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Adair RK. Constraints on biological effects of weak extremely-low-frequency electromagnetic fields. Physical Review A 1991;43:1039-1048 | Adair RK. Constraints on biological effects of weak extremely-low-frequency electromagnetic fields. Physical Review A 1991;43:1039-1048 | ||
R. Adair, Hypothetical biophysical mechanisms for the action of weak low frequency electromagnetic fields at the cellular level, Radiation Protect Dosim. 72 1997. 271–278 | R. Adair, Hypothetical biophysical mechanisms for the action of weak low frequency electromagnetic fields at the cellular level, Radiation Protect Dosim. 72 1997. 271–278 | ||
Amat A, Rigau J, Waynant RW, Ilev IK, Anders JJ (2006) The electric field induced by light can explain cellular responses to electromagnetic energy: a hypothesis of mechanism. J Photochem Photobiol B 82:152–160. | Amat A, Rigau J, Waynant RW, Ilev IK, Anders JJ (2006) The electric field induced by light can explain cellular responses to electromagnetic energy: a hypothesis of mechanism. J Photochem Photobiol B 82:152–160. | ||
D. Astumian, H. Berg, Direct electric field effects and sequential processes in biosystems, Bioelectrochem. Bioenerg. 25 1991. 455–462. | D. Astumian, H. Berg, Direct electric field effects and sequential processes in biosystems, Bioelectrochem. Bioenerg. 25 1991. 455–462. | ||
Arai A1, Lynch G. Factors regulating the magnitude of long-term potentiation induced by theta pattern stimulation. Brain Res.1992 Dec 11;598(1-2):173-84. | Arai A1, Lynch G. Factors regulating the magnitude of long-term potentiation induced by theta pattern stimulation. Brain Res.1992 Dec 11;598(1-2):173-84. | ||
Ayrapetyan, S.N., Grigorian, K.V., Avansion, A.S., and Stanbltsian, K.V., 1994, Magnetic fields alter electrical properties of solutions and their physiological effects. Bioelectromagnetics 18: 133–142. | Ayrapetyan, S.N., Grigorian, K.V., Avansion, A.S., and Stanbltsian, K.V., 1994, Magnetic fields alter electrical properties of solutions and their physiological effects. Bioelectromagnetics 18: 133–142. | ||
Elias Aizenman, Karen A. Hartnett, and Ian J. Reynolds. Oxygen Free Radicals Regulate NMDA Receptor Function via a Redox Modulatory Site. Neuron, Vol. 5, W-846, December, 1990 | Elias Aizenman, Karen A. Hartnett, and Ian J. Reynolds. Oxygen Free Radicals Regulate NMDA Receptor Function via a Redox Modulatory Site. Neuron, Vol. 5, W-846, December, 1990 | ||
Arne Buschler, Jinzhong Jeremy Goh, and Denise Manahan-Vaughan. Frequency Dependency of NMDA Receptor-Dependent Synaptic Plasticity in the Hippocampal CA1 Region of Freely Behaving Mice. HIPPOCAMPUS 00:000–000 (2012) | |||
Chiabrera A, Bianco B, Caratozzolo F, Giannetti G, Grattarola M, Viviani R. 1985. Electric and magnetic field effects on ligand binding to the cell membrane. In: Chiabrera A, Nicolini C, Schwan HP, editors. Interaction between electromagnetic fields and cells, p 253-280. Plenum: New York, London. | Arne Buschler, Jinzhong Jeremy Goh, and Denise Manahan-Vaughan. Frequency Dependency of NMDA Receptor-Dependent Synaptic Plasticity in the Hippocampal CA1 Region of Freely Behaving Mice. | ||
HIPPOCAMPUS 00:000–000 (2012) | |||
Chiabrera A, Bianco B, Caratozzolo F, Giannetti G, Grattarola M, Viviani R. 1985. Electric and magnetic field effects on ligand binding to the cell membrane. In: Chiabrera A, Nicolini C, Schwan HP, editors. | |||
Interaction between electromagnetic fields and cells, p 253-280. Plenum: New York, London. | |||
James Close. Are stress responses to geomagnetic storms mediated by the cryptochrome compass system? Proc. R. Soc. B (2012) 279, 2081–2090 | James Close. Are stress responses to geomagnetic storms mediated by the cryptochrome compass system? Proc. R. Soc. B (2012) 279, 2081–2090 | ||
Aaron Chih-Hao Chen, Ying-Ying Huang, Praveen R Arany, Michael R. Hamblin. Role of Reactive Oxygen Species in Low Level Light Therapy. In Mechanisms for Low-Light Therapy IV, edited by Michael R. Hamblin, Ronald W. Waynant, Juanita Anders, Proc. of SPIE Vol. 7165, 716502 · © 2009 SPIE. | |||
Aaron Chih-Hao Chen, Ying-Ying Huang, Praveen R Arany, Michael R. Hamblin. Role of Reactive Oxygen Species in Low Level Light Therapy. In Mechanisms for Low-Light Therapy IV, edited by Michael R. Hamblin, Ronald W. Waynant, Juanita Anders, Proc. of SPIE Vol. 7165, 716502 · © 2009 SPIE. | |||
