salicylates and chloroxylenol

The aim of this study is to identify common household disinfectants that combine significant activity against the type orthopoxvirus, vaccinia virus with minimal impact in terms of potential toxicity and/or damage to household or personal items.. Laboratory scale experiments assessed common disinfectants containing anionic and nonionic detergents, oxygen-based bleach, potassium peroxomonosulfate, chloroxylenol or halogenated phenols. Disinfectants were assessed for their ability to inactivate the virus on contact or after a short incubation period in the presence and absence of foetal bovine serum as a potential interferant. Significant differences were observed ranging from negligible effect of detergents to complete inactivation on contact with chloroxylenol.. At least one chloroxylenol-based household disinfectant is available, which inactivates vaccinia virus on contact.. In the event of a release or major outbreak of a pathogenic orthopoxvirus there is likely to be significant public demand for disinfectants with activity against these viruses. The identification of common household disinfectants with such activity obviates any requirement to stockpile or distribute laboratory/industrial disinfectants for this purpose.

Topics: Chlorine; Culture Media; Detergents; Disinfectants; Drug Combinations; Household Products; Iodine; Oxidants; Peroxides; Phenols; Salicylates; Sulfuric Acids; Surface-Active Agents; Vaccinia virus; Virus Inactivation; Xylenes

Ochratoxin A, ochratoxin alpha (its major metabolite in rodents) and seven structurally related substances were assayed for SOS DNA repair inducing activity in Escherichia coli PQ37 strain. At a concentration range of 0.1-4 mM, ochratoxin A, chloroxine, 5-chloro-8-quinolinol, 4-chloro-meta-cresol and chloroxylenol were found to induce SOS-DNA repair in the absence of an exogenous metabolic activation system. Ochratoxin B, ochratoxin alpha, 5-chlorosalicylic acid and citrinin were inactive, but all except ochratoxin alpha were cytotoxic. Thus, the presence of a chlorine at C-5 in ochratoxin A and in other analogues appears to be one determinant of their genotoxicity. In order to ascertain whether this reactivity involves a bacterial glutathione conjugation reaction, we investigated the modifying effect on the genotoxicity of ochratoxin A of amino oxyacetic acid, an inhibitor of cysteine conjugate beta-lyase. Amino oxyacetic acid decreased the cytotoxicity of ochratoxin A but did not alter its genotoxic activity, suggesting the formation of a cytotoxic thiol-containing derivative. The way in which ochratoxin A and some of its active analogues induce SOS DNA repair activity was further investigated in E. coli PQ37 and in three derived strains (PQ300, OG100 and OG400, containing deletions within the oxy R regulon). The response in PQ37 strain was measured in the absence and presence of Trolox C, a hydrosoluble form of vitamin E. Trolox C completely quenched the genotoxicity of ochratoxin A, which was no greater in mutated than in wild type strains. These results implicate an ochratoxin A-derived free radical rather than reduced oxygen species as genotoxic intermediate(s) in bacteria.

Topics: Aminooxyacetic Acid; Chloroquinolinols; Chromans; Citrinin; Cresols; Dimethyl Sulfoxide; Escherichia coli; Free Radicals; Glutathione; Mutagenicity Tests; Ochratoxins; Salicylates; SOS Response, Genetics; Stimulation, Chemical; Structure-Activity Relationship; Xylenes