Possible Mechanisms Of Action Of Light Inert Gases On Chemiluminescence Arising As A Result Of Lipid Peroxidation

Abstract

The use of inert gases in biology and medicine and their effect on biological objects both in vitro and in vivo remains an active area of research. It has been established that light noble gases affect antioxidant processes, free radical oxidation, and enhance chemiluminescence, but an explanation of the physical and chemical mechanisms of this effect is still lacking and is key to further theoretical and experimental studies, given the broad prospects for the use of noble gases in medicine. In this article, we present two of the possible mechanisms of light inert gases' effect on chemiluminescence (CL), a phenomenon that occurs as a result of free radical recombination and chain breakage during lipid peroxidation. Since the effect on oxidation, in turn, precedes the effect on the antioxidant system and the body's defense mechanisms. One of the mechanisms of influence is based on the ability of inert gases to dissolve well in lipids and dissolve poorly in water. Their ability to dissolve in lipid bilayers and affect the conformation of lipid complexes can increase the surface area available for oxidation, the surface area that absorbs radiation and reduce the density of the environment, potentially increasing the availability of oxygen for oxidation reactions. This is the so-called spatial mechanism of inert gas influence on oxidation and chemiluminescence. The second mechanism is based on the influence on the quantum chemical parameters of the reaction medium. The acceleration of VT relaxation processes, the impact on the components of the medium in quenching excited states, and the radiative decay time of the excited state.