicity
- Zinc phosphide reacts with gastric HCl → liberates phosphine gas (PH₃)
- Gastric acid and recent food intake accelerate phosphine release
- An empty stomach may delay symptom onset up to 12 hours[3]
- Phosphine is absorbed through the GI tract and lungs → distributed to liver, kidneys, heart, brain, and adrenals
- Phosphine inhibits cytochrome C oxidase (complex IV of mitochondrial electron transport chain) → disrupts oxidative phosphorylation → cellular anoxia[1]
- Additionally causes direct oxidative stress with lipid peroxidation, glutathione depletion, and free radical formation
- Primary target organs: heart (most common cause of early death), lungs, liver, kidneys
- Zinc phosphide is radiopaque on abdominal radiography due to its zinc component[6]
Healthcare worker safety
- Phosphine gas may be released from the patient's vomitus and gastric contents — this is hazardous to healthcare workers[3]
- Treat in a well-ventilated area or negative-pressure room
- Use appropriate personal protective equipment
- Gastric lavage effluent should be handled as hazardous material
Clinical features
- Onset of systemic symptoms is typically delayed compared to aluminum phosphide (hours to >12 hours post-ingestion)[4]
- Patients may be initially asymptomatic and then deteriorate suddenly — including sudden cardiac arrest in asymptomatic patients[7]
Gastrointestinal (earliest)
- Nausea, vomiting (may have garlic/fishy odor), retching
- Epigastric and abdominal pain
- Diarrhea (may be bloody)
- Hematemesis
Cardiovascular (most common cause of death)
- Hypotension, circulatory collapse, refractory shock
- Myocarditis, pericarditis
- Cardiac dysrhythmias (most common terminal event)
- Acute pulmonary edema
- Congestive heart failure
Respiratory
- Dyspnea, tachypnea, cyanosis
- Acute pulmonary edema (cardiogenic and non-cardiogenic)
- ARDS
- Respiratory failure
Metabolic
- Severe metabolic acidosis (high anion gap; elevated lactate) — correlates with severity[4]
- Hyperkalemia, hyponatremia, hypocalcemia, hypomagnesemia
- Hypoglycemia (poor prognostic indicator)
Hepatic
- Hepatocellular injury (elevated AST, ALT)
- Acute hepatic failure — may progress over the first week[8]
- Coagulopathy
Renal
- Acute kidney injury
- Oliguria/anuria
Neurologic
- Headache, dizziness, agitation, restlessness
- Altered mental status, delirium
- Seizures, coma
Hematologic
- Methemoglobinemia (less common than in aluminum phosphide poisoning)
- Intravascular hemolysis (rare)
- DIC
Differential diagnosis
- Aluminum phosphide poisoning (more rapidly fatal; similar mechanism)
- Organophosphate poisoning
- Iron toxicity
- Arsenic poisoning
- Caustic ingestion
- Mushroom poisoning (amatoxin — for hepatic failure presentation)
- Copper sulfate toxicity
- Acetaminophen toxicity (for isolated hepatic failure)
- Myocardial infarction or myocarditis (other causes)
- Septic shock
Toxic gas exposure
- Carbon monoxide toxicity
- Chemical weapons
- Cyanide toxicity
- Dichloromethane toxicity
- Hydrocarbon toxicity
- Hydrogen sulfide toxicity
- Inhalant abuse
- Methane toxicity
- Smoke inhalation injury
- Ethylene dibromide toxicity
Evaluation
Workup
- Abdominal radiograph — zinc phosphide is radiopaque; positive X-ray is an indication for aggressive GI decontamination and portends worse prognosis[6]
- Serial abdominal X-rays to confirm complete decontamination
- ABG/VBG — metabolic acidosis with elevated lactate is the earliest and most sensitive marker of systemic toxicity; severity correlates with prognosis[4]
- CBC, BMP, hepatic function panel, coagulation studies (PT/INR), lipase
