Bioelectromagnetics: Difference between revisions

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'''Bioelectromagnetics''' is the study of how [[electromagnetic fields]] interact with and influence biological processes; almost the same as [[radiobiology|radiobiology]] of [[non-ionizing radiation|non-ionizing radiation]]. Common areas of investigation include the mechanism of animal migration and navigation using the geomagnetic field, studying the potential effects of man-made sources of electromagnetic fields, such as those produced by the [[electricity distribution|power distribution system]] and [[mobile phones]], and developing novel therapies to treat various conditions.  
'''Bioelectromagnetics''' is the study of how [[electromagnetic fields]] interact with and influence biological processes; almost the same as [[radiobiology|radiobiology]] of [[non-ionizing radiation|non-ionizing radiation]]. Common areas of investigation include the mechanism of animal migration and navigation using the geomagnetic field, studying the potential effects of man-made sources of electromagnetic fields, such as those produced by the [[electricity distribution|power distribution system]] and [[mobile phones]], and developing novel therapies to treat various conditions.  


While several treatments based on the use of magnetic fields have been reported in peer-reviewed journals, the only ones that have been approved by the FDA are the use of pulsed magnetic fields to aid non-union bone fractures. [[Transcranial magnetic stimulation]] is currently under active study in multiple research centres, and will likely become an approved therapy in the future.
While several treatments based on the use of magnetic fields have been reported in peer-reviewed journals, the only ones that have been approved by the FDA are the use of pulsed magnetic fields to aid non-union bone fractures. [[Transcranial magnetic stimulation]] is currently under active study in multiple research centers, and will likely become an approved therapy in the future. Laser therapy treatments, which depend on the energy derived from photons, are sometimes referred to as photo-electromagnetic in character. Numerous references exist in literature regarding the bioelecrtromagnetic effects of photon therapy.  


Bioelectromagnetics is not to be confused with [[bioelectromagnetism]], which deals with the ability of life to produce its own electromagnetism.
Bioelectromagnetics is not to be confused with [[bioelectromagnetism]], which deals with the ability of life to produce its own electromagnetism.

Latest revision as of 17:30, 4 October 2014

Editor-in-Chief: Robert G. Schwartz, M.D. [1], Piedmont Physical Medicine and Rehabilitation, P.A.;

Associate Editor-In-Chief: [2]Austin Schwartz, Department of Biophysics, Florida State University, Tallahassee, Florida

Bioelectromagnetics is the study of how electromagnetic fields interact with and influence biological processes; almost the same as radiobiology of non-ionizing radiation. Common areas of investigation include the mechanism of animal migration and navigation using the geomagnetic field, studying the potential effects of man-made sources of electromagnetic fields, such as those produced by the power distribution system and mobile phones, and developing novel therapies to treat various conditions.

While several treatments based on the use of magnetic fields have been reported in peer-reviewed journals, the only ones that have been approved by the FDA are the use of pulsed magnetic fields to aid non-union bone fractures. Transcranial magnetic stimulation is currently under active study in multiple research centers, and will likely become an approved therapy in the future. Laser therapy treatments, which depend on the energy derived from photons, are sometimes referred to as photo-electromagnetic in character. Numerous references exist in literature regarding the bioelecrtromagnetic effects of photon therapy.

Bioelectromagnetics is not to be confused with bioelectromagnetism, which deals with the ability of life to produce its own electromagnetism.

Introduction: general features of observed interactions

Thermal vs nonthermal nature

Most of the molecules that make up the human body interact only weakly with electromagnetic fields (EMF) that are in the radiofrequency or extremely low frequency bands. One basic interaction is the absorption of energy from the EMF, which can cause tissue to heat up; more intense field exposures will produce greater heating. This heat deposition can lead to biological effects ranging from discomfort to protein denaturation to burns. Many nations and regulatory bodies (for example, the International Commission on Non-Ionizing Radiation Protection) have established safety guidelines to limit the EMF exposure to a non-thermal level, which can either be defined as heating only to the point where the excess heat can be dissipated/radiated away, or as some small temperature increase that is not detectable with current instruments (such as a heating of less than 0.1°C).

However, many studies have shown that biological effects may be present for these non-thermal exposures. Various mechanisms have been proposed to explain biological effects from non-thermal exposures (Binhi, 2002), and there may be several mechanisms at work underlying the differing phenomena observed. Biological effects of weak electromagnetic fields are the subject of study in magnetobiology.

