INDEX
Abbe Nollet, 7, 17
ACTH (adrenocorticotropin), 113, 117
ACTH releasingfactor, 115
Acupuncture, 197-200
Adey, R., 104
ADH (antidiuretic hormone), 115
ADP, 137, 141
Adrenal gland, 112, 115-118
Ahmed, N., 85
Alrports, 180
Aldini, G., 12, 13
Alkaline phosphatase, 125
AM radio band, 177-179
Ammonia, 135, 138
Amoebas, 200
Ankermuller, F., 103
Antonowicz, K., 167
Aorta, 82
Appleton, B., 186
Ascorbate, bioelectrical role, 80
Athenstaedt, 84
ATP, 137
Bacon, F., 5
Bassett, C., 147, 166, 196
Batkin, S., 147
Battelle Laboratories, 130, 151-152
Bawin, S., 99
Bay Area Rapid Transit, 182
Bees, 200-201
Behavioral changes
Conditioned responses, 104
Motoractivity, 102
Reaction time, 103-104
Spontaneous behavior, 103
Beischer, D., 138
Bennet, A., 7
Berger, H., 19
Bemstein,J., 15
Hypothesis, 15, 17, 20, 32
Biogenesis, 17, 63
Biophilosophy, 3, 4
Blood, 139, 141
Bacteriocidal activity, 129
Brain barrier, 100
Globulins, 127
Glucose, 134
Pressure, 124
Bone, 82-84, 141
Bose-Einstein condensation, 165-167
Bowman, J., 169
Bradycardia, 123, 185
Brain, 101, 102, 135, 139
Brucke E., 17
BuIIard, 84
Bureau of Radiological Health, 190
Burr, H., 19, 32, 34, 36
Bychkov, M., 106
Calcium, 104, 112
Calculation
Electric field, 86
Magnetic fieid, 84
Electromagnetic radiation, 91
Carbohydrate metabolism, 134-135, 137
Cardiac muscle, 135
Carey, R., 101, 113
Cataracts, 186-187
Catecholamines, 113, 117-118
Cavendish, 7
Cells
Perineural, 28, 39, 40
Blood, 49
Bones, 52
Dedifferentiation of, 48-49, 51
In regenerative growth, 42, 47-48
Cellular bioenergetics, 137
Ceruloplasmin, 141
Chernysheva, O., 135
Chizhenkova, R., 97-98
Chlordiazepoxide, 104
Cholates, 85
Cholesterol, 139
Choline acetyltransferase, 100
Cholinesterase, 100
Collagen, 52-54
Conduction band, 79-80
Conductivity, 79-80
Cooper pair, 84-85
Cope, F., 85-86, 166-167
Corticoids, 112-116, 185
Creatine phosphate, 138
Cybernetics, 160-161
Cytochromeoxidase, 100, 134
Cytochromoxidase, 143
Czerski, P., 130
Darwin, C., 17
Davy, H., 13
Dead-body theory, 189
Delta waves, 97
Dentin, 82
Denver, Colorado, 184
Descartes, R., 6-7
Desynchronization, 97
Dielectric constant, 86
Diuresis, 115, 138
Dose-effect relationship, 135
Dugesia, 200-201
Dumanskiy, Y., 99, 134
E. coli, 129
Eakin, S., 102
Earth's electromagnetic environment, 177
ECG (electrocardiogram), 173, 185
Edison, T., 18-19, 176
EEG (electroencephalogram), 19, 37-38, 63,97-99, 104, 185
Elastin, 82
Electret, 84
Electrical osteogenesis, 196, 197
Electricity
Animal, 9, 12, 14, 16
Bimetallic, 10, 13, 44
Chemistry, 13
Direct current, 20, 27-30, 32-34, 37-39, 42-44, 48
Generation of, 6
Injury, 14-15, 43
Measurement of, 7
Transmission, 7, 14
Static, 6-7
Storage, 7
Electronic excitation, 163-165
Electron paramagnetic resonance, 54
Electrophoresis, 135
Electroretinogram, 39
EMF (defined), 92
Apparatus
Electric field, 86
Electromagnetic radiation, 90-91
Magnetic field, 88-89
Dosimetry, 87-89
Effect on
Behavior Conditioned responses, 104-105
Motoractivity, 102-103
Reaction time, 103-104
Spontaneous behavior, 103
Blood
Cholinesterase, 100
Globulins, 127
Glucose, 119
Lymphocytes, 125
RBC, 124-127
WBC, 124-125
Blood-brain barrier, 100
Brain biochemistry
Choline acetyltransferase, 100
Cytochromeoxidase, 100
Norepinephrine, 100
Brain histopathology, 101-102
Cardiovascular system
Blood pressure, 124
Bradycardia, 123-124
ECG, 123
Hemorrhage, 124
Reserve capacity, 124
