Title :
Deriving principles of microbiology by multiscaling laws of molecular physics
Author :
Ortoleva, Peter J. ; Adhangale, P. ; Cheluvaraja, S. ; Fontus, Max W A ; Shreif, Zeina
Author_Institution :
Indiana Univ., Bloomington, IN
Abstract :
It has long been an objective of the physical sciences to derive principles of biology from the laws of physics. At the angstrom scale for processes evolving on timescales of 10-14 s, many systems can be characterized in terms of atomic vibrations and collisions. In contrast, biological systems display dramatic transformations including self-assembly and reorganization from one cell phenotype to another as the microenvironment changes. We have developed a framework for understanding the emergence of living systems from the underlying atomic chaos.
Keywords :
bioelectric phenomena; biology computing; microorganisms; molecular biophysics; physiological models; bacterial division; bioelectrics; microbiology; molecular physics; multiscaling laws; nanomedicine; stochastic forces; Biological systems; Biology computing; Cells (biology); Chaos; Displays; Equations; Feedback; Nanobioscience; Physics; Self-assembly; Algorithms; Computational Biology; Microbiological Phenomena; Microbiology; Models, Biological; Nanocapsules; Nanotechnology; Physics; Software;
Journal_Title :
Engineering in Medicine and Biology Magazine, IEEE
DOI :
10.1109/MEMB.2009.932389
