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Cytoelectric Coupling" is a groundbreaking hypothesis of our brain working.

Things like BCI systems make it possible to transfer human thoughts to the computer screen, making it possible what people see when they sleep. That ability allows researchers to go into the mystery world of imagination and dreams. 

When researchers use those neuro-interacting microchips is possible to see what people see while they sleep. The problem with dream research is how to confirm what a person tells. And another problem is that people cannot remember anything about their dreams. The person loses memories of dreams about a minute after waking up. And those memories contain only a small part of the sleeping sequences. 

If people use these kinds of things like suggestions and BCI systems. That makes it possible to use dreams in the R&D process. But for that thing, we should have perfect models of how the brain works and interacts. 

If we think that our brain is a quantum computer, we can say that this quantum computer has 200 billion different qubit states. In that model, every neuron has axon connections that allow it to connect with another neuron. And every single connection between neurons is a unique state of this awesome qubit. 

The number of neurons is not as important as the number of connections between them. Every single connection between neurons forms virtual neurons that act like physical neurons. And there are possibilities to make about 200 billion virtual connections. The connection between two neurons side-by-side is the same way important as the connections between neuron groups around the brain. In the brain is no meaningless connections. 

A new theory, called "Cytoelectric Coupling" is the model where researchers try to explain why our brain has so many functions with low-level energy use. The groundbreaking model tries to explain why our brain is so effective. The model is simple. The information travels in the neural system to the molecular- and maybe even to the atomic level. The atomic level connections mean. 

That there could be more than 200 billion connections and virtual connections. The thing is that EEG impulses transport information in the brain. And those electromagnetic fields are also interacting with each other. So how big a role do those EM fields and their interaction play in brain functions? Cytoelectric Coupling tries to explain those interactions. 



"Researchers from MIT and Harvard have demonstrated that people are more creative when awakened from early sleep stages and guided to dream about a specific topic. This method, facilitated by a device called Dormio, increased creativity by 43% in comparison to those who napped without specific dream guidance". (ScitechDaily.com/Harnessing Hypnagogia: MIT and Harvard’s Breakthrough in Boosting Creativity Through Targeted Dream Incubation)


"Brain waves act as carriers of information. A recently proposed “Cytoelectric Coupling” hypothesis suggests that these wavering electric fields contribute to the optimization of the brain network’s efficiency and robustness. They do this by influencing the physical configuration of the brain’s molecular framework". “ScitechDaily.com/ Cytoelectric Coupling”: A Groundbreaking Hypothesis on How Our Brains Function.)

The powerful self-suggestion made it possible that Friedrich August Kekule von Stradonitz could model the Benzene molecule's structure. He saw that structure in a dream, and I will return to that thing a little bit later. 

But then we can think about the theory about the quantum world and its effect on the brain working. The question is this. How deep interaction between particles in the brain is? How small are the particles that take part in the brain working? 

Deep knowledge of brain functions makes developers possible to control the brain's working. Researchers at Harvard and MIT improved creativity by using targeted brain incubation. We know that human is the most productive while sleeping. 

Sleep releases neurons that normally handle sensor-motor functions to production processes. And the problem is that we cannot remember anything about this thing. Many great inventions are forgotten just after a person wakes up. 

The reason why I believe that is simple. Many great inventions are made while a person sleeps. And some of those people just wrote those things to papers. The most well-known of those cases was the finding of the form of the Benzene molecule, where Friedrich August Kekule von Stradonitz saw the molecule while he sleep. 

And that thing made him understand how carbons were in the Benzene molecule. Or actually, Kekule von Stradonitz saw a snake that ascending from the fire. And then that bites its tail. And then that vision made him understand the form of Benzene. 

Kekule von Stradonitz thought that form very hard. And then that form was solved while that man slept. So the reason for that sudden happening success was self-suggestion. And of course, he was lucky that he wrote that thing in his papers. 

But the fact is this: by using BCI systems and suggestion is possible to transform dreams into a tool for the R&D process. If the BCI system can see images what a person sees that thing takes us deeper into the mythic world of dreams. 



https://scitechdaily.com/cytoelectric-coupling-a-groundbreaking-hypothesis-on-how-our-brains-function/?expand_article=1

https://scitechdaily.com/harnessing-hypnagogia-mit-and-harvards-breakthrough-in-boosting-creativity-through-targeted-dream-incubation/


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