Development of an Acute, Short-term Exposure Model for Phosgene

Overview

Journal Toxicol Mech Methods

Publisher Informa Healthcare

Specialty Toxicology

Date 2019 Jun 26

PMID 31237465

Citations 2

Authors

Stephen T Hobson

Robert P Casillas

Richard A Richieri

Robert N Nishimura

Richard H Weisbart

Rick Tuttle

Glenn T Reynolds

Missag H Parseghian

Affiliations

Soon will be listed here.

Abstract

Phosgene is classified as a chemical warfare agent, yet data on its short-duration high concentration toxicity in a nose-only exposure rat model is sparse and inconsistent. Hence, an exposure system for short-term/high concentration exposure was developed and characterized. Herein, we report the median lethal concentration (LC) for a 10-min nasal exposure of phosgene in a 24-h rat survival model. Male Wistar rats (Envigo) weighing 180-210 g on the day of exposure, were exposed to phosgene gas via nose-only inhalation using a system specifically designed to allow the simultaneous exposure and quantification of phosgene. After 24 h, the surviving rats were euthanized, the lung/body mass ratio determined, and lung tissues analyzed for histopathology. Increased terminal airway edema in the lungs located primarily at the alveoli (resulting in an increased lung/body mass ratio) coincided with the observed mortality. An LC value of 129.2 mg/m for a 10-min exposure was determined. Furthermore, in agreement with other highly toxic compounds, this study reveals a LC concentration value supportive of a nonlinear toxic load model, where the toxic load exponent is >1 ( = 1.17). Thus, in line with other chemical warfare agents, phosgene toxicity is predicted to be more severe with short-duration, high-concentration exposures than long-duration, low-concentration exposures. This model is anticipated to be refined and developed to screen novel therapeutics against relevant short-term high concentration phosgene exposures expected from a terrorist attack, battlefield deployment, or industrial accident.

Citing Articles

Special issue: emerging chemical terrorism threats.

Casillas R, Tewari-Singh N, Gray J Toxicol Mech Methods. 2021; 31(4):239-241.

PMID: 33730980 PMC: 10728888. DOI: 10.1080/15376516.2021.1904472.

The Strategic National Stockpile: identification, support, and acquisition of medical countermeasures for CBRN incidents.

Neumeister S, Gray J Toxicol Mech Methods. 2020; 31(4):308-321.

PMID: 33208007 PMC: 10754051. DOI: 10.1080/15376516.2020.1853294.

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