Electric fields that guide the 3D shape of cells and organs
How does the cell know what size and synoptic boost shape it should have? Many cells change their shape to provide different functions, such as microglia. Even more complex is the question of how organs, limbs and creatures know how big and how big they should be when they grow up. How do cells know how and where to form an organ? How does the creature know how to rebuild a branch cut into the correct size, shape and orientation?
There are thousands of these same questions, which include how astrocytes and neurons know the exact networks they should be forming. How do immune cells know how to travel in very complex 3D environments?
An equally difficult question has been addressed in previous publications on how Baby’s feetcell knows exactly what form a protein-encoded sequence will take. Cells and microbes modify the codes of their protein toxins that require extremely detailed and precise forms. In fact, modern science can not calculate the shape of a coded sequence of 400 amino acids when folded into a protein. It would take two thousand years for all the supercomputers to calculate the folding of an average protein. However, the proteins are assembled in the exact form in a millisecond, aided by very complex chaperone molecules. The cells regularly edit their messenger RNA with an alternative splice to create a variety of forms. How do they know how to do this?
Four Weeks Human Embryo: Pairing with B1402 If a cell is removed from a two-cell embryo, it becomes the creature itself.
Hungry worms shrink while maintaining perfect proportions between organs
Planaria can reproduce the whole body from a small piece
Amphibians can develop a perfectly proportioned limb
Many organizations need nerve-mediated information to maintain their shape and function
For all these questions, it is difficult to imagine the information of the 3D shape inside a cell, or even a group of cells. It seems more likely that an information field guides these processes. Does this evidence for an electric field of information form three-dimensional shapes of cells, organs and creatures, also, related to the influence of the mind?
Previous documents have shown the critical part played by the electrical synapses in the formation of the neural network structure that uses chemical synapses. In addition, a previous publication has shown that field potentials in and around brain cells, although little known, are important for specific functions. Several messages have documented the elaborate communication that occurs between cells through signaling, including neurotransmitters, brain factors, cytokines, and hormones.
A significant amount of research shows the importance of several gradients in the capillary space with red blood cells between cells for communication. This has been noticed in messages about the movement of platelets that attract and signal other immune cells. Another article has shown the elaborate trips of leukocytes. Now we know a lot about the morphogen gradients in the developing embryo: how the cells know where to go and what types of cells will be converted.