20222
Author: Flavin, Dana × Subject: Wave ×
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    A model for analyzing evolutions of neurons by using EEG waves
    2022
     | AIMS Press
    It is known that differences between potentials of soma, dendrites and different parts of neural structures may be the origin of electroencephalogram (EEG) waves. These potentials may be produced by some excitatory synapses and currents of charges between neurons and then thereafter may themselves cause the emergence of new synapses and electrical currents. These currents within and between neurons emit some electromagnetic waves which could be absorbed by electrodes on the scalp, and form topographic images. In this research, a model is proposed which formulates EEG topographic parameters in terms of the charge and mass of exchanged particles within neurons, those which move between neurons, the number of neurons and the length of neurons and synapses. In this model, by knowing the densities of the frequencies in different regions of the brain, one can predict the type, charge and velocity of particles which are moving along neurons or are exchanged between neurons.
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    A theoretical model for considering the role of hemoglobin and other spinors in exchanging spin waves between brain and heart
    2022
     | Anka Publishers
    It has been known that both brain and heart produce magnetic fields however, intensity of heart magnetic field is more. The question arises that what is the relation between heart and brain waves. We answer this question by suggesting a theoretical model which use of hemoglobins and other spinors as packages of information and spin waves for exchanging information between heart and brain. In this model, heart genes within heart cells control motions of charged ions and their spins. By motions of these electrical and spinor ions, both electrical and magnetic waves are emerged. Electrical waves produce known action potentials and magnetic waves force on iron atoms within hemoglobins and electrons on other biological objects and induce spin waves and information in multigonal structures around them. Hemoglobins and other spinors are carried by blood cells and liquid molecules and move from heart to brain. Near neurons within the brain, magnetic spins within the hemoglobins and spinors force into ions and cause to their motion towards cells. These ions pass the neuron membranes, force on ionic packages and cause that some new ions become free. These charged/spinor ions produce electrical currents between neurons and emit some magnetic and electrical waves around the brain. We have done some calculations which show by increasing height differences between two mans, time differences for exchanging information between brain and heart increase. This result is related to local entanglement between spinors. However, there is additional non-local entanglements between spinors on the heart and spinors on the brain. These entanglements may be produced through two ways: 1. Some spinors within blood vessels and nerve systems may join to each other and form several strings. Any change in one of spins within this string, cause to changes in all spins. Thus, information could be transmitted between brain and heart immediately. 2. In addition to classical magnetic field which is produced by charged currents, there is another quantum magnetic field which is produced by spinors. This quantum wave couldn’t be detected by present devices, however any change in spinors on the heart cause to a change in quantum magnetic field and spinors on the brain. This is a theoretical model and could be a proposal for scientists to test it.
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