Carbon monoxide toxicity

Background

• Colorless, odorless gas
• Most toxic component in smoke inhalation and major contributor to fire-related deaths
  • Can co-occur with Cyanide toxicity in industrial fires
• Case fatality rate as high as 30%^[1]
• Peak incidence in winter months for unintentional exposure

References

Formed from incomplete combustion of hydrocarbons

• Automotive exhaust
• Propane-fueled heaters
• Wood or coal-burning heaters
• Structure fires
• Gasoline-powered motors
• Natural gas-powered heaters

Pathophysiology

• Hypoxia
  • Binding affinity of hemoglobin for CO (carboxyhemoglobin) is 200x that of O2
  • Half-Life
    • Room air: ~5hrs
    • 100% O2: ~1hr
    • HBO 2.5atm: 24min
• Lactic acidosis
  • CO inhibits oxidative phosphorylation
• Hypotension
  • CO induces NO2 and guanylate cyclase release → vasodilation release
  • CO binds to myoglobin and alters its function
• CO damage at cellular level due to reactive oxygen species, lipid peroxidation, and cellular apoptosis
  • Occurs in CNS and leads to neurological sequela

Clinical Features

Clinical features of CO toxicity

• May range from "flu-like" symptoms to coma
• CNS
  • Headache
  • Visual disturbances
  • Confusion
  • Ataxia
  • Seizure
  • Syncope
  • Retinal hemorrhage
  • Focal neurologic deficit
  • Coma
• GI
  • Vomiting
• Pulm
  • Dyspnea/tachypnea
• Cardio
  • Chest pain
  • ECG changes/dysrhythmias
• Derm
  • Bullous skin lesions
  • Classic finding of cherry red oral mucosa is rarely seen in living patients
    • More likely seen in > 25% COhemoglobin levels

Expected CNS Function by COhemoglobin%

Symptoms By Frequency^[2]

Delayed Neurological Sequela^[3]

• Can occur days to weeks after apparent resolution of acute symptoms in up to 46% of patients. The globus pallidus is the most commonly affected area.
• Persistent, disabling, or permanent
• Includes:
  • Cognitive effects
  • Motor disturbances
  • Ataxia
  • Neuropathies
  • Psychosis
  • Dementia

Differential Diagnosis

A "great mimicker" due to the presentation of poisoning being diverse and nonspecific

• Viral syndrome
• Depression
• Chronic fatigue syndrome
• Chest pain
• Other headache
• ARDS
• Acute mountain sickness
• Lactic acidosis
• Diabetic ketoacidosis
• Meningitis
• Methemoglobinemia
• Opioid or toxic alcohol poisoning
• Inhalation exposure

Further Considerations

• Carbon Monoxide Toxicity
• Cyanide Toxicity
• Hydrocarbons Toxicity
• Smoke Inhalation Injury
• Hydrogen Sulfide

Burns

• Burn
  • First degree
  • Second degree
  • Third degree
  • Fourth degree
• Smoke inhalation injury (airway compromise)
• Chemical injury
  • Acrolein
  • Hydrochloric acid
  • Tuolene diisocyanate
  • Nitrogen dioxide
• Systemic chemical injury
  • Carbon monoxide toxicity
  • Cyanide toxicity
• Electrical injury

Evaluation

• Must have high clinical suspicion (esp in coma, altered mental status, or anion gap acidosis)
  • Comatose patients removed from fire should be assumed to have CO poisoning
• Carboxyhemoglobin Level
  • Interpretation must take into account time since exposure and O2 treatment
  • Normal value in non-smokers is ~1%, normal value in smokers may be up to 10%
  • Symptoms and COhemoglobin levels do not always correlate well
• Pulse oximetry is unreliable
  • COhemoglobin registers the same as O2hemoglobin so will have artificially high SpO2
  • O2 saturation gap reflects discordance of SpO2 by pulse oximeter vs by VBG

Workup

• VBG (ABGs are no longer considered necessary^[4] as venous and arterial COHg levels will be within ±2%^[5])
  • CO-oximetry analysis will provide carboxyhemoglobin level
  • pH will be low secondary to metabolic acidosis caused by anaerobic metabolism and elevated lactate levels
• Pulse CO-oximetry
  • Special pulse CO-ox can accurately determine CO level^[6]
• Lactate
• Chemistry
• Troponin
• Total CK (rhabdomyolysis)
• bHCG
• ECG
  • May range from normal to STEMI (most common ST/T changes, then prolonged QT)
    • Few of the patients with AMI from CO have occlusive lesions in their arteries
• Head CT
  • Identified radiographically within 12 hours of exposure
  • Bilateral hypodense lesions in the basal ganglia: globus pallidus, putamen, and caudate nuclei^[7]