Electroencephalogram
Cat, 104
Rabbit, 97-99
Rat, 98
Salamander, 97
Endocrine system
ACTH, 115
ACTH releasing factor, 115
ADH, 115
Adren a I gl and, 115-118
Catecholamines, 100, 118
Cortico ids, 113-116
Diuresis, 115
Pancreas, 119
Pituitary, 113
Thyroid, 117
Evoked potentials, 100
Hearing, 100
Neuroelectric latency and threshold, 100
Neuronal firing rate, 100
Response to drugs, 100, 104
Environmental levels, 177-183
Epidemiological studies, 183-188
Health risks, 175-177, 188-190
Mechanism of action
Analytical approach, 162-167
Cybernetic approach, 160-162
Methodology, 120
Units
Electric field, 89
Electromagnetic radiation, 91
Magnetic field, 89
Uses, 176
Encephalitozoonosis, 101
Endorphins, 200
Eosinophils, 125
Ehrlich ascites tumor, 147
Eriksson, M., 200
Evans, M., 80
Evoked potentials, 100
Experimental problem, 80-84, 86
Ferroelectricity, 84
Field-generated forces, 163
Fischer, G., 100
Fish, 200-201
Flexner, A., 18
Report, 18-19
FM radio band, 177-179
Fracture, 49
Freud, S., 17
Frey, A., 100
Friedman, H., 101, 103, 107, 113
Frolich, H., 166-167
Fukada, E., 82, 84
Fulton,J., 184
Galen, 4-5
Galvani, L., 8-14, 16, 19
Gerard, R., 2o, 27-29, 31, 34, 36-37, 39
Gergely, J., 80
Glaucoma, 151
Globulins, 137
Glotova, K., 184
Glucose, 135
Glucose-6-phosphate dehydrogenase, 134, 143
Glutamine, 135, 138
Glycogen, 125, 135, 138-139
Goldstein, L., 98
Golgi apparatus, 101, 117
Goodman, E., 701
Granulocytosis, 128
Graue, L., 201
Grin, A., 100
Grissett,J., 147
Grodsky, I., 104
Growth, 143-147
Growth control, 83
Gutman, W., 84, 151
Hales, S., 7
Hall effect, 35-36, 38, 165
Halpern, E., 84
Hamer, J., 103
Harvey, W., 5
Hawkins, T., 100
Hb (hemoglobin), 126-127
Hct (hematocrit), 126-127
Healing, 147-148
Heart, 135, 139, 141
Heat, 163
Helmholtz coils, 196
Hemorrhage, 124
Hertz, H., 18, 91, 175
Hexokinase, 143
High-voltage transmission lines, 176, 181-183, 189-190
Hooke, R., 6
Hormones, 112
Human experimentation, 190
Immune response
resistance to infection, 127-129
phagocyticcapability, 129
lymphocytes, 130
inflammatory response, 130
Immune system, 127-130
In vitro studies, 104, 137, 150
Intermediary metabolism
carbohyd rate, 134-135, 137
protein, 135, 137-138
Iipids, 138-139
nucleic acid, 135
vitamins, 139
energy, 137
Intestine, 82
Iron metabolism, 125
Ivory, 82
Josephson junction, 167
Khlynin, S., 143
Kholodov, F., 97-98, 101, 106, 135
Kidney, 137, 139, 141
Klimkova, E., 185
Konig, H., 103
Krebs cycle, 138
Lactate dehydrogenase, 135
Lang, S., 84
Leeper, E., 184
Leukemia, 184
Leukocytes, 185
Libet, B., 2o, 27-29, 31, 34, 36-37, 39
Limb regeneration, 167
Lipidmetabolism, 138-139
Listeria, 129
Liver, 134-135, 137-139, 141
Lott, J., 98
Lymphocytes, 125, 127, 130, 149
Lymphoma, 184
Lynx, Academy of the, 6
Lysozyme (superconductivity), 85, 86
Lysozyme activity, 129
Magnetic field, 60-65, 70
Cyclic Quctuations in, 68
Magnetocardiogram, 39
Magnetoencephalogram, 38-39
Majewska, K., 186
Marconi, G., 18, 175-176
Marsh, G., 201
Martin, R., 84, 151
Mascarenhas, S., 84
Mathematical modelling, 86
Mathewson, N., 135-137
Matteucci, C., 14-16
Maxwell, J., 18, 175
McCain, H., 98
McCleave, J., 201
McElhaney, J., 84, 150-151
MCH (mean corpuscular hemoglobin), 126
MCHC (mean corpuscular hemoglobin concentration), 126
MCV (mean cell volume), 126-127
Measurement
Electric field, 86
Magnetic field, 89
Megakarocytes, 130
Melanin, 86
