Premium
Design, implementation, and dosimetry analysis of an S‐band waveguide in vitro system for the exposure of cell culture samples to pulsed fields
Author(s) -
Varela José E.,
Page Juan E.,
Esteban Jaime
Publication year - 2010
Publication title -
bioelectromagnetics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.435
H-Index - 81
eISSN - 1521-186X
pISSN - 0197-8462
DOI - 10.1002/bem.20579
Subject(s) - bioelectromagnetics , specific absorption rate , monochromatic color , dosimetry , optics , electromagnetic field , waveguide , physics , pulse duration , pulse (music) , electromagnetic radiation , power (physics) , pulse repetition frequency , non ionizing radiation , telecommunications , computer science , radar , laser , medicine , quantum mechanics , detector , antenna (radio) , radiology
The interaction between electromagnetic fields and biological media, particularly regarding very high power, short pulses as in radar signals, is not a fully understood phenomenon. In the past few years, many in vitro, cellular communications‐oriented exposure studies have been carried out. This article presents a high‐power waveguide exposure system capable of dealing with monochromatic, multicarrier or pulsed signals between 1.8 and 3.2 GHz (L‐ and S‐band) with a pulse duration as low as 90 ns, minimum pulse repetition of 100 Hz, and maximum instantaneous power of 100 W. The setup is currently being used with a 2.2 GHz carrier modulated by 5 µs pulses with a 100 Hz repetition period and approximately 30 W of instantaneous power. After a worst‐case temperature analysis, which does not account for conduction and convection thermal effects, the experiment's exposure is considered sub‐thermal. Evaluation of the results through the specific absorption rate distribution is not considered sufficient enough in these cases. An electromagnetic field distribution analysis is needed. For monochromatic signals, the representation of the modulus of the electric and magnetic field components is proposed as a suitable method of assessment. Bioelectromagnetics 31:479–487, 2010. © 2010 Wiley‐Liss, Inc.