New perspectives in cell communication: Bioelectromagnetic interactions.

This paper explores physical signalling in biological communications, the so-called biophysical pathways, and especially the role of electromagnetic signalling in cell-cell interactions. The experiments were designed to evaluate whether different cell populations physically interfere when incubated in separate Petri dishes placed in close proximity. Two different cell populations, immortalized mouse fibroblasts (NIH3T3) and adult human microvascular endothelial cells (HMVECad) were selected and seeded in separate polystyrene Petri dishes. Dishes seeded with NIH3T3 were then placed on top of those seeded with HMVECad at distances of 4mm and 11mm. A black filter was placed between dishes containing the two cell populations in another experiment, to prevent transmission of electromagnetic radiation between the two. Cell number and morphology of NIH3T3 and endothelial cells were found to be modified in dishes without the black filter, suggesting that specific signals emitted by the cells were transmitted through the polystyrene wall, affecting cell proliferation rate and morphology, even though the cells were growing in separate dishes.

[1]  J. Pokorný ENDOGENOUS ELECTROMAGNETIC FORCES IN LIVING CELLS: IMPLICATIONS FOR TRANSFER OF REACTION COMPONENTS , 2001 .

[2]  Fabrice Rappaport,et al.  Visualization of coherent nuclear motion in a membrane protein by femtosecond spectroscopy , 1993, Nature.

[3]  J. Tuszynski,et al.  Modelling the Role of Intrinsic Electric Fields in Microtubules as an Additional Control Mechanism of Bi-directional Intracellular Transport , 2008, Cell Biochemistry and Biophysics.

[4]  I. Jerman,et al.  Deep Significance of the Field Concept in Contemporary Biomedical Sciences , 2009, Electromagnetic biology and medicine.

[5]  Michal Cifra,et al.  Electric field generated by axial longitudinal vibration modes of microtubule , 2010, Biosyst..

[6]  H. Fröhlich Long-range coherence and energy storage in biological systems , 1968 .

[7]  L. Morbidelli,et al.  The effect of hydroxyapatite nanocrystals on microvascular endothelial cell viability and functions. , 2006, Journal of biomedical materials research. Part A.

[8]  C. Rossi,et al.  The optical characterization of chromophoric dissolved organic matter using wavelength distribution of absorption spectral slopes , 2009 .

[9]  C. Rossi,et al.  Morphological anomalies in pollen tubes of Actinidia deliciosa (kiwi) exposed to 50 Hz magnetic field , 2005, Bioelectromagnetics.

[10]  C. Bonechi,et al.  The effect of exposure to high flux density static and pulsed magnetic fields on lymphocyte function , 2003, Bioelectromagnetics.

[11]  G. Albrecht‐Buehler,et al.  Surface extensions of 3T3 cells towards distant infrared light sources , 1991, The Journal of cell biology.

[12]  H. A. Pohl Natural electrical RF oscillation from cells , 1981, Journal of bioenergetics and biomembranes.

[13]  Ana M Soto,et al.  The microenvironment determines the breast cancer cells' phenotype: organization of MCF7 cells in 3D cultures , 2010, BMC Cancer.

[14]  M. Jibu,et al.  Evanescent (tunneling) photon and cellular "vision'. , 1997, Bio Systems.

[15]  H. Fröhlich,et al.  Evidence for coherent excitation in biological systems , 1983 .

[16]  H. Kitano,et al.  Computational systems biology , 2002, Nature.

[17]  Daniel Fels,et al.  Cellular Communication through Light , 2009, PloS one.

[18]  A. Pross On the Emergence of Biological Complexity: Life as a Kinetic State of Matter , 2005, Origins of Life and Evolution of Biospheres.

[19]  I. Jerman,et al.  Electric Field Absorption and Emission as an Indicator of Active Electromagnetic Nature of Organisms—Preliminary Report , 2009, Electromagnetic Biology and Medicine.

[20]  H. Haken Cooperative phenomena in systems far from thermal equilibrium and in nonphysical systems , 1975 .

[21]  W J Freeman,et al.  Biocomplexity: adaptive behavior in complex stochastic dynamical systems. , 2001, Bio Systems.

