Becker chose to experiment on salamanders because it was almost as physically complicated as a human being, yet had an amazing ability lacking in other mammals to spontaneously regenerate a severed limb.
Becker was exploring ‘what’, biologically-speaking, organized the growth of this new limb, and how the blastema - a little ball of undifferentiated cells that can turn into any other cell - knew what to do.
WHAT ORGANISES CELLS TO BECOME A PERSON OR CREATURE?
It was the same question, phrased in different words, that had the embryologists stumped, too: what was organizing the undifferentiated cells? What was controlling their development and corralling the process of regeneration?
Earlier on, in the 1930s, Paul Weiss floated the theory that the body had some sort of intangible ‘morphogenetic field’ that held the blueprint of what the body would become. The idea didn’t get very far in more traditional scientific circles, so by the time Becker came on the scene, no real progress had been made to try find if such a field actually existed, and if it did, how it actually stimulated undifferentiated cells to switch particular genes on and off.
Becker had his work cut out for him, not least because the overwhelmingly ‘mechanist’ view of medicine was shooting down any ideas that had even a whiff of belonging to the vitalist view point of life.
Becker writes: “When I started out, it was very dangerous for one’s career even to suggest that mature cells might create the blastema by de-differentiation.”
Yet amazingly, that’s what Becker’s subsequent experiments proved conclusively.
THE CURRENT OF INJURY
Becker began by reviewing the work of Russian biophysicist, A.M. Sinyukhin, whose work with tomato plants turned up what came to be called a ‘current of injury’. Sinyukhin cut branches off tomato plants, and then measured what was happening electrically near the place of the ‘wound’.
Over the first few days after the injury, a stream of electrons that formed a negative current flowed from the wound. The same thing happens to wounds in animals, too. In the second week, as a ‘scab’ formed on the wound and a new branch started to grow, the current reversed polarity to become positive, and became stronger.
As the positive current increased, the tomato plant’s cells at the site of the wound more than doubled their metabolic rate, became more acidic, and started producing more Vitamin C.
Sinyukhin’s experiments proved some very important principles:
1) That a change in the electrical current seemed to be linked to regeneration
2) The electrical current that initiated these changes was tiny - between 2 - 3 amperes.
Armed with this information, Becker started experimenting on salamanders (that can regenerate limbs) and bullfrogs (that can’t regenerate limbs).
Amongst other things, Becker’s experiments showed that:
- The current of injury was proportional to the amount of nerve present - and developed human beings have 80 less nerves in their limbs than simpler creatures.
- The current of injury stimulated de-differentiation of cells and regeneration (i.e. electrical stimulation could in theory create new STEM CELLS in an adult body...)
- DC current within the central nervous system regulate the sensitivity of neurons by:
- Changing the amount of current flowing in one direction
- Reversing polarity (i.e. changing the current’s direction)
- Modulating the current with slow waves (EXPLAIN THIS BETTER)
- External DC currents can and do affect the way the human brain operates
- The direction of current in the human brain (normally from front to back) changes with different states of consciousness.
- It’s strongest during heightened physical or mental activity
- Weaker in states of rest
- Reverses direction running back to front in normal sleep and anaesthesia.
- Living tissue acts like a semi-conductor of bio-electricity. Many semi-conductors (including the human body) absorb energy from light.
- Bone is piezoelectric (i.e. converts ‘stress’ into an electrical signal.) If it’s ‘squeezed’ or pressured hard enough when bent, a small, temporary negative charge is produced that migrates towards the area of compression.
- Bone is also photoelectric [which means that when electricity goes in, light comes out], and acts as a Light-Emitting Diode (LED).
- Trace metals like:
- Copper greatly affects the electrical nature of bone, and the way the apatite crystals and collagen fibers found in bone ‘fit’ together.
- Electricity controls the growth in bone.
Becker found that the body’s electrical field mapped to the body’s nervous system, with the head and spinal region being strongly positive. He also found that the body’s tiny DC current controlled the way nerves worked in the brain, as well as the rest of the body, including regulating states of consciousness.
“Redifferentiation instructions are passed along a tissue arc whose main element is the circuit already established between nerves and epidermis….The direction (polarity) plus the magnitude and force (amperage and voltage) of current could serve as a vector system giving distinct values for every area of the body. The electric field surrounding continuously charged and diminished with the distance from the nerve would provide a third coordinate, giving each cell a slightly different electrical potential…A magnetic field must exist around the current flow…adding a fourth dimension to the system. Together, these values might suffice to pinpoint any cell in the body.”
The idea is that these electric and magnetic fields could affect the charged cell membrane’s “‘choice’ of what ions to absorb, reject or expel’ - or to put it another way, could sway which genes gets switched on or off in every particular cell, together with the associated chemical changes.
In theory, Becker’s experiments proved that an electrical current was ‘the primary stimulus that began the regenerative process, and that it could operate in mammals.’ But then he hit the next problem: there weren’t enough electrically-sensitive cells in human bone marrow to make enough a big enough blastema to regenerate a limb in a human. So Becker turned his attention to trying to find a way of making other cells in the human body ‘electrically sensitive’, so that they could also dediffentiate when a tiny current of electricity was applied.
SILVER IONS KILL ALL TYPES OF BACTERIA WITHOUT SIDE-EFFECTS
Becker discovered that using a silver electrode ‘at the positive pole killed or deactivated every type of bacteria without side-effects, even with very low currents.’ But that wasn’t even the only amazing thing he discovered. He also learnt that a positive silver electrode ‘dedifferentiates connective tissue cells’, called fibroblasts.
What 'positively charged' silver ions was proven to do:
- Stimulate bone-forming cells
- Cure even very stubborn bacterial infections
- Stimulate healing in skin and other soft tissue
- Stop the runaway mitosis of cancerous cells (fibrosarcoma cells) in their tracks.
NOT ALL CELLS IN THE HUMAN BODY CAN DEDIFFERENTIATE
Not all cells in the human body can dedifferentiate. The following cells were all dediffentiated in response to electrical stimulus by Becker and his team:
- Bone marrow cells (immature erythrocytes)
The right amount of electrical current has to be aimed at the right type of cells for de-differentiation to occur.
THE BODY'S BIO-ELECTRICITY IS FLOWING THROUGH THE PERINEURAL CELLS
It’s now believed that the body’s current flows through the perineural cells. Perineural cells is a catch-all description for many different types of cell that surround every nerve cell like a kind of ‘sheath’, and which account for 90% of the human brain.
The neuron is the basic unit of all nervous sytems. Nerves are how different parts of the body communicate. The whole neuron is ‘wrapped’ in different sorts of perineural cells. The different types of perineural cells in the brain are called ‘glia’. Schwann cells ‘wrap’ the axons and dendrites of the neural cells in the spinal cord.
Schwann cells form a sort of tube made up of spiraling layers of myelin around the largest fibers. Ependymal cells line the four brain cavities, or ventricles of the brain, and also the central canal of the spinal cord.
Perineural cells play a big role in getting nutrients to the neurons, in controlling the diffusion of ions which in turn effects impulse firing, in memory, and in conducting the direct currents that ‘regenerate’ different parts of the body.
Becker discovered all these things more than 35 years’ ago, back in the 1980s. But instead of eagerly starting more research into these findings, to see how they could be safely applied to improving human health - his funding was pulled, and his small lab was disbanded, due to lack of funds and political pressure.
We can't find a 'cure' for cancer, and other serious illnesses for as long as we continue to look in the wrong places for it.