210

Bioelectromagnetism

5.6 Conclusions

Variations in the MF intensity infuence many plant biological processes. Te mechanism of plant mag-

netoreception/perception is still unknown; however, the RPM of chemical magnetosensing appears to

adequately explain the MFEs observed in plants. Te favin-based RP system is one of the most studied

MFE and an RP-based sensor may also be enhanced by interactions with its fuctuating environment,

a property apparently found in many areas of “quantum biology.” Te only currently hypothesized

RP that may potentially explain plant MFE is FADH^• / O^•

2

− , generated in the reoxidation of the fully

(photo)reduced FADH⁻. Unlike the electric feld, the MF is not attenuated by living tissue and penetrates

through the whole plant body. Relative changes in the Vm are obtained only at very high MF intensities.

Terefore, the variations in channel activities found afer exposure to GMF or NNMF intensities cannot

be ascribed to the direct efect of the MF, being the consequence of the cascade of events afer MF per­

ception. Exposure to MFs above 15 T induces the perturbation of metabolic processes in the presence of

strong MFs and may be useful for guiding future research designed to calibrate safe exposure standards

for living organisms. Plants show both light-dependent and light-independent magneto perception, and

recent data suggest that diferent organs may perceive MFE in a diferential way, with a typical hormetic

behavior. Further studies are required to dissect the plant signaling cascade of events triggered by MF

variations, which remain still far from being deciphered.

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