As at 1 June 2001 Prepared originally by Lou Heyrick, to whom we are deeply indebted for this list. Note: these are a mixture of in vitro and in vivo studies, with positional and theoretical papers included, and are, for the sake of completeness, not necessarily reflecting positive or adverse effects.
Adair, R.K. (1991)
CONSTRAINTS ON BIOLOGICAL EFFECTS OF WEAK EXTREMELY-LOW-FREQUENCY ELECTROMAGNETIC FIELDS
Phys. Rev. A, Vol. 43, No. 2, pp. 1039-1048
0005
Adey, W.R., C.V. Byus, C.D. Cain, R.J. Higgins, R.A. Jones, C.J. Kean, N. Kuster:, A. MacMurray, R.B. Stagg, G, Zimmerman, J.L. Phillips, and W. Haggren (1999)
SPONTANEOUS AND NITROSOUREA-INDUCED PRIMARY TUMORS OF THE CENTRAL NERVOUS SYSTEM IN FISCHER 344 RATS CHRONICALLY EXPOSED TO 836 MHz MODULATED MICROWAVES
Radiat. Res., Vol. 152, pp. 293-302
1298 [VIV]
Adey, W.R., C.V. Byus, C.D. Cain, R.J. Higgins, R.A. Jones, C.J. Kean, N. Kuster A. MacMurray, R.B. Stagg, and G. Zimmerman (2000)
SPONTANEOUS AND NITROSOUREA-INDUCED PRIMARY TUMORS OF THE CENTRAL NERVOUS SYSTEM IN FISCHER 344 RATS EXPOSED TO FREQUENCY-MODULATED MICROWAVE FIELDS
Cancer Res., Vol. 60, pp. 1857-1863
1406 [VIV]
Akoev, I.G., S.I. Alekseev, V.V. Tiazhelov, B.S. Fomenko, B. S., and V.L. Shnyrov (1986)
PRIMARY MECHANISMS OF THE ACTION OF RADIO-FREQUENCY FIELDS
In BIOLOGICAL EFFECTS OF ELECTROMAGNETIC FIELDS. THEIR APPLICATIONS AND STANDARDIZATION,
pp. 4-14, USSR Acad. of Sciences, Res. Center for Biological Studies, Inst. of Biological Physics, Pushchino
0537
Albanese, R., J. Blaschak, R. Medina, and J. Penn (1994)
ULTRASHORT ELECTROMAGNETIC SIGNALS: BIOPHYSICAL QUESTIONS, SAFETY ISSUES, AMD MEDICAL OPPORTUNITIES
Aviat., Space, and Environ. Med., pp. A116-A120
0479
Antipenko, E.N. and I.V. Koveshnikova (1988)
CYTOGENETIC EFFECTS OF MICROWAVES OF NONTHERMAL INTENSITY IN MAMMALS
Dokl. Biol. Sci. Transl. Dokl. Acad. Nauk. SSSR) Vol. 296, No. 3, pp. 518-520
0011 [VIV]
Astumian, R.D., J.C. Weaver, and R.K. Adair (1995)
RECTIFICATION AND SIGNAL AVERAGING OF WEAK ELECTRIC FIELDS BY BIOLOGICAL CELLS
Proc. Nat. Acad. Sci., Vol. 92, pp. 3740-3743
1049
Baillie, H.D. (1970a)
THERMAL AND NONTHERMAL CATARACTOGENESIS BY MICROWAVES In S.F. Cleary (ed.), BIOLOGICAL EFFECTS AND HEALTH IMPLICATIONS OF MICROWAVE RADIATION,
Dept. of Health, Education, and Welfare, Washington:, D.C., HEW Publication BRH/DBE 70-2, pp. 59-65
0995 [VIV]
Barnes, F.S. and C.-L.J. Hu (1977)
MODEL FOR SOME NONTHERMAL EFFECTS OF RADIO AND MICROWAVE FIELDS ON BIOLOGICAL MEMBRANES
IEEE Trans. Microwave Theory Tech., Vol. 25, No. 9, pp. 742-746
0858
Barnes, F.S. (1984)