Management

General Mangement

• If smoke inhalation, good pulmonary toilet is very important
• NEVER use steroids in smoke inhalation injury; intubate early if concern for obstructing edema
• O2 100% by NRB or ETT
  • Provide O2 until COhemoglobin value <10%
  • Early PEEP prevents progressive atelectasis and improves O2 diffusion
  • In general, COhemoglobin levels fall rapidly to < 10% within 30 min of 100% O2
  • Maintain 100% O2 for additional 2-3 hrs after < 10%, since anaerobic Cometabolism is occuring due to cytochrome oxidase poisoning^[8]
    • Anaerobic metabolism universally seen with COhemoglobin > 40%
    • Monitor for return of aerobic metabolism with normal serum bicarbonate levels
• Consider other combustion products such as Cyanide

Hyperbaric Therapy (HBO)

• Decision to initiate HBO should be made in consultation with a hyperbaric specialist
• There is controversy regarding benefit^[9][10]
  • Three HBO treatments within 24hrs shown to reduce risk of cognitive sequelae 6 weeks and 12 months after CO poisoning^[11]
  • However, another study showed no benefit and suggested worse outcomes in HBO therapy^[12]
• Patient must be stable prior to transport since response to acute medical conditions while undergoing hyperbaric therapy in a chamber is difficult.
• Indications (generally accepted guidelines): ^[13]
  • Syncope
  • Confusion/altered mental status
  • Seizure
  • Coma
  • Focal neuro deficit
  • Pregnancy with Cohemoglobin level >15%
    • Fetal Hb tends to bind more CO
  • Blood level >25%
  • Acute myocardial ischemia

Disposition

Minimal or no symptoms

• Discharge
  • If discharging patient- may need to alert local fire/police services to evaluate home/work before they return. Check with your local branch.
  • Patient's should not be discharged to an environment where they will become toxic again

Mildly symptomatic

• Headache, vomiting, elevated COhemoglobin level
• Discharge after 4hr obs and symptom resolution and assurance that the discharge environment is safe

Severely symptomatic

• Ataxia, syncope, chest pain, focal neuro deficit, dyspnea, ECG changes, pregnant with COhemoglobin >15%
• Admit; discuss with hyperbaric specialist

See Also

• Toxidromes
• Burns
• Cyanide

References

1. ↑ Nikkanen H, Skolnik A. Diagnosis and management of carbon monoxide poisoning in the emergency department. Emerg Med Practice 2011;13(2):1-14.
2. ↑ Lavonas EJ. Carbon monoxide poisoning. In: Shannon M, Borron S, Burns M, eds. Haddad and Winchester’s Clinical Management of Poisoning and Drug Overdose. Philadelphia, Pa: Elsevier; 2007:1297-1307.
3. ↑ Nikkanen H, Skolnik A. Diagnosis and management of carbon monoxide poisoning in the emergency department. Emerg Med Practice 2011;13(2):1-14.
4. ↑ Lopez DM, et al. Relationship between arterial, mixed venous, and internal jugular carboxyhemoglobin concentrations at low, medium, and high concentrations in a piglet model of carbon monoxide toxicity. Crit Care Med. 2000; 28(6):1998-2001.
5. ↑ Touger M. et al. Relationship between venous and arterial carboxyhemoglobin levels in patients with suspected carbon monoxide poisoning. Ann Emerg Med 1995;33:105-109.
6. ↑ Coulange M, et al. Reliability of new pulse CO-oximeter in victims of carbon monoxide poisoning. Undersea Hyperb Med. 2008; 35(2):107-111.
7. ↑ Lee, DC: Hydrocarbons, in Marx JA, Hockberger RS, Walls RM, et al (eds): Rosen’s Emergency Medicine: Concepts and Clinical Practice, ed 7. St. Louis, Mosby, Inc., 2010, (Ch) 156:p 2035-2038
8. ↑ MetroHealth Medical Center Burn ICU Handbook (Not a policy manual), Cleveland, OH
9. ↑ ../docss/1083.pdf
10. ↑ Juurlink, D. N., Isbister, G., Bennett, M. H. and Lavonas, E. J. (1996) ‘Hyperbaric oxygen for carbon monoxide poisoning’, Cochrane Database of Systematic Reviews
11. ↑ Weaver, L. et al. Hyperbaric Oxygen For Acute Carbon Monoxide Poisoning. NEJM. 2002:347(14):1057 http://emed.wustl.edu/Portals/2/Answer%20Key%20PDF/2012/January2012/SecondYear.pdf
12. ↑ Scheinkestel C. et al. Med J Aust 1999; 170 (5): 203-210. Hyperbaric or normobaric oxygen for acute carbon monoxide poisoning: a randomised controlled clinical trial http://www.mja.com.au/journal/1999/170/5/hyperbaric-or-normobaric-oxygen-acute-carbon-monoxide-poisoning-randomised
13. ↑ Practice Recommendations in the Diagnosis, Management and Prevention of Carbon Monoxide Poisoning. Hampson NB et al. Am J Respir Crit Care Med 2012 Oct 18