- Cardiac biomarkers (troponin, BNP) — myocardial injury monitoring
- ECG — continuous monitoring for dysrhythmias; sinus tachycardia is common; may progress to fatal rhythm
- Blood glucose — hypoglycemia is a poor prognostic indicator
- Serum magnesium, calcium, phosphorus
- Methemoglobin level (co-oximetry)
- CK — for rhabdomyolysis
- Chest radiograph — for pulmonary edema, ARDS
- Salicylate, acetaminophen, ethanol levels — if intentional ingestion
- Phosphine levels are not routinely available or clinically useful in acute management
- Echocardiography — to assess myocardial function if hemodynamically unstable
Diagnosis
- Clinical: history of rodenticide ingestion + GI symptoms + metabolic acidosis + cardiovascular collapse
- Radiopaque material on abdominal X-ray in the setting of rodenticide ingestion is highly suggestive
- Garlic or decaying fish odor to breath/vomitus is a classic but unreliable finding
- Patients with positive abdominal X-ray are at higher risk for sudden deterioration even if asymptomatic[6]
Management
No specific antidote exists. Treatment is supportive with GI decontamination and organ support.[1]
GI decontamination
- Gastric lavage with coconut oil (200 mL) + sodium bicarbonate (NaHCO₃ 7.5%, 50 mL):[1]
- Coconut oil forms a protective mucosal layer and may reduce phosphine liberation
- Bicarbonate decreases gastric acid–driven conversion of phosphide to phosphine
- Do NOT use water for lavage — water promotes phosphine gas formation
- Alternative lavage solutions: potassium permanganate (1:10,000), liquid paraffin, or olive oil
- Activated charcoal (50 g) — may reduce absorption; administer after lavage[4]
- Whole-bowel irrigation with polyethylene glycol (PEG) — if radiopaque material visible beyond the stomach on X-ray
- Some authors caution that PEG's water base could promote phosphine release; castor oil is an alternative for bowel evacuation[9]
- Repeat abdominal X-rays to confirm clearance of all radiopaque material
Cardiovascular support
- Aggressive IV fluid resuscitation
- Vasopressors (norepinephrine, dopamine) for refractory hypotension
- Continuous cardiac monitoring (sudden cardiac arrest may occur in asymptomatic patients)[7]
- Hyperinsulinemia-euglycemia therapy (HIE): case reports suggest benefit in refractory cardiogenic shock[1]
- Insulin loading dose 1 IU/kg/h, maintenance 1-7 IU/kg/h; dextrose infusion to maintain euglycemia
- Intravenous lipid emulsion (ILE) — case reports of use for refractory shock; mechanism unclear[1]
Magnesium sulfate
- IV magnesium sulfate — membrane stabilizer and antioxidant; case-control studies suggest mortality reduction >50%[1]
- Multiple regimens described; one common protocol: 1 g/hour for 24 hours, then 1 g every 6 hours for 5-7 days
- Monitor serum magnesium; avoid toxicity (loss of deep tendon reflexes, respiratory depression)
Antioxidant therapy
- N-acetylcysteine (NAC): loading dose 140 mg/kg, maintenance 70 mg/kg for 17 doses — hepatoprotective, replenishes glutathione[1]
- Vitamin C: 1 g IV q8h for the first 24 hours (antioxidant; limited evidence)
- Vitamin E: 100 IU q12h for 72 hours (antioxidant; limited evidence)
- Alpha-lipoic acid: iron chelation and antioxidant properties; case report of use in combination therapy[10]
Metabolic acidosis
- Correct with IV sodium bicarbonate as needed
- Refractory acidosis is a poor prognostic sign
- Treat underlying cause (tissue hypoperfusion)
Organ failure management
- Hepatic failure: supportive; vitamin K, FFP for coagulopathy; liver transplant if fulminant[8]
- Acute kidney injury: hemodialysis for standard indications (uremia, hyperkalemia, volume overload, refractory acidosis)
