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Journal of Microwave Power
and Electromagnetic Energy (JMPEE) |
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TITLE |
Microwave Techniques in Biophysical Measurements [PDF] |
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AUTHORS |
P. O.
Vogelhut 1968 3 3 143-147 |
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Abstract One of the emerging fields
of study in biophysics and bioelectronics is the investigation of the role of
water in living systems. Microwave frequencies are well suited for studies of
water since "free" water shows a Debye dispersion with a relaxation
time of |
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. Differential volumetric techniques were devised to allow
measurements of changes in the water structure surrounding active
macromolecules such as enzymes. Another microwave technique-Faraday
rotation-was adapted to measure the concentration of free dipoles in systems
consisting of macromolecules and varying amounts of water. Since some enzymes
(e.g., urease) can act as catalysts even in a relatively dry environment, a
combination of the above two techniques allows one to clarify structural changes
in the water surrounding enzymes while they are interacting with their
substrate molecules. The Faraday rotation technique is also used as a
contactless Hall-effect measurement to study the mobilities of charge
carriers in organic semiconductors which are of importance in biological
systems. Several "non-thermal" effects of microwaves have been
reported in the literature but as yet have eluded precise substantiation and
interpretation by molecular events. A new model is proposed based on the frequency
variation of the dielectric constant of bound and free water and the thermal
characteristics of the cellular and interstitial system. The model postulates
microthermal effects which produce temperature gradients that result in
thermoosmotic and thermoelectric after effects.