Microwavedisease, 186
Microwave-relay antennas, 180
Miro, 138
Mitchell, D., 102
Mitochondria, 137
Mongolism (Down's Syndrome), 186
Motor activity, 102
MountWilson, 179
Mutagenesis, 148-150
Nassarius, 68
Nerve
Electricity, 16, 20, 27
Growth relationship, 41
Impulse, 15-16, 20, 26, 28, 30, 34, 42
Membrane, 15-16
Regeneration relationship, 41
Neuroelectric latency, 100
Neuroelectric threshold, 100
Neuroepiderman junction, 46-47
Neutrophils, 125, 127, 129
Newton, I., 6
Nonunions, 196
Norepinephrine, 100
Noval,J., 143
Novitskiy, A., 114
Nucleic acids, 82, 135
Occupational exposure limits (USSR), 187
Odland, L., 186
Oersted, H., 13, 18
Olds self-stimulation response, 102
Optical spectroscopy, 141
Oscar, K., 100
Ossenkopp, K., 117
Osteoporosis, 151
Ovaries, 143
Oxidative phosphorylation, 138
Pacinian corpuscle, 30-31
Pancreas, 112, 119
Parathyroid gland, 112
Pearl-chain formation, 165
Persinger, M., 103, 117
Phillips, R., 148
Phosphoryiation effectiveness factor, 137
Physarum polycephalum, 200-20I
Piezoelectricity, 53-54, 56, 81-84, 150-151, 165, 196-197
Pile, voltaic, 11, 14
Pilla, A., 166
Pituitary, 113
Planaria, 40
Plane wave, 91
Plasma oscillations, 166
Polarization, 163-165
Pomeranz, B., 200
Potential
Injury, 14-16
Resting, 15
Preston, E., 100
Procrustean bed, 168
Protein synthesis, 135, 137-138
Protolipids, 137
Public Service Commission (New York), 190
Public Service Commission (West Virginia), 189
Pyroelectricity, 84
Radiolaria, 64-65
RBC (red blood cell count), 124-127
Reproduction
Estrous-cycle dysfunction, 143
Post-natal mortality, 143-145
Spermatogenesisysfunction, 141
Testicular metabolism, 141-143
Respiratorycontrol, 137-141
Response to drugs, 100, 104
Rhode Island, 184
Risk evaluation, 190
RNA (superconductivity), 86
Roberti, R., 102
S. aureus Wacherts, 128
Sadchikova, M., 184-186
Salamander, 3 5, 42-43, 70
Selye, H., 107
Semiconductor, 21, 25-26, 35, 53
Sentinel Heights, 180
Servantie, B., 99
Shandala, M., 129, 137
Silk, 82
Sjolund, B., 200
Skeletal muscle, 135, 137, 139
Sokolov, 185
Southern, W., 200
Soviet EMF exposure levels, 187-188
Sperm, 141, 143, 185, 187-188
Spindles, 97
Spleen, 138
Stalnaker, R., 84
Stress, 1101 107, 112-113, 120, 183, 189
Suicide, 183-184
Superconductivity, 84-86, 165, 167
Sutherland, P., 200
Synergism, 189
Szent-Gyorgyi, A., 21, 25-26, 35, 80-81, 170
Szmigielski, S., 127
Tabrah, F., 147
Takamaster, T., 84
Teeth, 141
Tendon, 82
Testosterone, 143
Thomas,J., 104
Thompson, W., 102
Thymus, 138
Thyroid gland, 112, 117
Tissue
band structure, 79-81
constants, 86
electronparamagnetic resonance, 81
photo conductivity, 81
piezoelectricity, 81-84
superconductivity, 84-86
water, 84-86
Tolgskaya, M., 102
Tomashevskaya, L., 134
Trace-elementlevels, 139-141
Trachea, 82
Triglycerides, 137-139
TSH (thyroid-stimulatinghormone), 117
Tumor, 41
Tumor growth, 147, 149
Tunneling current (superconductivity), 85
TV signals, 177-179
Udinstev,N., 115-116, 118, 120, 143
Uncontrolled variables, 150-153
Uterus, 143
Valance band, 79-80
Vesalius, A., 5
Vinogradov, G., 129
Vitamin B6 (pyridoxine), 139
Volta, A., 11-13
WBC (white blood cell count), 124
Weapons-detection systems, 182
Weiss, P., 159
Wertheimer, N., 184
Williams, T., 200
Wolf, A., 84
Wolf's Law, 83
Wood, 82
Wound-healing, 147-148
Yasuda, I., 82, 84
Zarat, M., 186-187
Zon, J., 166
Zydecki, S., 187
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