Behavioral effects

Many subtle, and at times, not-so-subtle effects on behaviour have been reported from exposure to magnetic fields, with a particular focus in research on pulsed magnetic fields. The specific pulseform used appears to be an important factor for the behavioural effect seen. For instance, a pulsed magnetic field originally designed for magnetic resonance spectroscopic imaging was found to alleviate symptoms in bipolar patients (Rohan et al, 2004), while another MRI pulse had no effect. A whole-body exposure to a pulsed magnetic field was found to alter standing balance (Thomas et al, 2001) and pain perception (Shupak et al, 2004) in other studies.

TMS (and related)

A strong changing magnetic field can induce electrical currents in conductive tissue, such as the brain. Since the magnetic field will penetrate tissue, it can be generated outside of the head to induce currents within, hence Transcranial magnetic stimulation. These currents will depolarize neurons in a selected part of the brain, leading to changes in the patterns of neural activation. Essentially, the effect of TMS is to change the information content in the neurons. There is no structural or heating effect that may damage the tissue; only natural signals (action potentials) are generated in the target area. If there are any risks, these are due to the arrival of action potentials to synapses and the natural activation of the postsynaptic cell.

A number of scientists and clinicians are attempting to use TMS to replace electroconvulsive therapy (ECT) to treat disorders such as severe depression. Instead of one strong electric shock through the head as in ECT, a large number of relatively weak pulses are delivered in TMS treatment, typically at the rate of about 10 pulses per second.

If very strong pulses at a rapid rate are delivered to the brain, the induced currents can cause convulsions. Sometimes this is done deliberately in order to treat depression such as in ECT.

Molecular Effects

Low frequency weak magnetic fields have been shown to cause millivolt changes in membrane potential, however the mechanism for this effect is yet to be understood (Mathie et al, 2003).

See also

References

Organizations

Books

  • Robert O. Becker and Andrew A. Marino, Electromagnetism and Life, State University of New York Press, Albany, 1982 (ISBN 0-87395-561-7)
  • Robert O. Becker, The Body Electric: Electromagnetism and the Foundation of Life, William Morrow & Co, 1985 (ISBN 0-688-00123-8)
  • Robert O. Becker, Cross Currents: The Promise of Electromedicine, the Perils of Electropollution, Tarcher, 1989 (ISBN 0-87477-536-1)
  • Jaakko Malmivuo and Robert Plonsey, Bioelectromagnetism: Principles and Applications of Bioelectric and Biomagnetic Fields, Oxford University Press, 1995 (ISBN 0-19-505823-2)
  • David O. Carpenter and Sinerik Ayrapetyan, Biological Effects of Electric and Magnetic Fields, Volume 1 : Sources and Mechanisms, Academic Press, 1994 (ISBN 0-12-160261-3)
  • David O. Carpenter and Sinerik Ayrapetyan, Biological Effects of Electric and Magnetic Fields : Beneficial and Harmful Effects (Vol 2), Academic Press, 1994 (ISBN 0-12-160261-3)
  • A. Chiabrera (Editor), Interactions Between Electromagnetic Fields and Cells, Springer, 1985 (ISBN 0-306-42083-X)
  • Mary E. O'Connor (Editor), et al, Emerging Electromagnetic Medicine, Springer, 1990 (ISBN 0-387-97224-2)
  • William F. Horton and Saul Goldberg, Power Frequency Magnetic Fields and Public Health, CRC Press, 1995 (ISBN 0-8493-9420-1)
  • Riadh W. Y. Habash, Electromagnetic Fields and Radiation: Human Bioeffects and Safety, Marcel Dekker, 2001 (ISBN 0-8247-0677-3)
  • Ho Mae-Wan, et al, Bioelectrodynamics and Biocommunication, World Scientific, 1994 (ISBN 981-02-1665-3)
  • Paul Brodeur, Currents of Death, Simon & Schuster, 2000 (ISBN 0-7432-1308-4)
  • Binhi V.N. Magnetobiology: Underlying Physical Problems. San Diego: Academic Press, 2002. ISBN 0-12-100071-0. http://www.elsevier.com/wps/find/bookdescription.cws_home/699798/description

Journals

Journal Articles

  • Rohan et al., 2004. Am J Psychiatry. 161(1):93-8.
  • Shupak et al., 2004. Neurosci Lett. 363(2):157-62.
  • Thomas et al., 2001. Neurosci Lett. 309(1):17-20.
  • Mathie et al. 2003. Radiat Prot Dosimetry. 106(4): 311-315.