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

Volume

28

Issue

2

fYear

2009

Firstpage

70

Lastpage

79

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;

fLanguage

English

Journal_Title

Engineering in Medicine and Biology Magazine, IEEE

Publisher

ieee

ISSN

0739-5175

Type

jour

DOI

10.1109/MEMB.2009.932389

Filename

4809863