CELL MEMBRANE TEMPERATURE RATE SENSITIVITY PREDICTED FROM THE NERNST EQUATION
Bioelectromagnetics, Vol. 5, No. 1, pp. 113-115
0859
Bawin, S.M., L.K. Kaczmarek, and W.R. Adey (1975)
EFFECTS OF MODULATED VHF FIELDS ON THE CENTRAL NERVOUS SYSTEM
In P.W. Tyler (ed.), BIOLOGIC EFFECTS OF NONIONIZING RADIATION
Ann. N.Y.Acad. Sci., Vol. 247, pp. 74-81
0862 [VIT]
Bawin, S.M. and W.R. Adey (1976a)
INTERACTIONS BETWEEN NERVOUS TISSUES AND WEAK ENVIRONMENTAL ELECTRIC FIELDS
In C.C. Johnson and M.L. Shore (eds.), BIOLOGICAL EFFECTS OF ELECTROMAGNETIC WAVES,
U.S. Dept. of Health, Education, and Welfare, Washington, D.C., HEW Publication (FDA) 77-8010, Vol. 1, pp. 323-330
1002 [VIT]
Bawin, S.M. and W.R. Adey (1976b)
SENSITIVITY OF CALCIUM BINDING IN CEREBRAL TISSUE TO WEAK ENVIRONMENTAL ELECTRIC FIELDS OSCILLATING AT LOW FREQUENCIES
Proc. Nat. Acad. Sci., Vol. 73, No. 6, pp. 1999-2003
1003 [VIT]
Behari, J., K.K. Kunjilwar, K. K. and S. Pyne (1998)
INTERACTION OF LOW LEVEL MODULATED RF RADIATION WITH A+-K+-ATPase
Bioelectrochem. Bioenerg., Vol. 47, No. 2, pp. 247-252
1314 [VIV]
Belyaev, I. Ya., V.S. Shcheglov, Ye. D. Alipov, and V.A. Polunin (1996)
RESONANCE EFFECT OF MILLIMETER WAVES IN THE POWER RANGE FROM 10-19 TO 3 X 10-3 W/cm2 ON ESCHERICHIA coli CELLS AT DIFFERENT CONCENTRATIONS
Bioelectromagnetics, Vol. 17, No. 4, pp. 312-321
1172 [VIT]
Belyaev, I. Ya., V.S. Shcheglov, Ye. D. Alipov, and V.L Ushakov (1997)
REPLY TO COMMENTS OF OSEPCHUK AND PETERSEN
Bioelectromagnetics, Vol. 18, No. 7, pp. 529-530
1174 [VIT]
Bergqvist, B., L. Arvidsson, E. Pettersson, S. Galt, E. Saalman, Y. Hamnerius, and B. Norden (1994)
EFFECT OF MICROWAVE RADIATION ON PERMEABILITY OF LIPOSOMES. EVIDENCE AGAINST NON-THERMAL LEAKAGE
Biochim. Biophys. Acta, Vol. 1201, No. 1, pp. 51-54
0483
Bernhardt, J.H. and H. Pauly (1973)
ON THE GENERATION OF POTENTIAL DIFFERENCES ACROSS THE MEMBRANES OF ELLIPSOIDAL CELLS IN AN ALTERNATING ELECTRIC FIELD
Biophysik, Vol. 10, pp. 89-98
0417
Blackman, C.F., J.A. Elder, C.M. Weil, S.G. Benane, D.C. Eichinger, and D.E. House (1979)
INDUCTION OF CALCIUM-ION EFFLUX FROM BRAIN TISSUE BY RADIO-FREQUENCY RADIATION: EFFECTS OF MODULATION FREQUENCY AND FIELD STRENGTH
Radio Sci., Vol. 14, No. 6S, pp. 93-98
0573
Blackman, C.F., S.G. Benane, D.E. House, and W.T. Joines (1985a)
EFFECTS OF ELF (1-120 Hz) AND MODULATED (50 Hz) RF FIELDS ON THE EFFLUX OF CALCIUM IONS FROM BRAIN TISSUE
Bioelectromagnetics, Vol. 6, No. 1, pp. 1-11
0426
Blackman, C.F., S.G. Benane, J.R. Rabinowitz, D.E. House, and W.T. Joines (1985b)
A ROLE FOR THE MAGNETIC FIELD IN THE RADIATION-INDUCED EFFLUX OF CALCIUM IONS FROM BRAIN TISSUE IN VITRO
