Abstract
Insight into the distortion of electromagnetic (EM) signals in living tissue is
important for optimising medical applications. To obtain this insight, field calculations have
been carried out for a plane-stratified configuration of air, skin, fat, muscle and bone tissue.
In this configuration, an EM field is generated by a prescribed pulsed current in a circular
loop. Debye dispersion models have been developed for the description of the permittivity
of the tissues. The field problem is solved analytically with the aid of a temporal Fourier
transformation and a spatial Hankel transformation. The corresponding inverse transformations have been carried out numerically. To demonstrate the influences of stratification and dispersion separately, the EM fields in the stratified configuration, in a completely musclefilled space and in vacuum are compared. Two different pulses have been considered; narrow and wide. It emerges that dispersion results in a retardation and an attenuation of the field. Stratification causes additional fluctuations of the time-dependent field. Furthermore, the conductivity of ~ssue at high frequencies is mainly determined by its water content. Tissues with high water content, like muscle and skin, exhibit higher conductivity at high frequencies than fat and bone. Muscle and skin tissue therefore behave as low-pass filters to EM signals.
Original language | English |
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Pages (from-to) | 213-220 |
Number of pages | 8 |
Journal | Medical and Biological Engineering and Computing |
Volume | 34 |
Issue number | 3 |
DOIs | |
Publication status | Published - 1996 |