Forces, Chromosomal Configurations, and Carcinogenesis: Towards Another Therapeutic Approach

Abstract

Various types of forces, such as cohesive and adhesive forces, are involved in physical and biological processes. Many of these processes appear to have developmental features through different scales of nature, and such processes may reflect a universal dynamic of accommodation involving the universal dimensional constants. A particular avenue of plant tissue culture research, utilizing the process of electronic desaturation, might very well point to such a subsuming, universal process. Through the process of electronic desaturation of proteins in living cells, cohesive and adhesive forces are generated and regenerated between cellular proteins and between structured water and the proteins throughout and between mammalian cells. Those forces stabilize cells and tissues and prevent carcinogenesis [1,2]. In electronic desaturation, methylglyoxal-ascorbic acid complexes attach to particular protein regions, which enable or promote the conduction or movement of outer electrons of the proteins via methylglyoxal-ascorbic acid to oxygen. When such cohesive forces cease to exist in cells due to the conversion of methylglyoxal (MG) to D-lactic acid by glyoxalase, carcinogenesis ensues. Glyoxalase is an enzyme that can actively exist in cells. As noted by SzentGyorgyi [1,2], the presence of oxygen, MG, and ascorbic acid enabled the evolution of organisms with high levels of development and a general capability of preventing dedifferentiation that could lead to carcinogenesis.