Bioelectromagnetics, Vol. 6, No. 4, pp. 327-337
0576
Blackman, C.F., S.G. Benane, D.J. Elliot, D.E. House, and M.M. Pollock (1988a)
INFLUENCE OF ELECTROMAGNETIC FIELDS ON THE EFFLUX OF CALCIUM IONS FROM BRAIN TISSUE IN VITRO: A THREE-MODEL ANALYSIS CONSISTENT WITH THE FREQUENCY RESPONSE UP TO 510 Hz
Bioelectromagnetics, Vol. 9, No. 3, pp. 215-227
0016
Blackman, C.F., L.S. Kinney, D.E. House, and W.T. Joines (1989)
MULTIPLE POWER-DENSITY WINDOWS AND THEIR POSSIBLE ORIGIN
Bioelectromagnetics, Vol. 10, No. 2, pp. 115-128
0017
Blackman, C.F., S.G. Benane, and D.E. House (1991)
THE INFLUENCE OF TEMPERATURE DURING ELECTRIC- AND MAGNETIC-FIELD-INDUCED ALTERATION OF CALCIUM-ION RELEASE FROM IN VITRO BRAIN TISSUE
Bioelectromagnetics, Vol. 12, No. 3, pp. 173-182
0018
Chagnaud, J.-L., J.-M. Moreau, and B. Veyret (1999)
NO EFFECT OF SHORT-TERM EXPOSURE TO GSM-MODULATED LOW-POWER MICROWAVES ON
BENZO(a)PYRENE-INDUCED TUMOURS IN RAT
Int. J. Radiat. Biol., Vol. 75, No. 10, pp. 1251-1256
1326 [VIV]
Cooper, M.S. and N.M. Amer (1983)
THE ABSENCE OF COHERENT VIBRATIONS IN THE RAMAN SPECTRA OF LIVING CELLS
Phys. Lett., Vol. 98A, No. 3, pp. 138-142
0601
Davis, C.C., G.S. Edwards, M.L. Swicord, J. Sagripanti, and J. Saffer (1986)
DIRECT EXCITATION OF INTERNAL MODES OF DNA BY MICROWAVES
Bioelectrochem. Bioenerg., Vol. 16, pp. 63-76
1052
Davis, C.C. (1987) XXX
MICROWAVE ABSORPTION CHARACTERISTICS OF DNA
Office of Naval Research Contract No. N00014-84-K-0550, Annual Report, 1 Aug. 1985 to 31 July 1986
0886
de Pomerai D., C. Daniells, H. David, J. Allan, I. Duce, M. Mutwakil, D. Thomas, P. Sewell, J. Tattersall, D. Jones, and P. Candido (2000)
NONTHERMAL HEAT SHOCK RESPONSE TO MICROWAVES
Nature, Vol. 405, May 25, 2000, pp. 417-418.
1407 [VIV]
Eulitz, C., P. Ullsperger, G. Freude, and T. Elbert (1998)
MOBILE PHONES MODULATE RESPONSE PATTERNS OF HUMAN BRAIN ACTIVITY
NeuroReport, Vol. 9, No. 14, pp. 3229-3232
1283 [VIV]
Frei, M.R., R.E. Berger, S.J. Dusch, V. Guel, J.R. Jauchem, J.H. Merritt, and M.A. Stedham (1998)
CHRONIC EXPOSURE OF CANCER-PRONE MICE TO LOW-LEVEL 2450 MHz RADIOFREQUENCY RADIATION
Bioelectromagnetics, Vol. 19, No. 1, pp. 20-31
1182 [VIV]
Goodman, E.M., B. Greenebaum, and M.T. Marron (1995)
EFFECTS OF ELECTROMAGNETIC FIELDS ON MOLECULES AND CELLS
Int. Rev. Cytol., Vol. 158, pp. 279-338
1057
Greengard, P. (1982)
EFFECTS OF ELECTROMAGNETIC RADIATION ON CALCIUM IN THE BRAIN
Aeromed. Rev. 2-82, U. S. Air Force School of Aerospace Medicine, Brooks AF Base,TX, July 1982
1449 [PERIPH (VIT, CALCIUM EFFLUX)] ???
