he body be born electricity? The answer is YesBut it’s worth digging deeper. as well Scientists They have been studying for a long time microbiome and the genome From the people, there are now two approaches that seek to understand the so-called electruma. under the dynamics Bioelectricitythe Cells communicate each other so that each part of Organism works properly.
This is how the scientific publisher explained it Sally Eddy In his new book called We are electricity. “And so electrical signals Supports global communication networks, we find that they do the same thing in our bodies. We are electric machines that we have not even dreamed of in their full dimensions. Electricity runs through our area nervous cellsmakes our win heart “It flows into every cell of the body,” Addy said.
He added, “Bioelectrics is a surprisingly unexplored field of science that involves all parts of the body. Scientists are looking for ways to manipulate the body’s natural electric fields to treat injuries, depression, paralysis, and even cancer.”
How was Adee’s interest in bioelectricity born? On a trip to California, USA, he participated in a simulation designed to train snipers in the use of electric shocks that elicited startle responses. “Having an electric field that hit my nerves instantly sharpened my ability to focus,” the writer said.
This event was the beginning of his book, which was published in February 2023. He highlighted in the text: “The next scientific frontier could be decoding the photoelectric code in the same way we did with the genetic code.”
Mustafa Jamjouz He is Professor Emeritus at Imperial College London, where he is devoted to cancer biology. in a report with BBC WorldÇamguz described how bioelectricity works: “All the elements in our bodies, such as sodium, potassium, calcium, magnesium and zinc, go through a chemical reaction that causes their atoms to separate, forming what is known as negativeswhich are electrically charged particles – close to 0.07 volts-. Our bodily fluids are full of these ions. Those with opposite charges attract each other, those with the same charge repel each other. And when they travel through our bodies they generate a current.”
Secondly, the expert went deeper, saying: “When we think of the electrical properties of the body, the first thing we think of is the brain, heart and muscles, but the truth is that even the microbes in our gut, the immune system and the carcinogens Generate electrical signals“.
In Çamguz’s view, “Humans have 22,000 genes, and everyone has a different genetic makeup, and that’s why we have personalized medicine. But in the field of bioelectricity, there is one basic law that applies to everyone, as all cells and tissues in our bodies use the same process to communicate.”
According to Adi in his book, one of the pioneers of bioenergy was Italian scientist Luigi Galvani. It was in the eighteenth century that he discovered in his laboratory that the bodies of animals generate their own electricity. as I did? He conducted experiments on frogs: he applied an electric current to the spinal cord of one of the frogs that had already died and observed that there were pronounced muscle spasms. This result even gave him the feeling that the animal was alive.
In a manuscript written by Galvani as a report, there is an eloquent phrase that reflects the curiosity aroused by these proceedings. “We can never suppose that fortune will be so kind to me, that perhaps it will allow me to be the first to deal, as it were, with the electricity hidden in the nerves.”
“The idea was created, but at that time electricity was not for biology. It was for machines, telegraphs, and chemical reactions,” Addy reviewed the pioneering development of Galvani, who was widely criticized for his speculations about the electricity of a living organism and his electrocution of animals. However, at about the same time, the idea of \u200b\u200bthe Italians was associated in another discipline with the invention of the electric battery by one of its compatriots, the physicist Alessandro Volta.
Since the 1990s, Djamgoz and his team of colleagues have been working on a development that has not yet been tested in humans, but that could change paradigms of medical approach to cancer. Being a disease in which cells grow and spread uncontrollably, the scientist triggered a series of thoughts. Cancer cells generate a buzz of electrical activity and this makes them hyperactive Electrically excitable.
“The problem with cancer is that there is no tumor,” Çamguz assumed. You can live with a tumor as long as it is localized. The big problem is when the cancer spreads, in a process we call metastasis. To stop this cell overgrowth, these cells’ ion channels, which are responsible for causing electronic excitations that promote cancer growth, can be blocked.
Another avenue that scientists take with bioelectricity is wound healing, with Addie noting in her book that cells “generate an electric field upon injury.” Interfering with this dynamic can speed up recovery. The ideas still need to be explored and reconfirmed, but the fact is that bioelectricity is here to stay.