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Electromagnetic Biology and Medicine Volume 33, 2014 - Issue 4
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Research Article

External control of the Drosophila melanogaster lifespan by combination of 3D oscillating low-frequency electric and magnetic fields

Vladimir I. MakarovDepartment of Physics, University of Puerto Rico Rio Piedras, San Juan, Puerto RicoUSACorrespondence[email protected] [email protected]
&
Igor KhmelinskiiDepartment of Chemistry and Pharmacy, Faculty of Science and Technology, CIQA, Universidade do Algarve FaroPortugal
Pages 276-281 | Received 06 Mar 2013, Accepted 16 Jun 2013, Published online: 26 Aug 2013

References

  • Ayrapetyan, G. S., Dadasyan, E. H., Mikayelyan, E. R., et al. (2009). Cell bathing medium as a target for non-thermal effect of MMW on heart muscle contractility. In: PIERS 2009, Moscow, Proceedings, The Electromagnetics Academy, Cambridge, MA. pp. 1057–1060
  • Balzano, Q. (2003). RF nonlinear interactions in living cells-II: Detection methods for spectral signatures. Bioelectromagnetics 24:483–488
  • Banik, S., Bandyopadhyay, S., Ganguly, S. (2003). Bioeffects of microwaves – A brief review. Bioresour. Technol. 87:155–159
  • Barnes, F. (1992). Some engineering models for interactions of electric and magnetic fields with biological systems. Bioelectromagnetics 13:67–85
  • Bolterauer, H., Tuszynski, J. A., Sataric, M. V. (1991). Fröhlich and Davydov regimes in the dynamics of dipolar oscillations of biological membranes. Phys. Rev. A 44:1366–1381
  • Borodin, I., Budagovskii, A., Budagovskaya, O., et al. (2008). Using the effect of photoinduced variability of optical properties of chlorophyll-containing tissues for diagnosing the functional state of plants. Russ. Agr. Sci. 34:357–359
  • Belyaev, I. (2005a). Nonthermal biological effects of microwaves: Current knowledge, further perspective, and urgent needs. Electromagn. Biol. Med. 24:375–403
  • Belyaev, I. Y. (2005b). Non-thermal biological effects of microwaves. Microwave Rev. 11:13–29
  • Belyaev, I., Shcheglov, V., Alipov, E., Ushakov, V. (2000). Nonthermal effects of extremely high-frequency microwaves on chromatin conformation in cells in vivo-dependence on physical, physiological, and genetic factors. IEEE Trans. Microw. Theor. Tech. 48:2172–2179
  • Beneduci, A. (2008). Bioelectrochemistry Research Developments. Huntington, NY: Nova Science Publishers. Review on the mechanisms of interaction between millimeter waves and biological systems. pp. 35–80
  • Berg, H. (2004). Milestones of bioelectromagnetism: Monographs and proceedings. Electromagn. Biol. Med. 23:181–184
  • Betskii, O. V., Lebedeva, N. N. (2004). Clinical Application of Bioelectromagnetic Medicine. New York: Marcel Dekker. pp. 741–760
  • Chiang, H. C., Hodson, A. C. (1950). An analytical study of population growth in D. melanogaster. Ecol. Monogr. 20:173–206
  • Cifra, M., Fields, J. Z., Farhadi, A. (2010). Electromagnetic cellular interactions. Prog. Biophys. Mol. Biol. 30:1–20
  • Creath, K., (2008). A look at some systemic properties of self-bioluminescent emission. Proc. SPIE 7057:705708-1–705708-11
  • Creath, K., Schwartz, G. (2006). Measurement of bioluminescence and thermal fields from humans: Comparison of three techniques for imaging biofields. Proc. SPIE 6285:628505
  • Gouras P. (1958). Spreading depression of activity in amphibian retina. Am. J. Physiol. 195:28–32
  • Jaffe, L. F. (2004). Marine plants may polarize remote fucus eggs via luminescence. Biol. Bull. 207:160
  • Jaffe, L. F. (2005). Marine plants may polarize remote fucus eggs via luminescence. Luminescence 20:414–418
  • Kula, B., Sobczak, A., Kuska, R. (2000). Effects of static and ELF magnetic fields on free-radical processes in rat liver and kidney. Electromagn. Biol. Med. 19:99–105
  • Kulcera, O. (2006). Measurement of electromagnetic yeast cell activity in mm wave region, in Czech, Merení elektromagnetické aktivity kvasinek v pásmu mm vln, Bachelor thesis, Czech Technical University in Prague
  • Kumar, A. (2003). Nonthermal effects of electromagnetic fields at microwave frequencies. CCECE 2003. Canadian Conference on Electrical and Computer Engineering, 2003, IEEE. 1:285–288
  • Makarov, V. I., Khmelinskii, I. (2011). FTIR and UV spectroscopy in real-time monitoring of S. cerevisiae cell culture. Electromagn. Biol. Med. 30:181–197
  • Mayburov, S. N., Volodyaev, I. (2009). Photons production and communications in biological systems. In: PIERS, 2009 in Moscow, Proceedings, The Electromagnetics Academy, Cambridge, MA, pp. 1937–1941
  • McCaig, C. D., Rajnicek, A. M., Song, B., Zhao, M. (2005). Controlling cell behavior electrically: Current views and future potential. Physiol. Rev. 85:943–978
  • McKemmish, L. K., Reimers, J. R., McKenzie, R. H., et al. (2009). Penrose-Hameroff orchestrated objective-reduction proposal for human consciousness is not biologically feasible. Phys. Rev. E 80:021912-1–021912-6
  • Piga, R., Micheletto, R., Kawakami, Y. (2007). Acoustical nanometre-scale vibrations of live cells detected by a near-field optical setup. Opt. Express. 15:5589–5594
  • Pilla, A., Nasser, P., Kaufman, J. (1992). Cell–cell communication significantly decreases thermal noise limits for electromagnetic bioeffects. In: Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society. 14:300–301
  • Scully, M., Svidzinsky, A. (2009). The super of superradiance. Science 325:1510–1511
  • Serpersu, E., Tsong, T. (1984). Activation of electrogenic Rbþ transport of (Na, K)-ATPase by an electric field. J. Biol. Chem. 259:7155–7162
  • Sewchand, L., Rowlands, S. (1983). Specificity of the Frölich interaction of erythrocytes. Phys. Lett. A. 93:363–364
  • Shcheglov, V., Alipov, E., Belyaev, I. (2002). Cell-to-cell communication in response of E. coli cells at different phases of growth to low-intensity microwaves. Biochimica et Biophysica Acta (BBA)-General Subjects. 1572:101–106
  • Shen, X., Mei, W., Xu, X. (1994). Activation of neutrophils by a chemically separated, but optically coupled neutrophil population undergoing respiratory burst. Experientia 50:963–968
  • Solovei, I., Kreysing, M., Lanctot, C., et al. (2009). Nuclear architecture of rod photoreceptor cells adapts to vision in mammalian evolution. Cell 137:356–368
  • Wolkenstein, M. V. (1981). Biophysics. Moscow: Nauka

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