Grodsky, I.T. (1975)
POSSIBLE PHYSICAL SUBSTRATES FOR THE INTERACTION OF ELECTROMAGNETIC FIELDS WITH BIOLOGIC MEMBRANES
In P.W. Tyler (ed.), Ann. N.Y. Acad. Sci., Vol. 247, pp. 117-124
0902
Grundler, W., F. Keilmann, and H. Froehlich (1977)
RESONANT GROWTH RATE RESPONSE OF YEAST CELLS IRRADIATED BY WEAK MICROWAVES
Phys. Lett., Vol. 62A, No. 6, pp. 463-466
0653
Grundler, W. and F. Keilmann (1978)
NONTHERMAL EFFECTS OF MILLIMETER MICROWAVES ON YEAST GROWTH
Z. Naturforsch., Vol. 33C, pp. 15-22
0440
Grundler, W., F. Keilmann, V. Putterlik, and D. Strube (1982)
RESONANT-LIKE DEPENDENCE OF YEAST GROWTH RATE ON MICROWAVE FREQUENCIES
Brit. J. Cancer Suppl., Vol. 45, No. 5, pp. 206-208
0297
Grundler, W. and F. Keilmann (1989)
RESONANT MICROWAVE EFFECT ON LOCALLY FIXED YEAST MICROCOLONIES
Z. Naturforsch. Vol. 44C, pp. 863-866
0441
Grundler, W. and F. Kaiser (1992)
EXPERIMENTAL EVIDENCE FOR COHERENT EXCITATIONS CORRELATED WITH CELL GROWTH
Nanobiology
0399
Grundler, W., F. Kaiser, F. Keilmann, and J. Walleczek (1992)
MECHANISMS OF ELECTROMAGNETIC INTERACTION WITH CELLULAR SYSTEMS
Naturwiss., Vol. 79, pp. 551-559
0442
Higashikubo, R., V.O. Culbreth, D.R. Spitz, M.C. LaRegina, W.F. Pickard, W.L. Straube, E.G. Moros, and J.L. Roti Roti (1999)
RADIOFREQUENCY ELECTROMAGNETIC FIELDS NO EFFECT ON THE IN VIVO PROLIFERATION OF THE 9L BRAIN TUMOR
Radiat. Res., Vol. 152, pp. 665-671
1353 [VIV]
Hu, C.J. and F.S. Barnes (1975)
A SIMPLIFIED THEORY OF PEARL CHAIN EFFECTS
Radiat. Environ. Biophys., Vol. 12, No. 1, pp. 71-76
0909
Illinger, K.H. (1982)
SPECTROSCOPIC PROPERTIES OF IN VIVO BIOLOGICAL SYSTEMS: BOSON RADIATIVE EQUILIBRIUM WITH STEADY-STATE NONEQUILIBRIUM MOLECULAR SYSTEMS
Bioelectromagnetics, Vol. 3, No. 1, pp. 9-16
0664
Ivaschuk, O.I., R.A. Jones, T. Ishida-Jones, W. Haggren, W.R. Adey, and J.L. Phillips (1997)
EXPOSURE OF NERVE GROWTH FACTOR-TREATED PC12 RAT PHEOCHROMOCYTOMA CELLS TO A MODULATED RADIOFREQUENCY FIELD AT 836.55 MHz: EFFECTS ON c-jun AND c-fos EXPRESSION
Bioelectromagnetics, Vol. 18, No. 3, pp. 223-229
1136
Kaczmarek, L.K. (1977)
CATION BINDING MODELS FOR THE INTERACTION OF MEMBRANES WITH EM FIELDS
Neurosci. Res. Program Bull., Vol. 15, No. 1, pp. 54-60
0917
Kaiser, F. (1992)
BIOPHYSICAL MODELS RELATED TO FROEHLICH EXCITATIONS
Nanobiology, Vol. 1, pp. 149-161
0400
Keilmann, F. and D.B. Kell (1983)
COHERENT EXCITATION IN BIOLOGY
Nature, Vol. 301, 24 Feb 1983, pp. 656-657
0303
Klug, S., M. Hetscher, S. Giles, S. Kohlsmann, and K. Kramer (1997)
THE LACK OF EFFECTS OF NONTHERMAL RF ELECTROMAGNETIC FIELDS ON THE DEVELOPMENT OF RAT EMBRYOS GROWN IN CULTURE
Life Sci., Vol. 61, No. 18, pp. 1789-1802
1394
