ABSTRACT
Globally, concerns regarding the COVID-19 pandemic its prevention have become important. Because of COVID-19 and other microbial diseases, enhance research work has emerged revealing new antimicrobial and antiviral materials and techniques. Tremendous growth in nanotechnology has opened up the door to fabricating numerous nanomaterials. These nanomaterials are employed as antimicrobial and antiviral agents for various applications with 99.99% effectiveness compared with conventional techniques. Nanoparticles possess unique physicochemical characteristics for multiple applications. This chapter details the use of nanoparticles for antifungal, antimicrobial, and antiviral applications. It describes various kinds of nanoparticles, such as nanometals, metal oxides, polymeric nanomaterials, and carbon-based nanomaterials. © 2023 Elsevier Inc. All rights reserved.
ABSTRACT
Global pandemic COVID-19 has affected almost the entire world population in every aspect of life in terms of health, environment, and economy. According to WHO, the main source of transmission of this deadly virus (SARS-CoV-2) is proven to be through the aerosol coming from the infected person's cough, sneeze, or exhalation. These aerosols are likely to settle down on the exposed surfaces and such infected surfaces are known to be potential source of contamination. The spread of the viral infections can be controlled in a great extent with the development of anti-viral nano-coating materials for various surfaces. Thus, development of such anti-viral nano-coating materials becomes increasingly popular amongst the researchers due to their extensive applications on surfaces, such as, glass, cotton, plastic and many more. In this short review, we will describe a summary of the popular metals and metal oxide nanomaterials commonly explored as antiviral coatings to control the spread of various viral disease along with the corresponding working principle and effectivity of such coatings.
ABSTRACT
In recent years, an unprecedented increase in the development of products and technologies to protect the human being has been observed. Now, more than ever, the world population is exposed to several threats, harmful to their well-being and health. Chemical and biological hazardous agents stand out as one of the biggest threats, not only for the military forces, but also for the civilians. Consequently, it's essential to develop personal protective systems that are able to protect their user, not only passively, but actively, being able to detect, adsorb, degrade and decontaminate pesticides, pollutants, microorganisms and most importantly: chemical/biological warfare agents. One recent strategy for the development of active fibrous structures with improved functions and new properties is their functionalization with nanoparticles (NPs), especially metal oxides. Although their known effectiveness in the decomposition of harmful agents, the NPs could also include other functionalities in the same structure using low quantities of material, without adding extra weight, which is of huge importance for a soldier in the battlefield. The use of natural fibers as the substrate is also very interesting, since this material is a much sustainable alternative when compared to synthetic ones, also providing excellent properties.