References
- Arafa H. M. M., Abd-Allah A. R. A. Immunomodulatory effects of -carnitine and q10 in mouse spleen exposed to low-frequency high-intensity magnetic field. Toxicology 2003; 187: 171–181
- Bellia P., Carrubba S., . Influence of static and low frequency magnetic field on growth curve of Saccharomyces cerevisiae. Proceedings of 3rd International Workshop on Biological Effects of EMFs, P. Kostarakis, et al. Greece, Kos 2004; 128–132
- Berg H. Problems of weak electromagnetic field effects in cell biology. Bioelectrochem. Bioenerg. 1999; 48: 355–360
- Blank M., Goodmann R. Electromagnetic initiation of transcription at specific DNA sites. J. Cell Biochem. 2001; 81: 689–692
- Bohmann D., Bos T. J., et al. Human proto-oncogene c-Jun encodes a DNA binding protein with structural and functional properties of transcription factor AP-1. Science 1987; 238: 1386–1392
- Czyz J., Nikolova T., et al. Non-thermal effects of power-line magnetic fields (50 Hz) on gene expression levels of pluripotent embryonic stem cells—the role of tumour suppressor p53. Mutat. Res. Genet. Toxicol. Environ. Mutagen. 2004; 557: 63–74
- Finnie J., Gebski V. Neuronal changes produced in mouse brain after short- and long-term exposure to global system for mobile communication (GSM)-like radiofrequency fields. Proceedings of 3rd International Workshop on Biological Effects of EMFs, P. Kostarakis. Greece, Kos 2004; 393–398
- Feychting M., Ahlbom A., Savitz D. Electromagnetic fields and childhood leukaemia. Epidemiology 1998; 9: 225–226
- Fojt L., Strašák L., et al. Comparsion of the low-frequency magnetic field effects on bactaria Escherichia coli, Leclercia adecarboxylata and Staphylococcus aureus. Bioelectrochemistry 2004; 63: 337–341
- Glade N., Tabony J. Brief exposure to high magnetic fields determines microtubule self-organisation by reaction–diffusion processes. Biophys. Chem. 2005; 115: 29–35
- Ham L. H., Van N. T. K., Vinh D. N. The impact of magnetic field on in vitro culture systems. Proceedings of 3rd International Workshop on Biological Effects of EMFs, P. Kostarakis. Greece, Kos 2004; 134–141
- Harrison G. H., Balcer-Kubiczek E. K., et al. Kinetics of gene expression following exposure to 60 Hz, 2 mT magnetic fields in three human cell lines. Bioelectrochem. Bioenerg. 1997; 43: 1–6
- Hashish, A. H., El-Missiry, M. A. et al. (2007). Assessment of biological changes of continuous whole body exposure to static magnetic field and extremely low frequency electromagnetic fields in mice. Ecotoxicol. Environ. Safety. In press.
- Hausmann A., Marksteiner J., et al. Magnetic stimulation induces neuronal c-Fos via tetrodotoxin-sensitive sodium channels in organotypic cortex brain slices of the rat. Neurosci. Lett. 2001; 310: 105–108
- Jahreisn G. P., Johnson P. G., et al. Absence of 60-Hz, 0.1-mT magnetic field-induced changes in oncogene transcription rates or levels in CEM-CM3 cells. Biochimica et Biophysica Acta (BBA)—Gene Struct. Express. 1998; 1443: 334–342
- Kabuto H., Yokoi I., et al. Effects of an in vivo 60 Hz magnetic field on monoamine levels in mouse brain. Pathophysiology 2000; 7: 115–119
- Kroupová J., Bártová E., et al. Low-frequency magnetic field effect on cytoskeleton and chromatin. Bioelectrochemistry 2007; 70: 96–100
- Kurien B. T., Scofield R. H. Western blotting. Methods 2006; 38: 283–293
- Lange K. Microvillar ion channels: cytoskeletal modulation of ion fluxes. J. Theoret. Biol. 2005; 206: 561–584
- Lockwood D. R., Kwon B., et al. Behavioral effects of static high magnetic fields on unrestrained and restrained mice. Physiol. Behav. 2003; 78: 635–640
- Lupke M., Frahm J. Gene expression analysis of ELF-MF exposed human monocytes indicating the involvement of the alternative activation pathway. Biochimica et Biophysica Acta (BBA)—Molec. Cell Res. 2006; 1763: 402–412
- Madec F., Billaudel B., et al. Effect of ELF and static magnetic fields on calcium oscillations in islets of Langerhans. Bioelectrochemistry 2003; 60: 73–80
- Mehedintu M., Berg H. Proliferation response of yeast Saccharomyces cerevisiae on electromagnetic field parameters. Biolelectrochem. Bioenerg. 1997; 43: 67–70
- Miyakoshi J., Moria Y., et al. Suppression of heat-induced hsp-70 by simultaneous exposure to 50 mT magnetic field. Life Sci. 2000; 66: 1187–1196
- Morrissey J. J., Raney S., et al. IRIDIUM exposure increases c-Fos expression in the mouse brain only at levels which likely result in tissue heating. Neuroscience 1999; 92: 1539–1546
- Novák J., Strašák L., et al. Effects of low-frequency magnetic fields on the viability of yeast Saccharomyces cerevisiae. Bioelectrochemistry 2007; 70: 115–121
- Phillips J. L., Haggren W., et al. Magnetic field-induced changes in specific gene transcription. Biochimica et Biophysical Acta 1992; 1132: 140–144
- Repacholi M. H., Greenebaum B. Interaction of static and extremely-low-frequency electric and magnetic fields with living systems: health effects and research needs. Bioelectromagnetics 1999; 20: 133–160
- Strašák L., Fojt L., Vetterl V. Effects of 50 Hz magnetic fields on the viability of different bacterial strains. Electromagn. Biol. Med. 2005; 24: 293–300
- Strašák L., Vetterl V., Šmarda J. Effect of low-frequency magnetic fields on bacteria E. coli. Bioelectrochem. Bioenerg. 2002; 55: 161–164
- Volpe P., Eremenko T. DNA replication and repair in a magnetically shielded room vs. a low-frequency/low-intensity magnetic irradiation. Proceedings of 3rd International Workshop on Biological Effects of EMFs, P. Kostarakis. Greece, Kos 2004; 193–200