FREE NEJM E-TOC    HOME   |   SUBSCRIBE   |   CURRENT ISSUE   |   PAST ISSUES   |   COLLECTIONS   |   Search Term  Advanced Search

Sign in | Get NEJM's E-Mail Table of Contents — Free | Subscribe

Previous Volume 325:1761-1766 December 19, 1991 Number 25 Next

	Add to Personal Archive Add to Citation Manager Notify a Friend E-mail When Cited PubMed Citation

Abstract

BACKGROUND. The nature of the toxic gases that cause death from smoke inhalation is not known. In addition to carbon monoxide, hydrogen cyanide may be responsible, but its role is uncertain, because blood cyanide concentrations are often measured only long after exposure. METHODS. We measured cyanide concentrations in blood samples obtained at the scene of residential fires from 109 fire victims before they received any treatment. We compared the results with those in 114 persons with drug intoxication (40 subjects), carbon monoxide intoxication (29 subjects), or trauma (45 subjects). The metabolic effect of smoke inhalation was assessed by measuring plasma lactate at the time of admission to the hospital in 39 patients who did not have severe burns. RESULTS. The mean (+/-SD) blood cyanide concentrations in the 66 surviving fire victims (21.6 +/- 36.4 mumol per liter, P less than 0.001) and the 43 victims who died (116.4 +/- 89.6 mumol per liter, P less than 0.001) were significantly higher than those in the 114 control subjects (5.0 +/- 5.5 mumol per liter). Among the 43 victims who died, the blood cyanide concentrations were above 40 mumol per liter in 32 (74 percent), and above 100 mumol per liter in 20 of these (46 percent). There was a significant correlation between blood cyanide and carbon monoxide concentrations in the fire victims (P less than 0.001). Plasma lactate concentrations at the time of hospital admission correlated more closely with blood cyanide concentrations than with blood carbon monoxide concentrations. Plasma lactate concentrations above 10 mmol per liter were a sensitive indicator of cyanide intoxication, as defined by the presence of a blood cyanide concentration above 40 mumol per liter. CONCLUSIONS. Residential fires may cause cyanide poisoning. At the time of a patient's hospital admission, an elevated plasma lactate concentration is a useful indicator of cyanide toxicity in fire victims who do not have severe burns.

Source Information

Reanimation Toxicologique, Hopital Fernand Widal, Universite Paris 7, France.

This article has been cited by other articles:

• Shepherd, G., Velez, L. I (2008). Role of Hydroxocobalamin in Acute Cyanide Poisoning. The Annals of Pharmacotherapy 42: 661-669 [Abstract] [Full Text]  
• Baud, F J (2007). Cyanide: critical issues in diagnosis and treatment. Hum Exp Toxicol 26: 191-201 [Abstract]  
• Pham, J. C., Huang, D. T, McGeorge, F. T, Rivers, E. P (2007). Clarification of cyanide's effect on oxygen transport characteristics in a canine model. Emerg. Med. J. 24: 152-156 [Abstract] [Full Text]  
• Geller, R. J., Barthold, C., Saiers, J. A., Hall, A. H. (2006). Pediatric Cyanide Poisoning: Causes, Manifestations, Management, and Unmet Needs. Pediatrics 118: 2146-2158 [Abstract] [Full Text]  
• Chan, G. M. (2006). Carbon monoxide poisoning, myocardial injury, and mortality.. JAMA 295: 2601-2601 [Full Text]  
• Duenas-Laita, A., Burillo Puzte, G., Nogue Xarau, S., Ruiz Mambrilla, M. (2006). Cardiovascular Manifestations of Carbon Monoxide Poisoning. J Am Coll Cardiol 47: 690-691 [Full Text]  
• Cancio, L. C (2005). Current concepts in the pathophysiology and treatment of inhalation injury. Trauma 7: 19-35 [Abstract]  
• Borron, S. W., Megarbane, B., Baud, F. J., Sheridan, R., Schultz, J., Ryan, C. (2004). Case 6-2004: Severe Burns from a Nightclub Fire. NEJM 350: 2314-2314 [Full Text]  
• Newmark, J., Hurst, C. G., Nogue-Xarau, S., Duenas, A., Burillo, G., Kales, S. N., Christiani, D. C. (2004). Acute Chemical Emergencies. NEJM 350: 2102-2104 [Full Text]  
• Kales, S. N., Christiani, D. C. (2004). Acute Chemical Emergencies. NEJM 350: 800-808 [Full Text]  
• Bhattacharya, R, Vijayaraghavan, R (2002). Promising role of a-ketoglutarate in protecting against the lethal effects of cyanide. Hum Exp Toxicol 21: 297-303 [Abstract]  
• Djerad, A., Monier, C., Houze, P., Borron, S. W., Lefauconnier, J.-M., Baud, F. J. (2001). Effects of Respiratory Acidosis and Alkalosis on the Distribution of Cyanide into the Rat Brain. Toxicol Sci 61: 273-282 [Abstract] [Full Text]  
• Houeto, P., Borron, S. W., Marliere, F., Baud, F. J., Levillain, P. (2001). Development of a Method for Measuring Volatile Organic Compounds in the Blood of Fire Victims Using'Purge and Trap' Gas Chromatography. Indoor and Built Environment 10: 62-69 [Abstract]  
• Judkins, K. (2000). Current consensus and controversies in major burns management. Trauma 2: 239-251 [Abstract]  
• Schimmer, M., Bermudez, R. M., Cabrera, C. A., Monafo, W. W. (1997). Treatment of Burns. NEJM 336: 1392-1393 [Full Text]  
• Zhu, P. J. (1997). Adenosine Release Mediates Cyanide-Induced Suppression of CA1 Neuronal Activity. J. Neurosci. 17: 2355-2364 [Abstract] [Full Text]  
• Baud, F. J, Borron, S. W, Bavoux, E., Astier, A., Hoffman, J. R (1996). Relation between plasma lactate and blood cyanide concentrations in acute cyanide poisoning. BMJ 312: 26-27 [Full Text]  
• Locatelli, C., Candura, S. M., Maccarini, D., Butera, R., Manzo, L. (1994). Review : Carbon Monoxide Poisoning in Fire Victims. Indoor and Built Environment 3: 16-21 [Abstract]