Title :
Biological applications of large electric fields: some history and fundamentals
Author_Institution :
Rhode Island Univ., Kingston, RI, USA
fDate :
2/1/2000 12:00:00 AM
Abstract :
The history of electric fields in biology is summarized briefly. Physical concepts important for explaining the action of electric field pulses on biological objects are reviewed: relation of pulse width to frequency spectrum; precise meaning of “conductor” and “dielectric”; electrical properties of living tissues; translatory and rotational motion of electric charges and dipoles; effects of inhomogeneity, diffusion and viscosity; conditions for validity of linear models; electrical mobility of ions in membrane channels and membranes; conditions for radiation; reflection, refraction, and penetration of radiated fields; effect of radiated magnetic fields on chemical reaction rates; radiation pressure; electrostriction; the problem of distinguishing between thermal and nonthermal effects. The rationale for close collaboration among biologists, engineers, physicists, and physicians is discussed
Keywords :
bioelectric phenomena; biological effects of fields; biomembrane transport; electrostriction; biological applications; chemical reaction rates; conductor; dielectric; diffusion; dipole motion; electric charge motion; electric fields; electrostriction; frequency spectrum; history; ion electrical mobility; linear models; living tissues electrical properties; membrane channels; membranes; nonthermal effects; pulse width; radiated fields; radiated magnetic fields; radiation; radiation pressure; thermal effects; viscosity; Biological system modeling; Biological tissues; Biomembranes; Frequency; History; Magnetic properties; Nonuniform electric fields; Reflection; Space vector pulse width modulation; Viscosity;
Journal_Title :
Plasma Science, IEEE Transactions on
