Biophoton Signaling In The Brain
The brain is the most important organ of the human body, ensuring its higher nervous activity and coordinating all metabolic and functional processes. Therefore, the development of aspects of biophoton signaling in the brain is an important part of the concept. This is a new and important scientific aspect that requires further study.
The brain’s functioning is carried out due to the generation of coherent electromagnetic energy by biopolymers of its cell membranes and the subsequent unique interaction of these resulting electromagnetic currents/biophoton signals with each other. This is based on unique mechanisms of transmission/redistribution of biophoton signals in the tissues of all brain areas. Ultimately, this electromagnetic cellular activity creates a unique local electromagnetic field of the human brain, ensures the functioning of the human body, and its life as a rational being.
According to the universal laws of physics, electromagnetic fields must interact. Therefore, it is logical to believe that electromagnetic energy from the brain should somehow replenish the human body’s electromagnetic field, formed by the activity of its other tissues and organs. The brain’s electromagnetic field is an important integral component of biophoton signaling and a source of information for the general electromagnetic field of the human body. The study of quantum mechanisms of interaction of electromagnetic fields and biophoton signaling in various areas of the brain is an important and promising direction for future neuroscience development. This is a new scientific direction that is just emerging. How can existing scientific knowledge about the structure and functioning of the brain be integrated into the concept of biophoton signaling?
The principle of the structure of brain cells is analogous to all other cells of the human body. Therefore, at the micro level, the processes of biophoton signaling in brain cells should occur similarly to those described for other body cells. However, the unique internal structure of the brain will provide a completely different and still not fully explained from a scientific point of view nature of the propagation of the biophoton signal inside the brain and the quantum interaction of these signals with each other.
Scheme of factors that determine the characteristics of the propagation of a biophotonic signal inside the brain. Illustrations are based on Garman (2010), Chikly et al. (2016), Stępkowski et al. (2017), and Rangaraju et al. (2019).
A is an anatomical division of the brain into zones;
B is an example of heterogeneity of neuronal populations in the brain on sections stained with hematoxylin and eosin; final magnifications: (a,c,d) = 277x; (b) = 554x; (e,f) = 138x;
C is a symbolic representation of the brain as a single neural network;
D is a schematic representation of intracranial resonances of electromagnetic frequencies of the brain;
E is a photograph of mitochondria (multiple yellow inclusions) in neurons (Stępkowski et al., 2017);
F is a diagram of the arrangement of mitochondria in a neuron (Rangaraju et al., 2019);
G is an illustration and iof the primo vessel floating inside the ventricular system of the brain by Chikly et al. (2016);
H is an image of the primo vessel floating inside the brain’s ventricular system by Chikly et al. (2016).
Nirosha Murugan, PhD, is a biophysicist with a particular interest in quantum biology and electrobiology. She is an assistant professor at Wilfrid Laurier University in Waterloo, Ontario, where her lab investigates the biophysical language of cellular communication. Her work has investigated topics including the electrical properties of cells, biophotons, heliobiology, magnetobiology and how all of these aspects of the environment shape the energetic landscape of biological systems. These fields present important areas of investigation not only in understanding disease, but also understanding life itself.
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