Abstract
In this work a comparative theoretical analysis vs. experimental study on human blood under a magnetic field stimulation is presented. Twenty samples of leukoreduced human blood were stimulated with an alternant magnetic field using a Helmholtz coil system; this magnetic field induced an electromotive force in them. Theoretical calculations were performed for the induced electromotive force in a simple model of blood tissue under magnetic stimulation at frequencies: 50 Hz, 100 Hz, 800 Hz, and 1500 Hz. Experimental measurement was performed at the same frequencies for comparison purposes. Results show a high correlation between theoretical and experimental study, as well as effects of agglutination in the stimulated blood cells.
Highlights
Interactions between living systems and magnetic field (MF) on the environment cannot be avoided; it is important to widely study those interactions in order to understand any potential side effects
Earlier studies have shown the presence of proliferation, agglutination, growth and other effects when some culture cells are stimulated with applied magnetic field (AMF) at low or high frequencies
It is known that when a biological system is modeled as a conductor and it is stimulated by a MF, by Faraday’s law, it is induced a electromotive force in the tissue which causes a flow of a current density through the biological system [8]
Summary
Interactions between living systems and magnetic field (MF) on the environment cannot be avoided; it is important to widely study those interactions in order to understand any potential side effects. Earlier studies have shown the presence of proliferation, agglutination, growth and other effects when some culture cells are stimulated with applied magnetic field (AMF) at low or high frequencies.
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