Kubinyi, G., G. Thuróczy, J. Bakos, E. Bölöni, H. Sinay, and L. Szabó (1996)
EFFECT OF CONTINUOUS-WAVE AND AMPLITUDE-MODULATED 2.45 GHz MICROWAVE RADIATION ON THE LIVER AND BRAIN AMINOACYL-TRANSFER RNA SYNTHETASES OF IN UTERO EXPOSED MICE
Bioelectromagnetics, Vol. 17, No. 6, pp. 497-503
1105 [VIV]
Kunjilwar, K.K. and J. Behari (1993)
EFFECT OF AMPLITUDE-MODULATED RADIO FREQUENCY RADIATION ON CHOLINERGIC SYSTEM OF DEVELOPING RATS
Brain Res., Vol. 61, pp. 321-324
1181 [VIV]
Kwee, S. and P. Raskmark (1998)
CHANGES IN CELL PROLIFERATION DUE TO ENVIRONMENTAL NON-IONIZING RADIATION 2. MICROWAVE RADIATION
Bioelectrochem. & Bioenerg., Vol. 44, No. 2, pp. 251-255
1396
Lai, H. and N.P. Singh (1996a)
REPLY TO "COMMENT ON `ACUTE LOW-INTENSITY MICROWAVE EXPOSURE INCREASES DNA SINGLE-STRAND BREAKS IN RAT BRAIN CELLS'" [by G.M. Williams]
Bioelectromagnetics, Vol. 17, No. 2, p. 166
1208 [PERIPH (COMMENT)]
Lai, H. and N.P. Singh (1996b)
SINGLE- AND DOUBLE-STRAND DNA BREAKS IN RAT BRAIN CELLS AFTER ACUTE EXPOSURE TO RADIOFREQUENCY ELECTROMAGNETIC RADIATION
Int. J. Radiat. Biol., Vol. 69, No. 4, pp. 513-521
1116
Lai, H. and N.P. Singh (1997)
MELATONIN AND A SPIN-TRAP COMPOUND BLOCK RADIOFREQUENCY ELECTROMAGNETIC RADIATION-INDUCED DNA STRAND BREAKS IN RAT BRAIN CELLS
Bioelectromagnetics, Vol. 18, No. 6, pp. 446-454
1149 [VIV]
Lary, J.M., D.L. Conover, and P.H. Johnson (1983b)
ABSENCE OF EMBRYOTOXIC EFFECTS FROM LOW-LEVEL (NONTHERMAL) EXPOSURE OF RATS TO 100 MHz RADIOFREQUENCY RADIATION
Scand. J. Work Environ. Health, Vol. 9, pp. 120-127
1433 [VIV]
Lawrence, A.F. and W.R. Adey (1982)
NONLINEAR WAVE MECHANISMS IN INTERACTIONS BETWEEN EXCITABLE TISSUE AND ELECTROMAGNETIC FIELDS
Neurol. Res., Vol. 4, Nos. 1-2, pp. 115-153
0930
Lindauer, G.A., L.-M. Liu, G.W. Skewes, and F.J. Rosenbaum (1974)
FURTHER EXPERIMENTS SEEKING EVIDENCE OF NONTHERMAL BIOLOGICAL EFFECTS OF MICROWAVE RADIATION
IEEE Trans. Microwave Theory Tech., Vol. 22, No. 8, pp. 790-793
1434
Litovitz, T.A., D. Krause, M. Penafiel, E.C. Elson, and J.M. Mullins (1993)
THE ROLE OF COHERENCE TIME IN THE EFFECT OF MICROWAVES ON ORNITHINE DECARBOXYLASE ACTIVITY
Bioelectromagnetics, Vol. 14, No. 5, pp. 395-403
0936
Litovitz, T.A., C.J. Montrose, P. Doinov, K.M. Brown, and M. Barber (1994)
SUPERIMPOSING SPATIALLY COHERENT ELECTROMAGNETIC NOISE INHIBITS FIELD-INDUCED ABNORMALITIES IN DEVELOPING CHICK EMBRYOS
Bioelectromagnetics, Vol. 15, No. 2, pp. 105-113
1029
Litovitz, T.A., L.M. Penafiel, J.M. Farrel, D. Krause, R. Meister, and J.M. Mullins (1997)
BIOEFFECTS INDUCED BY EXPOSURE TO MICROWAVES ARE MITIGATED BY SUPERPOSITION OF ELF NOISE
Bioelectromagnetics, Vol. 18, No. 6, pp. 422-430
