Antimicrobial Activity and Degradation Ability Study on Nanoparticle-Enriched Formulations Specially Designed for the Neutralization of Real and Simulated Biological and Chemical Warfare Agents

Overview

Journal Pharmaceuticals (Basel)

Publisher MDPI

Specialty Chemistry

Date 2022 Jan 21

PMID 35056158

Authors

Raluca-Elena Ginghina

Gabriela Toader

Munizer Purica

Adriana-Elena Bratu

Claudiu Lazaroaie

Tudor-Viorel Tiganescu

Ramona-Elena Oncioiu

George-Ovidiu Iorga

Florina-Lucica Zorila

Mihai Constantin

Gabriel Craciun

Florin Comanescu

Cosmin Romanitan

Affiliations

Soon will be listed here.

Abstract

The present work reveals a comprehensive decontamination study on real and simulated biological and chemical warfare agents (BCWA). The emphasis was on evaluating the antimicrobial activity against real biological warfare agents, such as , and also the capacity of neutralizing real chemical warfare agents, such as mustard gas or soman, by employing three different types of organic solutions enriched with ZnO, TiO, and zeolite nanoparticles, specially designed for decontamination applications. The capacity of decontaminating BCWA was evaluated through specific investigation tools, including surface monitoring with the swabs method, minimum inhibitory (MIC) and minimum bactericidal concentration (MBC) evaluations, time-kill tests for microorganisms, and GC-MS for monitoring chemical agents on different types of surfaces (glass, painted metal, rubber, and cotton butyl rubber). These tests revealed high decontamination factors for BCWA even after only 10 min, accomplishing the requirements imposed by NATO standards. At the completion of the decontamination process, the formulations reached 100% efficacy for after 10-15 min, for soman after 20-30 min, and for mustard gas in an interval comprised between 5 and 24 h depending on the type of surface analyzed.

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