Incapacitating and irritating agents produce temporary disability persisting for hours to days after the exposure. One can be exposed to these agents occupationally in industrial or other working environments. Also general public can be exposed in special circumstances, like industrial accidents or riots. Incapacitating and irritating agents discussed in this review are chloropicrin and capsaicinoids. In addition, we include sulfur mustard, which is an old chemical warfare agent and known to cause severe long-lasting injuries or even death. Chloropicrin that was used as a warfare agent in the World War I is currently used mainly as a pesticide. Capsaicinoids, components of hot pepper plants, are used by police and other law enforcement personnel as riot control agents. Toxicity of these chemicals is associated particularly with the respiratory tract, eyes, and skin. Their acute effects are relatively well known but the knowledge of putative long-term effects is almost non-existent. Also, mechanisms of effects at cellular level are not fully understood. There is a need for further research to get better idea of health risks, particularly of long-term and low-level exposures to these chemicals. For this, exposure biomarkers are essential. Validated exposure biomarkers for capsaicinoids, chloropicrin, and sulfur mustard do not exist so far. Metabolites and macromolecular adducts have been suggested biomarkers for sulfur mustard and these can already be measured qualitatively, but quantitative biomarkers await further development and validation. The purpose of this review is, based on the existing mechanistic and toxicokinetic information, to shed light on the possibilities for developing biomarkers for exposure biomonitoring of these compounds. It is also of interest to find ideas for early effect biomarkers considering the need for studies on subchronic and chronic toxicity.
The acute toxicity and the genotoxicity of four colored smokes were studied by an in vitro method based on the exposure of human bronchial epithelial cell cultures to the smokes. All smoke formulations consisted of the oxidizer fuel mixture (potassium chlorate/lactose), talcum and the following dyes: 1,4‐dihydroxy anthraquinone (orange), 1‐(p‐tolylamino)‐4‐hydroxy anthraquinone (violet), 1‐methylamino anthraquinone (red) and 4,4′‐methylidyne‐bis‐3‐methyl‐1‐phenyl‐2‐pyrazolin‐5‐one (yellow). The experiments were carried out in a laboratory scale chamber and in a large container. The toxicity was compared to that of hexachloroethane (HC)‐based reference smoke with known toxicity. All the colored smokes displayed acute toxicity. The order of toxicity in the laboratory scale tests was orange>violet≈red>HC>yellow and in the container tests orange>violet≈yellow>red. The orange smoke appeared genotoxic in all the tests. With the yellow and the violet smokes, the genotoxicity could not be totally excluded. The red smoke showed evidence of weak genotoxicity only in one test series at the highest concentration level.
The two hexachloroethane (HC)-based smoke formulations studied consisted of HC/Zn/2,4,6-trinitrotoluene (TNT) and HC/Zn. In the in vitro tests, human bronchial epithelial cells were exposed to the smokes at various concentrations. The responses studied were acute toxicity (viability of cells, trypan blue exclusion method) and genotoxicity (DNA single-strand breaks, COMET assay). The tests were conducted in a laboratory-scale chamber (V = 150 L) and in a container (V = 55 m3). Both smoke formulations appeared to be acutely toxic and genotoxic. For the 0.5- and 1-g burning experiments the responses were more pronounced with HC/Zn/TNT than with HC/Zn smoke. To study the irritation potency of the smokes, the mouse bioassay according to ASTM E 981-84 was applied. The respiratory parameters measured were tidal volume (VT), airflow during expiration at 0.5 VT (VD), time of pause after expiration (TP), time of breaking after inspiration (TB), and the respiratory frequency (BPM; breaths per minute). In the single-exposure experiments, HC/Zn/TNT smoke induced concentration-dependent sensory irritation in mice and the occupational exposure limit (TLV) was estimated to be 4 mg/m3. In the repeated-exposure experiments, HC/Zn/TNT smoke induced sensory irritation at the beginning of the exposure. Pulmonary irritation tended to dominate when the exposures were repeated. With HC/Zn smoke we were unable to generate sufficient high exposure concentrations. In the repeated-exposure experiments, indications of sensory and pulmonary irritation were seen at concentrations used. No evidence of apoptotic cell death was found in caspase-3-like protease activity assay.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.