Inhalational Poisoning

Inhalational Poisoning Dr. CC Lau

Classification • Simple asphyxiants • Chemical asphyxiants • Pulmonary irritants • Systemic toxicants

Factors • Concentration • Duration of exposure • Environment (enclosed space) • Vapour density • Toxic particle size and solubility • Patient factors • (presence of fire / explosion, thermal unjuries)

Oxygen • Essential for cellular respiration • “Oxygenation” affected by • Respiration suppression (opioids) • “Dilution” of oxygen in air • Simple asphyxiants (no direct toxic effect) • Interfere with gas exchange • Pulmonary irritants • Systemic toxic effects • affect oxygen binding to Hb (CO, Met-Hb) • Interfere with cellular respiration (Chemical asphyxiants, CN, CO, H2S)

Simple Asphyxiants • Pathophysiology • Displace oxygen >> lowering FiO2 • Not irritating and no direct systemic toxic effect • Clinical effects due to HYPOXIA

Clinical Findings Goldfrank’s Toxicologic Emergencies, 6th Edition

Simple Asphyxiants • Carbon dioxide • Fire accident, dry ice, fire extinguishers, refrigerant • Nitrogen • Chromatography, fertilizer, cryogenic agent, scuba diving • Noble Gases • Welding operations, lasers, illumination

Simple Asphyxiants • Hydrocarbon Gases • Methane • Natural gas, marsh gas, fire damp • Ethane • Natural gas, refrigerant • Propane • Fuel, solvent • Butane • Fuel, solvent

Cameroon Lake Nyos

Nearly 2,000 people perished down slope of LAKE NYOS in August, 1986, when a large volume of poisonous gas was suddenly released from the lake late one evening. People simply "went to sleep" that night, and few ever awoke. • Lake Nyos was a young volcanic maar, and that carbon dioxide of volcanic origin had been released from solution in the lake's waters. • CO2 is continuing to be supplied to the lake, and that other gas-release events are inevitable in the future. Permanent habitations in vulnerable areas down slope is now prohibited.

Treatment for Simple Asphyxiants • 100% oxygen • Remove from exposure • ABCs and supportive care • Rapid resolution of symptoms unless end-organ damage has occurred

Pulmonary Irritants • Direct toxic effect on the respiratory tract • Most severe - Acute Lung Injury (ALI) • Characterized by pulmonary inflammation and alveolar filling

Pulmonary Irritants • Pathophysiology • As simple asphyxiants (at high concentration) • Direct local effects on mucosal surface

Pulmonary Irritants • Site and onset of injury depends upon particle size and solubility (those with smaller particle size and low solubility can pass to more distal airways) • High solubility • Upper airway • Eyes • Nose • Low solubility • Lower respiratory tract

Pulmonary Irritants

Ammonia (NH3) Plastics, explosives, fertilizer, cleaning agent Hydrogen Chloride Pyrolysis of PVCs Commercial chemicals Sulphur Dioxide By-product found in smelting and oil refining Smog Dose-related bronchospasm Pulmonary Irritants - Examples

Pulmonary Irritants - Clinical Effects • High water solubility gases • Rapidly irritating • Upper airways and eyes affected • Glottic inflammation may compromise airway • Prolonged exposure can result in bronchial/pulmonary effects

Pulmonary Irritants - Clinical Effects • Intermediate water solubility gases • Delay to irritation concentration dependent • Low concentration or less irritating agents affect lower airways • May be delayed to ALI

Pulmonary Irritants - Examples • Chlorine (Cl2) • Oxidizing agent; many industrial uses • Chemical warfare gas WWI • Swimming pool tablets; water treatment, compressed gas for direct chlorination of pool • Intermediate water solubility • HCl + HOCl >> ocular and upper airway irritation >> coughing, hoarseness, pulmonary oedema

Pulmonary Irritants - Examples • Phosgene (COCl2) • Weapon of mass destruction WWI • Pleasant odor >> promote deep and prolonged breathing • Relatively water insoluble • Dissolution >> liberation of hydrochloric acid and reactive oxygen species • DELAYED onset of ALI, may be nearly a day

Pulmonary Irritants – Clinical Effects • Low water solubility gases • Generally non-irritating • Exposure often prolonged resulting in pulmonary effects • May have pleasant smell • Bronchospasm • Delayed ALI • Bronchiolitis obliterans (BOOP)

Nitrogen Dioxide • Silo filler’s disease • Inhalation due to accumulation of nitrogen dioxide from bacterial conversion of nitrates from fresh grains • Limited water solubility >> lower airway problem, slow conversion of nitrogen oxide to nitric acid in alveoli >> delayed alveolar injury • High conc. may lead to acute symptoms • “triphasic illness” • Delayed – bronciolitis obliterans

Pulmonary Irritants - Treatment • General management • Remove from exposure • ABCs and supportive care; oxygen • -agonists • No role for steroids (except for bronchiolitis obliterans)

Pulmonary Irritants - Treatment • Specific management • Aerosolized bicarbonate (2% solution) • Nebulized sodium bicarbonate for chlorine exposure • 1 part NaHCO3:3 parts water/saline • May also work for hydrogen chloride • Reduces symptoms; no data on outcome Chisolm CD. Ann Emerg Med, 1989;18:466

