Bioelectrodynamics Explained

Bioelectrodynamics is a branch of medical physics and bioelectromagnetism which deals with rapidly changing electric and magnetic fields in biological systems, i.e. high frequency endogenous electromagnetic phenomena in living cells. Unlike the events studied by the electrophysiology, the generating mechanism of bioelectrodynamic phenomenon is not connected with currents of ions and its frequency is typically much higher. Examples include vibrations of electrically polar intracellular structures and non-thermal emission of photons as a result of metabolic activity.

Theories and Hypotheses

Plenty of theoretical work was published on theories and hypotheses describing generation of electromagnetic field by living cells in very broad frequency range.[1] [2] [3] The most influential one was once probably the Fröhlich's hypothesis of coherence in biological systems introduced by Herbert Fröhlich in the late 1960s.[4] Despite the fact that experimental evidence for Fröhlich's hypothesis does not exist yet, numerical estimates indicate biological feasibility of at least Fröhlich's weak condensation.[5]

Recent theoretical considerations predict generation of radio frequency electromagnetic field in cells as a result of vibrations of electrically polar intracellular structures, e. g., microtubules.[6] Emission in optical part of electromagnetic spectrum is usually attributed to reactive oxygen species (ROS).

Experimental evidence

Bioelectrodynamic effects were experimentally proven in optical range of electromagnetic spectrum.[7] Spontaneous emission of photons by living cells, with intensity significantly higher than corresponds to emission by thermal radiation, was repeatedly reported by several authors over decades.[8] These observations exhibit experimental simplicity and good reproducibility. Although non-thermal emission of photons from living cells is generally accepted phenomenon, much less is known about its origin and properties. On the one hand, it is sometimes attributed to chemiluminescent metabolic reactions (including for instance reactive oxygen species (ROS) [9]), on the other hand, some authors relate this phenomenon to far-from-equilibrium thermodynamics.

Indirect evidence exists on acoustic and radio frequencies; however, direct measurement of field quantities is missing. Pohl and others observed force effect on dielectric particles which were attracted to cells and repulsed from cells, respectively, depending on particles' dielectric constant.[10] Pohl attributed this behavior to dielectrophoresis caused by electromagnetic field of cells. He estimated the frequency of this field as about hundreds of MHz. Other indirect evidence comes from the fact that mechanical vibrations were experimentally proven in very broad frequency range in cells.[11] Since many structures in cells are electrically polar, they will generate electromagnetic field if they vibrate.[12]

Controversy

As a question opened for decades, bioelectrodynamics was not always part of scientific mainstream and thus it was sometimes treated with poor scientific standards. This is particularly true for:

  1. - overestimation of the significance of experimental data obtained (Kucera[13] argues that claims by several authors about direct measurement of cellular electromagnetic activity in radio-frequency band should be accepted with skepticism since technical properties of experimental setups have not even met criteria arising from optimistic theoretical biophysical predictions. Firstly, spatial resolution of used sensors was too low with respect to expected spatial complexity of electromagnetic field in cells. Secondly, the sensitivity of experimental setups was not high enough compared to power available in living cell.),
  2. - misinterpretation of experimental data (Fritz-Albert Popp's claim about coherence of photo-emission from cells[14] is based on statistical distribution of photon counts; however, this is not proof of coherence. Coherent emission (see coherent states) has Poisson distribution, but Poisson distribution is not exclusively related only to coherent processes.) and
  3. - development of uncorroborated hypotheses .