- Hemodialysis does not effectively remove phosphine
- Methemoglobinemia: Methylene blue 1-2 mg/kg IV if symptomatic
- Intubation and mechanical ventilation for respiratory failure/pulmonary edema
Disposition
- All patients with confirmed or suspected zinc phosphide ingestion must be admitted — even if initially asymptomatic[7]
- ICU admission for all significant ingestions — continuous cardiac monitoring is mandatory
- Monitoring period: minimum 72 hours; risk of cardiovascular collapse greatest in first 24-48 hours but delayed hepatic failure may occur through the first week[8]
- Serial ABGs, LFTs, coagulation studies, renal function, and ECGs every 6-12 hours
- Serial abdominal X-rays until all radiopaque material has cleared
- Prognosis is worse with:[4]
- Large ingested volume
- Delayed presentation to hospital
- Metabolic acidosis or elevated lactate at presentation
- Hypotension, tachycardia, or tachypnea on arrival
- Hyperkalemia, hypoglycemia
- Acute kidney injury, need for vasopressors or intubation
- All intentional ingestions: psychiatric evaluation mandatory prior to discharge
- Contact Poison control (1-800-222-1222 in the US) for all cases
Medication Dosing
N-Acetylcysteine 140mg/kg PO loading dose, then 70mg/kg q4hr x 17 doses PO Magnesium sulfate 1g/hr IV x 24hr, then 1g q6hr x 5-7 days IV
See Also
- Aluminum phosphide poisoning
- Organophosphate poisoning
- Caustic ingestion
- Mushroom poisoning
- Iron toxicity
- Copper sulfate toxicity
- Methemoglobinemia
- Acute kidney injury
- Acute liver failure
External Links
- Toxics — Zinc Phosphide Poisoning: From A to Z (2023)
- Case Rep Crit Care — Zinc Phosphide Poisoning (2014)
- Ther Clin Risk Manag — Clinical characteristics of zinc phosphide poisoning in Thailand (2017)
- Indian J Crit Care Med — Successful management of zinc phosphide poisoning (2016)
- NPIC — Zinc Phosphide Fact Sheet
References
- ↑ 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 Arroyo-Arcos CR, et al. Zinc Phosphide Poisoning: From A to Z. Toxics. 2023;11(7):555. doi:10.3390/toxics11070555
- ↑ Dogan E, Güzel A, Ciftçi T, et al. Zinc Phosphide Poisoning. Case Rep Crit Care. 2014;2014:589712. doi:10.1155/2014/589712
- ↑ 3.0 3.1 3.2 Zinc Phosphide Technical Fact Sheet. National Pesticide Information Center (NPIC). Oregon State University.
- ↑ 4.0 4.1 4.2 4.3 4.4 4.5 Trakulsrichai S, et al. Clinical characteristics of zinc phosphide poisoning in Thailand. Ther Clin Risk Manag. 2017;13:335-340. doi:10.2147/TCRM.S129610
- ↑ Proudfoot AT. Aluminium and zinc phosphide poisoning. Clin Toxicol (Phila). 2009;47(2):89-100. doi:10.1080/15563650802016425
- ↑ 6.0 6.1 6.2 Hassanian-Moghaddam H, Shahnazi M, Zamani N, Bahrami-Motlagh H. Abdominal imaging in zinc phosphide poisoning. Emerg Radiol. 2014;21(3):329-331. doi:10.1007/s10140-014-1195-3
- ↑ 7.0 7.1 7.2 Parhizgar P, et al. Sudden Cardiac Arrest in an Asymptomatic Zinc Phosphide-Poisoned Patient: A Case Report. Cardiovasc Toxicol. 2020;20(5):525-530. doi:10.1007/s12012-020-09578-2
- ↑ 8.0 8.1 8.2 Saraf V, et al. Acute liver failure due to zinc phosphide containing rodenticide poisoning: clinical features and prognostic indicators of need for liver transplantation. Indian J Gastroenterol. 2015;34(4):325-329. doi:10.1007/s12664-015-0583-2
- ↑ Shakoori V, et al. Successful management of zinc phosphide poisoning. Indian J Crit Care Med. 2016;20(6):368-370. doi:10.4103/0972-5229.183907
- ↑ Takacs A, et al. Successful management of zinc phosphide poisoning — a Hungarian case. Int J Emerg Med. 2020;13:51. doi:10.1186/s12245-020-00307-8