1150
Liu, L.-M. and S.F. Cleary (1995)
ABSORBED ENERGY DISTRIBUTION FROM RADIOFREQUENCY ELECTROMAGNETIC RADIATION IN A MAMMALIAN CELL MODEL: EFFECT OF MEMBRANE-BOUND WATER
Bioelectromagnetics, Vol. 16, No. 3, pp. 160-171
0510
Malyapa, R.S., E.W. Ahern, W.L. Straube, E.G. Moros, W.F. Pickard, and J.L. Roti Roti (1997a)
MEASUREMENT OF DNA DAMAGE AFTER EXPOSURE TO 2450 MHz ELECTROMAGNETIC RADIATION
Radiat. Res., Vol. 148, No. 6, pp. 608-617
1179 [VIV]
Malyapa, R.S., E.W. Ahern, W.L. Straube, E.G. Moros, W.F. Pickard, and J.L. Roti Roti (1997b)
MEASUREMENT OF DNA DAMAGE AFTER EXPOSURE TO ELECTROMAGNETIC RADIATION IN THE CELLULAR PHONE COMMUNICATION FREQUENCY BAND (835.62 AND 847.74 MHz)
Radiat. Res., Vol. 148, No. 6, pp. 618-627
1180 [VIV]
Malyapa, R.S., E.W. Ahern, W.L. Straube, M. LaRegina, W.F. Pickard, and J.L. Roti Roti (1998a)
DNA DAMAGE IN RAT BRAIN CELLS AFTER IN VIVO EXPOSURE TO 2.450 MHz ELECTROMAGNETIC RADIATION AND THE VARIOUS METHODS OF EUTHANASIA
Radiat. Res., Vol. 149, pp. 637-645
1189 [VIV]
Markin, V.S., L. Daosheng, M.D. Rosenberg, and T.Y. Tsong (1992)
RESONANCE TRANSDUCTION OF LOW LEVEL PERIODIC SIGNALS BY AN ENZYME: AN OSCILLATORY ACTIVATION BARRIER MODEL
Biophys. J., Vol. 61, pp. 1045-1049
0404
Mayers, C.P. and J.A. Habeshaw (1973)
DEPRESSION OF PHAGOCYTOSIS: A NON-THERMAL EFFECT OF MICROWAVE RADIATION AS A POTENTIAL HAZARD TO HEALTH
Int. J. Radiat. Biol., Vol. 24, No. 5, pp. 449-461
0719
Merritt, J.H., W.W. Shelton, and A.F. Chamness (1982)
ATTEMPTS TO ALTER 45Ca++ BINDING TO BRAIN TISSUE WITH PULSE-MODULATED MICROWAVE ENERGY
Bioelectromagnetics, Vol. 3, No. 4, pp. 475-478
0728
Mittler, S. (1977)
FAILURE OF CHRONIC EXPOSURE TO NON-THERMAL FM RADIOWAVES TO MUTATE DROSOPHILA
J. Heredity, Vol. 68, pp. 257-288
Miura, M. and J. Okada (1991)
NON-THERMAL VASODILATATION BY RADIO FREQUENCY BURST-TYPE ELECTROMAGNETIC FIELD RADIATION IN THE FROG
J. Physiol., Vol. 435, pp. 257-273
0420 [VIV]
Myers, R.D. and D.H. Ross (1981)
RADIATION AND BRAIN CALCIUM: A REVIEW AND CRITIQUE
Neurosci. Biobehav. Rev., Vol. 5, No. 4, pp. 503-543
1439 [PERIPH (VIT, CALCIUM EFFLUX)]
Neshev, N.N. and E.I. Kirilova (1994)
POSSIBLE NONTHERMAL INFLUENCE OF MILLIMETER WAVES ON PROTON TRANSFER IN BIOMEMBRANES
Electro. Magnetobiol., Vol. 13, No. 3, pp. 191-194
0518
Neshev, N.N. and E.I. Kirilova (1995)
SYNCHRONIZATION OF FUNCTIONING IN ENZYME REACTIONS BY AMPLITUDE-MODULATED ELECTROMAGNETIC FIELD
Electro. Magnetobiol. Vol. 14, No. 1, pp. 17-21
0519
Osepchuk, J.M. and R.C. Petersen (1997)
COMMENTS ON "RESONANCE EFFECT OF MILLIMETER WAVES IN THE POWER RANGE FROM 10-19 TO 3 X 10-3 W/cm2 ON ESCHERICHIA coli CELLS AT DIFFERENT CONCENTRATIONS,"