Pulmonary Irritants - Treatment • Observation • No delayed toxicity from highly water soluble agents • Observe for durations of symptoms • Decreased solubility increases risk of ALI; onset may be delayed. • Admit for 24 hours / patient instructions • arrange follow-up (bronchiolitis obliterans)

Simple vs Chemical Asphyxiants • All gases can act as simple asphyxiants • Chemical asphyxiants interfere with oxygen utilization by the body • Carbon monoxide • Hydrogen sulphide (H2S) • Cyanide

Carbon Monoxide

Carbon monoxide • Epidemiology - Leading cause of poisoning morbidity & mortality in US - Between 50 and 5000 deaths reported annually - about 1/2 suicides - about 1/3 are fire victims

Sources of CO • Incomplete combustion of any carbonaceous material - Fires, particularly coal and wood

Other Sources of CO • Methylene chloride - Found in paint and varnish removers - Metabolized to CO in the liver - Toxicity may be delayed 4-8 hours after exposure

Risk factors for CO toxicity • Extremes of age • Pregnant women (fetus) • Pre-existing coronary artery disease

Kinetics • Rapidly absorbed across alveolar membranes • Binds hemoglobin (Hb) with approximately 250 times greater affinity than oxygen • T1/2

Pathophysiology • Carboxyhemoglobin (COHb) does not carry oxygen   O2 content in blood • Binding to myoglobin  impaired O2 extraction  myocardial & skeletal muscle hypoxia • Induces lipid peroxidation in CNS neurological sequelae *

Glycolysis (cytosol) Glucose ADP+ NAD+ ATP NADH NADH NAD+ Lactate Pyruvate Pyruvate dehydrogenase complex Cori Cycle I III IV Acetyl-CoA Q Cyto C CoA-SH NADH O2 H2O NADH NAD+ NAD++ Electron Transport Chain (inner mitochondrial membrane) Inhibited by CO, CN, H2S Kreb’s Cycle (mitochondrial matrix) FADH2 NAD++ FADH NADH Impaired by hypoxemia ATP NADH NAD++

Lipid peroxidation in the CNS

Clinical Presentation • Acute symptoms are due to tissue hypoxia: heart and brain most affected - CNS: headache, dizziness, blurry vision, altered mental status, ataxia, seizures, coma - CVS: exertional dyspnea,  HR,  RR, hypotension, palpitations, angina, weakness, dysrhythmias, myocardial ischemia

Clinical Presentation • Renal: acute renal failure • Musculoskeletal: rhabdomyolysis • Ocular: venous engorgement, rarely blindness • Dermal: bullae; cherry-red color (seen with severe exposure, generally after patient expires)

Normal: 1-2%; higher in smokersPoor correlation with symptoms (expecially chronic exposure)Do not predict development of delayed sequelae COHb levels

Outcome • 12% persistent CNS signs or symptoms • 12% delayed neurologic sequelae (overall) • 25% in severe patients • 2% death

Delayed Neurologic Sequelae • Deterioration after lucid period of 2 days to 4 weeks (mean 15 days) • Elderly appear to be most susceptible • Most cases associated with LOC during acute phase • Characterized by: dementia, amnesia, apathy, hypokinesia, ataxia, tremor, memory impairment, parkinsonism

Prognosis of Delay Neurologic Symptoms • Mild symptoms: • almost 100% resolution within 2 months • Severe symptoms: • 75% resolution within 1 yr • Mean 3-6 months

Management • Remove from exposure; ABC’s • 100% O2 by non-breather mask • Check COHb level • Assess for evidence of end organ damage • Pregnancy test • Hyperbaric oxygen if indicated

Reasons for HBO • COHb half-life • Displaces CO from myoglobin and cytochrome oxidase •  O2 content of blood and improves O2 delivery •  lipid peroxidation • Improved neurological outcome

HBO Therapy • Goulon et al, Paris, 1962-69 • For CO and anoxia from coal gas • Experience with 302 patients Rx with HBO • HBO within 6 hrs: 13.5% mortality • HBO greater than 6 hrs: 30.1% mortality Goulon M, J Hyperbaric Med 1986;1:23

HBO Randomized Clinical Trials Mild toxicity n= 65 Thom 1995 Weaver 2002 Raphael 1989 Mathieu 1996 Scheinkestel 1999 All, n= 150 All, n =629 Non-comatose, n - 299 All, n = 191 0.1 0.25 0.5 1 2 4 Benefit harm

Randomized-controlled, double-blinded trials

Hyperbaric Oxygen (HBO) • Indications 1) End organ damage - syncope, coma, seizures - myocardial ischemia or life-threatening dysrhythmia - persistent symptoms after treatment with normobaric O2

Recommendations for HBO 2) COHb levels (regardless of symptoms) - > 25% - > 15% in pregnant woman Fetus • Fetal Hgb  affinity for CO • Lower PO2 3) Other considerations - abnormal neuropsychiatric exam - metabolic acidosis - inability to oxygenate

Inhalational Poisoning

Inhalational Poisoning

Presentation Transcript

Poisoning

Inhalational agents

POISONING

Inhalational Poisoning

Inhalational Injury and Airway Management

Poisoning

Poisoning

Poisoning

Inhalational Injuries

Poisoning

Poisoning

Inhalational Injuries

Poisoning

Poisoning

Poisoning

Poisoning

POISONING

poisoning