16
Bioelectromagnetism
for the biological and health efects and medical applications of electromagnetism, is shown. Chapter 2
presents how bioelectromagnetism has been gradually developing and expanding into a variety of felds
such as engineering, biomedical engineering, medicine and biology. Tis chapter also explains the fan
tastic and dramatic history of bioelectromagnetism from ancient times until the twenty-frst century.
It chronologically details the history of the major subjects, the moments when scientists made relevant
physical, chemical, electrical and biological discoveries, and a historical debate about possible human
health efects due to exposure to electromagnetic felds. Tis chapter also includes, as far as possible, the
historical development of Japanese research in bioelectromagnetism. Te main emphasis of this chapter
is to present how through the long historical development of bioelectromagnetism, today’s scientifc
achievements in biomedical engineering, biology, medicine, etc. were shaped by elucidating the electro
magnetic phenomena found in biological systems.
Chapters 3 and 6 will establish the introduction regarding the connection between atmospheric elec
tricity, geomagnetic feld and biological systems, and the relationship between the evolutions of life with
the geomagnetic felds. As was already indicated, the electromagnetic phenomena of the atmospheres
have afected the evolution of life. Furthermore, the evolution of life has also been afected by the fuctu
ations and variations of the geomagnetic feld intensity as well as by changes in atmospheric oxygen lev
els and UV radiation. It has been estimated that following a geomagnetic feld reversal, the geomagnetic
feld becomes weaker, and its reduction in the last 200 years has been substantial. Also, the earth’s mag
netic poles are moving, and it is estimated that the north pole has moved 1,100 km over the last 170 years.
Furthermore, predictions based on simulations estimate that geomagnetic feld reversals can enhance
the oxygen escape rate by 3–4 orders if the magnetic feld becomes sufciently weak. Consequently, it is
anticipated that the global hypoxia will gradually kill numerous species. Chapter 6 comprises fascinat
ing topics regarding the “Cambrian explosion of life,” the “extinction of Neanderthals,” the “magnetic
feld defciency syndrome,” and the “magnetic storm and its related diseases,” all of which are possible
results of geomagnetic fuctuations.
Chapters 4 and 5 will present the recent advances in magnetobiology. Magnetobiology, a part of bio-
electromagnetism, studies living systems’ sensitivity to weak magnetic felds, such as magnetic naviga
tion, magnetotactic bacteria, and the magnetic response of plants, birds, animals and humans. Both
chapters focus on the magnetic navigation of birds and the magnetoreception in plants. Chapter 4 intro
duces the role of magnetic sensing in the migration of birds. Recently, the possibility that cryptochromes
serve as highly sensitive magnetoreceptors has been strongly suggested, and several research felds such
as quantum biology are actively paying attention to this functional characteristic. Te research of this
characteristic is also important because the blue-light photoreceptor protein, cryptochrome, which
includes FAD, is widely found in nature, i.e., bacteria, plants and animals. Magnetic sensing is presumed
to be the consequence of the reaction between FAD with the amino acid residue as the intermediate by
photoirradiation, i.e., the radical pair mechanism for quantum-assisted magnetic sensing, which is able
to detect weak magnetic felds such as the geomagnetic feld (approximately 50 μT). By means of these
magnetoreceptors found in their retina, the migratory birds are assumed to visually perceive in which
direction to move. Tis chapter reviews historical background in theoretical physics and ethology, and
outstanding results in several research felds to date. Chapter 5 introduces the magnetic sensing capabil
ity of plants. Efects of the geomagnetic feld have been observed in plants. However, the impact of the
geomagnetic feld on plant is still not well-understood and the magnetoreception mechanism in plants
is still not scientifcally conclusive. Te two main models for magnetoreception are the magnetite model
and the radical pair model. Te radical pair model is linked to cryptochrome, in a way similar to the
magnetoreceptors found in migratory birds. It was previously mentioned that cryptochromes are a class
of favor-proteins sensitive to light that are found in a variety of plants and animals. Phytochrome and
phototropin are also photoreceptor proteins found in plants. Magnetic feld efects in plants are also
related to light-dependent plant processes. In this chapter, the efects of the geomagnetic feld on plants
are reviewed and the possible mechanisms of magnetoreception in plants including the involvement of
photoreceptors are discussed.