Innate Immune Regulation Under Magnetic Fields With Possible Mechanisms and Therapeutic Applications

Lei, Hong; Pan, Yi; Wu, Rongqian; Lv, Yi

doi:10.3389/fimmu.2020.582772

“…Interactions between a magnetic field and living cells may result in the appearance of a variety of biomagnetic effects at the cellular and organism levels [ 5 , 6 , 7 , 8 , 9 , 10 , 11 , 12 ]. Many intriguing mechanisms have been suggested to explain biomagnetic effects [ 13 , 14 , 15 , 16 , 17 , 18 ]. The biological effects of high and ultrahigh magnetic fields are of particular interest; for example, a 9.4 T static MF suppress lung cancer growth [ 12 ]; a 10.5 T MRI static MF affects human cognitive, vestibular, and physiological functions [ 19 ]; a 16.4 T static MF results in long-term impairment of the vestibular system in mice [ 20 ]; a 27 T static MF changes the orientation and morphology of mitotic spindles in human cells [ 21 ].…”

Section: Introductionmentioning

confidence: 99%

Effects of High Magnetic Fields on the Diffusion of Biologically Active Molecules

Zablotskii

¹

,

Polyakova

²

,

Dejneka

³

2021

Cells

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The diffusion of biologically active molecules is a ubiquitous process, controlling many mechanisms and the characteristic time scales for pivotal processes in living cells. Here, we show how a high static magnetic field (MF) affects the diffusion of paramagnetic and diamagnetic species including oxygen, hemoglobin, and drugs. We derive and solve the equation describing diffusion of such biologically active molecules in the presence of an MF as well as reveal the underlying mechanism of the MF’s effect on diffusion. We found that a high MF accelerates diffusion of diamagnetic species while slowing the diffusion of paramagnetic molecules in cell cytoplasm. When applied to oxygen and hemoglobin diffusion in red blood cells, our results suggest that an MF may significantly alter the gas exchange in an erythrocyte and cause swelling. Our prediction that the diffusion rate and characteristic time can be controlled by an MF opens new avenues for experimental studies foreseeing numerous biomedical applications.

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“…The scientific research on electromagnetic effects on biological systems involves numerous theoretical and practical aspects in the last couple of centuries. Electric and magnetic fields, depending on their intensity, frequency, and gradients, affect the biological processes, including the immune cells [1]. The magnetic field could support chemotherapy in oncology [2], despite missing observable clinical changes, the improvement of the patients' quality of life is expected.…”

Section: Introductionmentioning

confidence: 99%

Bio-Electromagnetics without Fields: The Effect of the Vector Potential

Szász¹

2021

OJBIPHY

0

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Numerous considerations deal with specialties of bioelectromagnetic effects, including the force-free and field-free interactions. The fact that bioelectromagnetic phenomena consist of effects without mechanical forces and even without measurable fields looks impossible in the simple considerations. However, the stochastic fluctuations cause surprising results, with scientifically proven bioelectromagnetism in field-free conditions. In the first steps, we show the scalar and vector potentials' specialties instead of electric and magnetic fields defined by the well-known Maxwellian equations. The vanishing of the fields is connected to the potentials' stochastic fluctuations, the noises control the "zero-ground". The result shows a possibility of a wave that has no attenuation during its transmission through the material. In this meaning, the result is similar to the consequences of the scalar-wave (SW) considerations. The structural changes follow a particular noise spectrum (called pink-noise or 1/f noise), which keeps the entropy constant in a broad range of scaling magnification.

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“…Interactions between a magnetic field and living cells may result in the appearance of a variety of biomagnetic effects at the cellular and organism levels [8][9][10][11][12][13][14][15]. Many intriguing mechanisms have been suggested to explain biomagnetic effects [16][17][18][19][20][21]. The biological effects of high and ultrahigh magnetic fields are of particular interest, for example: 9.4 T static MF suppress lung cancer growth [15]; 10.5 T MRI static MF effects on human cognitive, vestibular, and physiological function [22]; 16.4 T static MF results in long-term impairment of the vestibular system in mice [23]; 27 T static MF changes orientation and morphology of mitotic spindles in human cells [24].…”

Section: Introductionmentioning

confidence: 99%

“…Interactions between a magnetic field and living cells may result in the appearance of a variety of biomagnetic effects at the cellular and organism levels [8][9][10][11][12][13][14][15]. Many intriguing mechanisms have been suggested to explain biomagnetic effects [16][17][18][19][20][21]. However, the biological effects related to MF-affected diffusion are poorly understood [7].…”

Section: Introductionmentioning

confidence: 99%

Effects of High Magnetic Fields on Diffusion of Biologically Active Molecules

Zablotskii

¹

,

Polyakova

²

,

Dejneka

³

2020

Preprint

0

View full text Add to dashboard Cite

The diffusion of biologically active molecules is a ubiquitous process, controlling many mechanisms and the characteristic time scales for pivotal processes in living cells. Here, we show how a high static magnetic field (MF) affects the diffusion of paramagnetic and diamagnetic species, including oxygen, hemoglobin, ROS and drugs. We derive and solve the equation describing diffusion of such biologically active molecules in the presence of a MF as well as reveal the underlying mechanism of the MF effect on diffusion. We find that a high MF accelerates diffusion of diamagnetic species while slowing the diffusion of paramagnetic molecules in cell cytoplasm. When applied to oxygen and hemoglobin diffusion in red blood cells, our results suggest that a MF may significantly alter the gas exchange in an erythrocyte and cause swelling. Our prediction that the diffusion rate and characteristic time can be controlled by a MF opens new avenues for experimental studies foreseeing numerous biomedical applications.SignificanceWe show that diffusion processes of biologically active molecules (hemoglobin, oxygen, reactive oxygen species, etc.) and paramagnetic drugs can be remotely controlled by high static magnetic fields. Since diffusion processes determine the reference time scale for all other processes in living cells as well as the propagation speed of signaling molecules during cell-to-cell communication, our results – the magnetic field dependences of the diffusion rate and characteristic time – may serve as an important key for revealing and understanding the mechanisms of magnetic field action on living cells, tissue and organisms.

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Innate Immune Regulation Under Magnetic Fields With Possible Mechanisms and Therapeutic Applications

Cited by 22 publications

References 91 publications

Effects of High Magnetic Fields on the Diffusion of Biologically Active Molecules

Effects of High Magnetic Fields on the Diffusion of Biologically Active Molecules

Bio-Electromagnetics without Fields: The Effect of the Vector Potential

Effects of High Magnetic Fields on Diffusion of Biologically Active Molecules

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