The differential effects of 200, 591, and 2,450 MHz radiation on rat brain energy metabolism.
暂无分享,去创建一个
[1] D. E. Goldman. A MOLECULAR STRUCTURAL BASIS FOR THE EXCITATION PROPERTIES OF AXONS. , 1964 .
[2] B. Chance,et al. A time sharing fluorometer for the readout of intracellular oxidation-reduction states of NADH and flavoprotein. , 1971, The Review of scientific instruments.
[3] G. J. Trezek,et al. A Probe Technique for Determining the Thermal Conductivity of Tissue , 1972 .
[4] R. Seaman,et al. Microwave-Power Absorption by Rectangular-Shaped Conductive Dielectric Samples in Stripline (Letters) , 1976 .
[5] J. W. Allis,et al. Measurement of microwave radiation absorbed by biological systems: 1. Analysis of heating and cooling data , 1977 .
[6] Ronald Pethig,et al. Dielectric and electronic properties of biological materials , 1979 .
[7] K. Foster,et al. Dielectric properties of brain tissue between 0.01 and 10 GHz. , 1979, Physics in medicine and biology.
[8] W. Joines,et al. Microwave effects on energy metabolism of rat brain. , 1980, Bioelectromagnetics.
[9] D. Schaefer,et al. Microwave power absorption differences between normal and malignant tissue. , 1980, International journal of radiation oncology, biology, physics.
[10] Calcium Ion Efflux Induction in Brain Tissue by Radiofrequency Radiation , 1981 .
[11] W. Joines,et al. The effects of hyperthermia and hyperthermia plus microwaves on rat brain energy metabolism. , 1984, Bioelectromagnetics.