8
Bioelectromagnetism
transmission of these potential changes helps the body to coordinate the activity of all of the systems in
our body. Te body can feed the information impinging on it from both the external and internal envi
ronments to the central nervous system, where it is processed, enabling the body to adapt in a suitable
manner to both of its environments (Kato, 2006). From the study of bioelectricity, many medical and
clinical applications such as electroencephalography (EEG), electrocardiography (ECG), electromyog
raphy and others have been developed. Moreover, electrobiology involves the study of how various elec
trical phenomena such as electric feld, voltages and currents afect biological systems (Popp et al., 1989).
In nature, it is known that some fsh can detect the weak electrical changes generated by bait. Tese
fsh are known to have sensory organs that detect these weak electrical changes, and this characteristic
is referred to as electroreception. It is now understood that this behavior is controlled by the response
of mechanosensory organs to electric stimuli, based on electroreception experiments with insects and
terrestrial animals.
Biomagnetism is the study of magnetic felds originating from biological systems. It also deals with
magnetic phenomena of biological systems, which can be observed at diferent intensities and frequen
cies. For example, the so-called magnetophosphene is a visual sensation caused by exposing the head to
a low-frequency (around 10–70 Hz) magnetic feld of around 10–20 mT. Tis sensation is generated in the
retina. Te earliest magnetic stimulation was reported by Jacques-Arsene d’Arsonval. Magnetic stimu
lation is based on Faraday’s law of induction. Tis law states how the change of an applied magnetic
feld induces an electric feld with accompanying current in the tissue. Te frst magnetic stimulation
of nerve was described by Alexander Kolin in 1959. Magnetic stimulation of the human brain and heart
has been used for the purpose of both research and clinical treatment. Te biological magnetic felds are
extremely weak compared to the geomagnetic felds. Te biological magnetic feld of the human heart,
called magnetocardiogram (MCG), was frst detected by Gerhard Baule and Richard McFee in 1963.
Te biological magnetic feld of the human brain called magnetoencephalogram (MEG) was detected
by David Cohen in 1968. Afer these pioneering studies, using superconductive quantum interference
devices techniques, the weak biological magnetic felds from the brain, heart and lung were easily mea
sured from outside the body. Biomedical stimulation with ELF electric or magnetic felds was used
frst for clinical applications such as the healing of bone fracture. Fundamental research activities have
been carried out for the healing promotion of various tissues. However, there is still no widely accepted
mechanism by which ELF electric or magnetic felds can afect biological tissues. Te well-known inter
action between ELF electric or magnetic felds and biological tissues is the eddy currents induced in the
tissues, which is a possible candidate mechanism. Te other candidate is the interaction of the applied
magnetic felds with an endogenous magnet such as magnetite. Because the brain is so important for
human behavior, and because the functions of the brain inherently involve a great amount of electrical
activity, since the beginning of bioelectromagnetism, it has been essential to examine the efects of mag
netic felds, electric felds and currents, since they can induce electric felds and currents on the brain.
Magnetobiology involves the study of interaction between magnetic feld and biological systems
(Popp et al., 1989). Magnetobiology also studies the identifcation and sensitivities of biological organ
isms to weak magnetic felds. Magnetoreception, a category of magnetobiology, is known as the sensing
of magnetic felds by biological organisms. It includes the magnetic navigation of migrating birds and
other organisms, the magnetotactic behavior of some bacteria and the magnetoreception in humans.
Te study of magnetobiology and magnetoreception has made great advances in the last 10–20 years. In
magnetobiology, the ability of birds, bees, turtles, reptiles, amphibians, plants and others to detect the
geomagnetic feld has been reported (Mafei, 2014, 2019; Wiltschko and Wiltschko, 1995). Certain crus
taceans, lobsters and bony fsh have also been found to use magnetism-related navigations (magnetic
compass). In this sense, magnetic sensibility is common in the animal kingdom. Tus, there is no longer
any doubt that animals can sense the geomagnetic feld; however, how they sense it is still unknown.
Te geomagnetic feld is weak and is unlikely to have a direct efect on the chemical reactions in the
body. Currently, the main theory of the mechanism of action of the geomagnetic feld is that magnetite
and chemical compasses based on quantum biology are responsible for the magnetoreception. For this