See also

External links

Groups

Notes and References

  1. Priel . Avner . Tuszynski . Jack A. . Cantiello . Horacio F. . Electrodynamic Signaling by the Dendritic Cytoskeleton: Toward an Intracellular Information Processing Model . Electromagnetic Biology and Medicine . Informa UK Limited . 24 . 3 . 2005 . 1536-8378 . 10.1080/15368370500379590 . 221–231. 83894290 .
  2. Cifra . M. . Electrodynamic eigenmodes in cellular morphology . Biosystems . Elsevier BV . 109 . 3 . 2012 . 0303-2647 . 10.1016/j.biosystems.2012.06.003 . 356–366. 22750075 .
  3. Zhou . Shu-Ang . Uesaka . Mitsuru . Bioelectrodynamics in living organisms . International Journal of Engineering Science . Elsevier BV . 44 . 1–2 . 2006 . 0020-7225 . 10.1016/j.ijengsci.2005.11.001 . 67–92.
  4. GJ Hyland and Peter Rowlands (editors) Herbert Frohlich FRS: A Physicist Ahead of his Time. (University of Liverpool, 2006, 2nd edition 2008.)
  5. Reimers . J. R. . McKemmish . L. K. . McKenzie . R. H. . Mark . A. E. . Hush . N. S. . Weak, strong, and coherent regimes of Frohlich condensation and their applications to terahertz medicine and quantum consciousness . Proceedings of the National Academy of Sciences . 106 . 11 . 26 February 2009 . 0027-8424 . 10.1073/pnas.0806273106 . 4219–4224. free . 19251667 . 2657444. 2009PNAS..106.4219R .
  6. Pokorný . Jiří . Hašek . Jiří . Jelínek . František . Electromagnetic Field of Microtubules: Effects on Transfer of Mass Particles and Electrons . Journal of Biological Physics . Springer Science and Business Media LLC . 31 . 3–4 . 2005 . 0092-0606 . 10.1007/s10867-005-1286-1 . 501–514. 3456341 . 23345914 .
  7. Kučera O, Červinková K, Nerudová M, Cifra M . Spectral Perspective on the Electromagnetic Activity of Cells . Current Topics in Medicinal Chemistry . 15 . 513–522 . 2015 . 6 . 25714382 . 10.2174/1568026615666150225103105 .
  8. Cifra . Michal . Fields . Jeremy Z. . Farhadi . Ashkan . Electromagnetic cellular interactions . Progress in Biophysics and Molecular Biology . Elsevier BV . 105 . 3 . 2011 . 0079-6107 . 10.1016/j.pbiomolbio.2010.07.003 . 223–246 . 20674588.
  9. Prasad . Ankush . Pospišil . Pavel . Two-dimensional imaging of spontaneous ultra-weak photon emission from the human skin: role of reactive oxygen species . Journal of Biophotonics . Wiley . 4 . 11–12 . 20 October 2011 . 1864-063X . 10.1002/jbio.201100073 . 840–849. 22012922 .
  10. Pohl . Herbert A. . Crane . Joe S. . Dielectrophoresis of Cells . Biophysical Journal . Elsevier BV . 11 . 9 . 1971 . 0006-3495 . 10.1016/s0006-3495(71)86249-5 . 711–727. 5132497 . 1484049 . 1971BpJ....11..711P . free.
  11. Kruse . Karsten . Jülicher . Frank . Oscillations in cell biology . Current Opinion in Cell Biology . Elsevier BV . 17 . 1 . 2005 . 0955-0674 . 10.1016/j.ceb.2004.12.007 . 20–26.
  12. Kučera . Ondřej . Havelka . Daniel . Mechano-electrical vibrations of microtubules—Link to subcellular morphology . Biosystems . Elsevier BV . 109 . 3 . 2012 . 0303-2647 . 10.1016/j.biosystems.2012.04.009 . 346–355. 22575306 .
  13. Kučera . Ondřej . Cifra . Michal . Pokorný . Jiří . Technical aspects of measurement of cellular electromagnetic activity . European Biophysics Journal . Springer Science and Business Media LLC . 39 . 10 . 20 March 2010 . 0175-7571 . 10.1007/s00249-010-0597-8 . 1465–1470. 20306029 . 36245681 .
  14. Popp FA (1999) About the Coherence of Biophotons 1999 Proceedings of an International Conference on Macroscopic Quantum Coherence, Boston University.