[22]  C. Rossi,et al.  Examining the dynamics of phytoplankton biomass in Lake Tanganyika using Empirical Orthogonal Functions , 2007 .

[23]  A. Keshavarzian,et al.  Evidence for non-chemical, non-electrical intercellular signaling in intestinal epithelial cells. , 2007, Bioelectrochemistry.

[24]  H. Fröhlich,et al.  The extraordinary dielectric properties of biological materials and the action of enzymes. , 1975, Proceedings of the National Academy of Sciences of the United States of America.

[25]  K. Blinowska,et al.  Cell membrane as a possible site of Fröhlich's coherent oscillations , 1985 .

[26]  Ravi Iyengar,et al.  Systems Biology—An Overview , 2011 .

[27]  Ana M Soto,et al.  The somatic mutation theory of cancer: growing problems with the paradigm? , 2004, BioEssays : news and reviews in molecular, cellular and developmental biology.

[28]  N. Marchettini,et al.  Chemical waves and pattern formation in the 1,2-dipalmitoyl-sn-glycero-3-phosphocholine/water lamellar system. , 2004, Journal of the American Chemical Society.

[29]  M. Cifra,et al.  Measurement of Electrical Oscillations and Mechanical Vibrations of Yeast Cells Membrane Around 1 kHz , 2009, Electromagnetic biology and medicine.

[30]  C. Bonechi,et al.  Metabolic response to exogenous ethanol in yeast: an in vivo NMR and mathematical modelling approach. , 2006, Biophysical chemistry.

[31]  A U Igamberdiev,et al.  Time, reflectivity and information processing in living systems: a sketch for the unified information paradigm in biology. , 1998, Bio Systems.

[32]  A U Igamberdiev,et al.  Foundations of metabolic organization: coherence as a basis of computational properties in metabolic networks. , 1999, Bio Systems.

[33]  M. Horton,et al.  Mapping correlated membrane pulsations and fluctuations in human cells , 2007, Journal of molecular recognition : JMR.

[34]  H. Fröhlich Long Range Coherence and the Action of Enzymes , 1970, Nature.

[35]  F. Popp,et al.  On the Dynamics of Self-Organization in Living Organisms , 2009, Electromagnetic biology and medicine.

[36]  H. Kitano Systems Biology: A Brief Overview , 2002, Science.

[37]  L. Brizhik,et al.  Nonlinear Model of the Origin of Endogenous Alternating Electromagnetic Fields and Selfregulation of Metabolic Processes in Biosystems , 2003 .

[38]  Hubert P. Yockey,et al.  Origin of Life on Earth and Shannon's Theory of Communication , 2000, Comput. Chem..

[39]  C. McCaig,et al.  Electrical dimensions in cell science , 2009, Journal of Cell Science.

[40]  C. Stuart Bio-informational equivalence. , 1985, Journal of theoretical biology.

[41]  P.K. Dhar,et al.  Computational approach to systems biology: from fraction to integration and beyond , 2004, IEEE Transactions on NanoBioscience.

[42]  Sublethal effect of a weak intermittent magnetic field on the development of Xenopus laevis (Daudin) tadpoles , 2003, International journal of biometeorology.

[43]  A U Igamberdiev,et al.  Quantum mechanical properties of biosystems: a framework for complexity, structural stability, and transformations. , 1993, Bio Systems.

[44]  J. Fields,et al.  Electromagnetic cellular interactions. , 2011, Progress in biophysics and molecular biology.

[45]  L. Montagnier,et al.  Electromagnetic signals are produced by aqueous nanostructures derived from bacterial DNA sequences , 2009, Interdisciplinary Sciences Computational Life Sciences.

[46]  L. Bertalanffy The theory of open systems in physics and biology. , 1950 .

[47]  C. Rossi,et al.  The Spatial Distribution of Optical Properties in the Ultraviolet and Visible in an Aquatic Ecosystem¶ , 2004, Photochemistry and photobiology.

[48]  W. Nagl,et al.  Biophoton emission , 1984, Cell Biophysics.

[49]  G. Albrecht‐Buehler Rudimentary form of cellular "vision". , 1992, Proceedings of the National Academy of Sciences of the United States of America.

[50]  C. Stuart,et al.  Physical models of biological information and adaptation. , 1985, Journal of theoretical biology.