Bioelectromagnetics, Vol. 18, No. 7, pp. 527-528
1173
Pakhomov, A.G., B.V. Dubovichk, V.E. Kolupayev, and A.N. Pronkevichh (1991)
ABSENCE OF NON-THERMAL MICROWAVE EFFECTS ON THE FUNCTION OF GIANT NERVE FIBERS
J. Bioelectricity, Vol. 10, Nos. 1 & 2, pp. 185-203
0172
Penafiel, L.M., T. Litovitz, D. Krause, A. Desta, and J.M. Mullins (1997)
ROLE OF MODULATION ON THE EFFECT OF MICROWAVES ON ORNITHINE DECARBOXYLASE ACTIVITY IN L929 CELLS
Bioelectromagnetics, Vol. 18, No. 2, pp. 132-141
1138
Pickard, W.F. and F.J. Rosenbaum (1978)
BIOLOGICAL EFFECTS OF MICROWAVES AT THE MEMBRANE LEVEL: TWO POSSIBLE ATHERMAL ELECTROPHYSIOLOGICAL MECHANISMS AND A PROPOSED EXPERIMENTAL TEST
Math. Biosci., Vol. 39, pp. 235-253
1339
Porcelli, M., G. Cacciapuoti, S. Fusco, R. Massa, G. d'Ambrosio, C. Bertoldo, M. De Rosa, and V. Zappia (1997)
NON-THERMAL EFFECTS OF MICROWAVES ON PROTEINS: THERMOPHILIC ENZYMES AS MODEL SYSTEM
FEBS Lett., Vol. 402, Nos. 2-3, pp. 102-106
1165
Repacholi, M.H., A. Basten, V. Gebski, D. Noonan, J. Finnie, and A.W. Harris (1997)
LYMPHOMAS IN Em-Pim1 TRANSGENIC MICE EXPOSED TO PULSED 900 MHz ELECTROMAGNETIC FIELDS
Radiat. Res., Vol. 147, No. 5, pp. 631-640
1130 [VIV]
Romano-Spica, V., N. Mucci, C.L. Ursini, A. Ianni, and N.K. Bhat (2000)
ETS 1 ONCOGENE INDUCTION BY ELF-MODULATED 50 MHz RADIOFREQUENCY ELECTROMAGNETIC FIELD
Bioelectromagnetics, Vol. 21, No. 1, pp. 8-18
1362
Saalman, E., B. Norden, L. Arvidsson, Y. Hamnerius, P. Hojevik, K.E. Connell, and T. Kurucsev (1991)
EFFECT OF 2.45 GHz MICROWAVE RADIATION ON PERMEABILITY OF UNILAMELLAR LIPOSOMES TO 5(6)-CARBOXYFLUORESCEIN. EVIDENCE OF NON-THERMAL LEAKAGE
Biochim. Biophys. Acta, Vol. 1064, No. 1, pp. 124-130
0976
Saito, K. and K. Suzuki (1995)
MALDEVELOPMENT OF EARLY CHICK EMBRYOS INDUCED BY NON-THERMOGENIC DOSE RADIO FREQUENCY RADIATION AT 428 MHz FOR THE FIRST 48 HOURS
Cong. Anom., Vol. 35, pp. 275-283
1215 [VIV]
Salford, L.G., A. Brun, J.L. Eberhardt, and B.R.R. Persson (1993b)
PERMEABILITY OF THE BLOOD-BRAIN BARRIER INDUCED BY 915 MHz ELECTROMAGNETIC RADIATION, CONTINUOUS WAVE AND MODULATED AT 8, 16, 50, AND 200 Hz
Bioelectrochem. & Bioenerg., Vol. 30, pp. 293-301
1216 [VIV]
Schmidt, R.E., J.H. Merritt, and K.H. Hardy (1984)
IN UTERO EXPOSURE TO LOW-LEVEL MICROWAVES DOES NOT AFFECT RAT FOETAL DEVELOPMENT
Int. J. Radiat. Biol., Vol. 46, No. 4, pp. 383-386
1397 [VIV]
Shelton, W.W., Jr. and J.H. Merritt (1981)
IN VITRO STUDY OF MICROWAVE EFFECTS ON CALCIUM EFFLUX IN RAT BRAIN TISSUE
Bioelectromagnetics, Vol. 2, No. 2, pp. 161-167
0785
Sheppard, A.R., S.M. Bawin, and W.R. Adey (1979)
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