Distressing research on animalsĀ š
Behavioral alterations in experimental animals under certain conditionsĀ to microwave exposure
from Florie Freshman
”…exposure32.
In addition to biochemical, histological and bioelectrical alterations,
microwave exposure reportedly affects behavioral alterations in experimental
animals under certain conditions. Galloway 33 , for example, tested the effects
of high intensity 2.45 GHz, CW microwaves on discrimination and repeated
acquisition tasks in rhesus monkeys. The heads of the experimental subjects
were exposed to 5, 10, 15, 20, and 25 W for two minutes prior to testing.
Convulsions were induced at 15 and 25 W. Animals were irradiated throughout
the durations of five consecutive one hour daily testing sessions for a total
irradiation time of 40 min/day. No behavioral deficits were detected at integral dose rates of less that 15 W. Exposure to 15 W or more produced
either skin burns or severe convulsions without reliably altering task performance. The author suggests that complex tasks, such as repeated acquisition, may be more sensitive to microwave radiation exposure than simple schedule control tasks, but in general the results of this study rule out the existence of low intensity microwave effects on repeated acquisition or discrimination in the rhesus monkey 33 ā¢”
”Straub: The shock wave does not occur at frequencies at which the molecule
does not absorb the energy. We do not see denaturation when we are off the
absorption peak. The shock wave you are talking about is, in reality, a
consequence of electronic relaxation.
At least in one case~ you said that when dye was injected the increase
was observed.
Straub: That is another problem. You mean in the isolated vesicle system.
There needs to be some more experimentation there, just to see what the
thermal conductivity of the membrane is, if nothing else. We do not know
that yet. ”
excerpt
Irvin T. Grodsky
Cleveland State University, Cleveland, Ohio
ABSTRACT
Recently there has been a steadily increasing amount of
evidence that certain types of nonionizing radiation are
resonantly absorbed by vertebrate brain tissue: windowed
both in frequency (VHF modulated and VLF) and amplitude
(power). Concurrently, evidence is mounting that the morphological structures in microtissue samples indicate strong
similarities to inorganic quantum amplification devices, such
as tunnel diodes, liquid crystals (smectic laminar), and population inversion systems (lasers, masers ā¢ā¢ā¢ ). In this talk
we hope to emphasize these analogies mathematically as homomorphisms, and indicate potential experiments capable of
differentiating between which functions utilize which quantum
cooperative dynamics. ”
