Carl F. Blackman

TL;DR: The results appear to describe a resonance-like relationship in which the frequency of the electromagnetic field that can induce a change in efflux is proportional to a product of LGF density and an index, 2n + 1, where n = 0,1.

TL;DR: The ion parametric resonance (IPR) model proposed by Lednev as discussed by the authors corrects mathematical errors in the earlier lednev model and extends that model to give explicit predictions of biological responses to parallel AC and DC magnetic fields caused by field-induced changes in combinations of ions within the biological system.

TL;DR: It is reported here that 16-Hz sinusoidal fields in the absence of a carrier wave can alter the efflux rate of calcium ions and shows a frequency-dependent, field-induced enhancement of calcium-ion efflux.

TL;DR: A 45-Hz field causes enhanced efflux in an intensity range around 40 Vp-p/m that is essentially identical to the response observed for 16-Hz fields, and exposures over a series of frequencies reveal two frequency regions that elicitEnhanced efflux.

TL;DR: In this article, Bawin et al. reported changes in binding of calcium after exposure of avian brain tissue to nonionizing electromagnetic radiation, which revealed a heretofore unrecognized potential for non-ionizing radio-frequency radiation to affect biological function.