Bioelectromagnetism (sometimes equated with bioelectricity) refers to the static voltage of biological cells and to the electric currents that flow in living tissues, such as nerves and muscles, as a result of action potentials. Biological cells use bioelectricity to store metabolic energy, to do work or trigger internal changes, and to signal one another. Bioelectromagnetism is the electric current produced by action potentials along with the magnetic fields they generate through the phenomenon of electromagnetic induction.

Bioelectromagnetism is studied primarily through the techniques of electrophysiology. In the late eighteenth century, the Italian physician and physicist, Luigi Galvani, first recorded the phenomenon while dissecting a frog at a table where he had been conducting experiments with static electricity. Galvani coined the term animal electricity to describe the phenomenon, while contemporaries labeled it galvanism. Galvani and contemporaries regarded muscle activation as resulting from an electrical fluid or substance in the nerves.

Bioelectromagnetism is an aspect of all living things, including all plants and animals. Bioenergetics is the study of energy relationships of living organisms. Biodynamics deals with the energy utilization and the activities of organisms. Some animals have acute bioelectric sensors and are highly sensitive to magnetic fields, such as migratory birds, which are believed to navigate in part by orienting with respect to the Earth's magnetic field. Also, sharks are more sensitive to local interaction in electromagnetic fields than most humans. Other animals, such as the electric eel, are able to generate large electric fields outside their bodies.

In the life sciences, biomedical engineering uses concepts of circuit theory, molecular biology, pharmacology, and bioelectricity. Bioelectromagnetism is associated with biorhythms and chronobiology. Biofeedback is used in physiology and psychology as to monitor rhythmic cycles of physical, mental, and emotional characteristics and as a technique for teaching the control of bioelectric functions.

Bioelectromagnetism involves the interaction of ions. Bioelectromagnetism is sometimes difficult to understand because of the differing types of bioelectricity, such as brainwaves, myoelectricity (e.g., heart-muscle phenomena), and other related subdivisions of the same general bioelectromagnetic phenomena. One such phenomenon is a brainwave, which neurophysiology studies, and is where bioelectromagnetic fluctuations of voltage between parts of the cerebral cortex that are detectable with an electroencephalograph. This is primarily studied in the brain by way of the electroencephalogram or "EEG."

See also

• activity series of metals
• alpha rhythm
• alpha wave
• beta rhythm
• beta wave
• biorhythm
• delta rhythm
• delta wave
• electrochemical potential
• electrochemistry
• life cycle
• Mana
• spontaneous generation
• theta rhythm
• theta wave
• Electroencephalography

Quotes

"We now realize that the phenomena of chemical interactions, and, ultimately life itself, are to be understood in terms of electromagnetism". Richard P. Feynman

External Links, resources, and references

Information

• Malmivuo, Jaakko, and Robert Plonsey, "Bioelectromagnetism, Principles and Applications of Bioelectric and Biomagnetic Fields". Oxford University Press, New York - Oxford. 1995.
• Direct and Inverse Bioelectric Field Problems
• Bioelectricity. Biophysics lectures.
• The Pseudoscience of Coghill Research Laboratories

Groups

• International Journal of Bioelectromagnetism
• International Society for Bioelectromagnetism
• Bioelectromagnetism Research Group
• Living State Physics Group
• Physikalisch-Technische Bundesanstalt. Laboratory for Bioelectricity/Biomagnetism, Berlin.