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Journal of Microwave Power
and Electromagnetic Energy (JMPEE) |
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TITLE |
The
Development of Biomedical Approaches and Concepts in Radiofrequency Radiation
Protection [PDF] |
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AUTHORS |
P. Czerski 1986 21 1 9-23 |
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Abstract The approaches and concepts
used in the development of radiofrequency radiation (RFR) protection
guidelines evolved over the past quarter of a century. The values of exposure
limits (EL) proposed by various groups are converging. Early guides specified
ELs in incident power density. Recent ELs are based on considerations of the
relationship between bioeffects and the magnitude of the whole body average
specific absorption rate MBA-SAP) and current densities induced in the body.
Both these quantities may be considered as dosimetric ones. Thresholds for
untoward health effects expressed in terms of these quantities were
suggested, and may be considered as basic ELs. It is possible to derive a
frequency dependent relationship between incident RFR fields and WBA-SAR
and/or induced current densities in the body. ELs specified for the purpose
of determining compliance in terms of electric and magnetic field strengths
or equivalent plane-wave power density existing at a point where a person
could be present, but measured in the absence of the exposed subject, may be
considered as derived working limits. The rationales offered for the
recommended ELs indicate that the principle consideration in establishing
limits for frequencies of 10 MHz and higher is the prevention of thermal
injury, thermal being defined as relatable to heating, i.e., an increase in
temperature. At lower frequencies,
below 100 kHz or 30 kHz, direct effects on membranes of nerve and muscle
cells may be the limiting factor. An
additional consideration is the hazard of shock and burns from contact with
ungrounded large metal objects that are charged by RFR fields. Recent advances in RFR dosimetry led to
concerns that exposure to presently accepted derived ELs may result in large
local SARs and induced current densities in certain parts of the body. The present review concludes that further
refinements to the basis for RFR should be introduced. Threshold for health,
hazards should be investigated taking into account both direct and thermal
bioeffects of RFR. The dose-thermal effects relationships should be
quantified using the concepts of SAR, SA and thermal dosage. Several
unresolved questions, such as the biological basis for SAR time-averaging,
and the limitation of pulse peak power, are briefly discussed. |
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