Adair, R.K., 1998, A physical analysis of the ion parametric resonance model. Bioelectromagnetics 19: 181–191. | Adair, R.K., 1998, A physical analysis of the ion parametric resonance model. Bioelectromagnetics 19: 181–191. | ||
Balcavage WX, Alvager T, Swez J, Goff CW, Fox MT, Abdullyava S, King MW (1996). A mechanism for action of extremely low frequency electromagnetic fields on biological systems. Biochem Biophys Res Commun 222:374–378. | Balcavage WX, Alvager T, Swez J, Goff CW, Fox MT, Abdullyava S, King MW (1996). A mechanism for action of extremely low frequency electromagnetic fields on biological systems. Biochem Biophys Res Commun 222:374–378. | ||
Binhi V.N., 2000, Amplitude and frequency dissociation spectra of ion-protein complexes rotating in magnetic fields. Bioelectromagnetics 21: 34–45. | Binhi V.N., 2000, Amplitude and frequency dissociation spectra of ion-protein complexes rotating in magnetic fields. Bioelectromagnetics 21: 34–45. | ||
Binhi VN. 1997a. Interference of ion quantum states within a protein explains weak magnetic field's effect on biosystems. Elec Magnetobiol 16:203-214. | Binhi VN. 1997a. Interference of ion quantum states within a protein explains weak magnetic field's effect on biosystems. Elec Magnetobiol 16:203-214. | ||
Binhi VN. 1997b. The mechanism of magnetosensitive binding of ions by some proteins. Biophysics 42:317-322. | Binhi VN. 1997b. The mechanism of magnetosensitive binding of ions by some proteins. Biophysics 42:317-322. | ||
Binhi VN. 1997c. Shift of spectral peaks of some magnetobiological effects under rotation of biological sample in ELF magnetic field. In: The 1997 Annual Review of Research on Biological Effects of Electric and Magnetic Fields. San Diego, California, November 9-13, p 78. | Binhi VN. 1997c. Shift of spectral peaks of some magnetobiological effects under rotation of biological sample in ELF magnetic field. In: The 1997 Annual Review of Research on Biological Effects of Electric and Magnetic Fields. San Diego, California, November 9-13, p 78. | ||
Binhi VN. 1998a. Interference mechanism for some biological effects of pulsed magnetic fields. Bioelectrochem Bioenerg. 45(1):73-81. | Binhi VN. 1998a. Interference mechanism for some biological effects of pulsed magnetic fields. Bioelectrochem Bioenerg. 45(1):73-81. | ||
Binhi VN. 1999. A formula for frequency and amplitude windows of some ELF and null MF bioeffects follows from the Schroedinger equation. In: Bersani F, editors. Electricity and Magnetism in Biology and Medicine. Plenum Publishing Corporation, p 417-421 | Binhi VN. 1999. A formula for frequency and amplitude windows of some ELF and null MF bioeffects follows from the Schroedinger equation. In: Bersani F, editors. Electricity and Magnetism in Biology and Medicine. Plenum Publishing Corporation, p 417-421 | ||
Binhi VN, Savin AV. 2002. Molecular gyroscopes and biological effects of weak extremely low-frequency magnetic fields. Phys Rev E Stat Nonlin Soft Matter Phys 65:051912. | Binhi VN, Savin AV. 2002. Molecular gyroscopes and biological effects of weak extremely low-frequency magnetic fields. Phys Rev E Stat Nonlin Soft Matter Phys 65:051912. | ||
Blackman, C.F., Benane, S.G., Kinney, L.S., Joines, W.T., and House, D.E., 1982, Effects of ELF fields on calcium-ion efflux from brain tissue in vivo. Rad. Res. 92: 510–520 | Blackman, C.F., Benane, S.G., Kinney, L.S., Joines, W.T., and House, D.E., 1982, Effects of ELF fields on calcium-ion efflux from brain tissue in vivo. Rad. Res. 92: 510–520 | ||
Blackman CF, Blanchard JP, Benane SG, House DE. 1995. The ion parametric resonance model predicts magnetic field parameters that affect nerve cells. FASEB J 9:547-551. | Blackman CF, Blanchard JP, Benane SG, House DE. 1995. The ion parametric resonance model predicts magnetic field parameters that affect nerve cells. FASEB J 9:547-551. | ||
C.F. Blackman, S.G. Benane, D.E. House, and D.J. Elliott. Importance of Alignment Between Local DC Magnetic Field and an Oscillating Magnetic Field in Responses of Brain Tissue In Vitro and In Vivo. Bioelectromagnetics 11 :159-167 (1990) | C.F. Blackman, S.G. Benane, D.E. House, and D.J. Elliott. Importance of Alignment Between Local DC Magnetic Field and an Oscillating Magnetic Field in Responses of Brain Tissue In Vitro and In Vivo. Bioelectromagnetics 11 :159-167 (1990) | ||
Shawn C. Burdette and Stephen J. Lippard. Meeting of the minds: Metalloneurochemistry. PNAS April 1, 2003 vol. 100 no. 7 3605–3610. | Shawn C. Burdette and Stephen J. Lippard. Meeting of the minds: Metalloneurochemistry. PNAS April 1, 2003 vol. 100 no. 7 3605–3610. | ||
