John Lorber 1915-1996 produced images of hundreds of brains and found many cases of hydrocephalus that had resulted in reduced brain size but with often no great cognitive impairment. In one case, a young man had an IQ of 126, gained a first class honours degree degree in mathematics and had normal social function but hardly any brain.
“When we did a brain scan, we saw that instead f the normal 4.5 cm thickness of brain tissue between the ventricles and the cortical surface, there was just a thin layer of mantle measuring a millimetre or so. His cranium is filled mainly with cerebrospinal fluid.” – John Lorber
The man had been referred to a physician as a boy because his head was slightly larger than normal.
What does all this mean?
The conundrum here is that the human head is quite large and uses up a lot of resources, which by itself is an evolutionary disadvantage. There must be some other pressing need then for a large cranium although brain volume seems irrelevant.
The logical conclusion is that the important factors in the workings of the brain are not the volume or number of neurons but instead the overall shape, size and proportions of the organ itself.
To see how this could be so we will need to understand a bit about embryonic development, fluid pressure, scalar waves, electromagnetic forces, fractal holo-fields and the golden ratio.
If, after this, things still seem a bit incredible then we can recall the words of Sherlock Holmes: ”When you have eliminated all which is impossible, then whatever remains, however improbable, must be the truth.”
In embryonic development we find that blood flow precedes the development of the blood vessels and apparently acts as a guide for their development somehow. Electric fields are suspected and this idea is reinforced by the observation that spiralling blood flow in the aorta is instrumental in the formation of the heart as a spiral vortex machine,
Once the heart is formed, regulation of pressure serves to refine the shape and determine the dimensions of the arteries and indeed the thickness of their walls.
Consideration of development is important. Evolutionary processes are commonly evaluated according to their function but what is hardly ever discussed is that every physical feature in biology has to have a physical cause; there has to be some developmental plan that can result in that organ or ability,
The developmental function of the early brain then is to increase in size thereby exerting a gentle outward pressure (static electric forces) on the still malleable skull and causing it to expand at a controlled rate. There is no need for DNA to be involved here, the forces are physical and the ‘plan’ is simple.
The brain grows in a particular way which determines the rate of expansion of the skull. Grey matter is added in a way that results in a ‘blooming’ much like a cauliflower or cloud might develop. This allows for a refinement of shape which a simple balloon-like inflation would not.
A skull that is expanded via a filling of water will experience equal pressure in every direction and tend to be larger, wider and more spherical than the norm.
The Golden Ratio
The normal skull is not spherical though, it has a very specific shape of very specific proportions and those proportions involve the Golden Ratio.
So to provide fine-grained control the shape of the developing brain then we need a morphogenic field that somehow ‘knows’ about the Golden Ratio.
As luck would have it, the scalar waves of Konstantin Meyl are the ideal candidate for such a function. It isn’t so much that they are capable of such a ratio but that they naturally form three dimensional structures whose most stable state has dimensions in the Golden Ratio.
So these dimensions then are actually ‘hard-coded’ into the laws of physics and it should not be surprising then to find them cropping up all over the place. As an example, the dimensions of the red blood cell are also in this ratio: Blood flow and scalar waves
So a series of linked toroidal scalar waves are suspected of being instrumental in the development of the brain and skull. But what happens once development is complete?
This magneto- electric field now has another function which is to act as the substrate for cognition. The whole brain is the host for a distributed ‘holographic’ field which is responsible for information management for the rest of the body as well as intellectual and emotional computation.
The field is non-dissipative and maintains stability as a toroidal attractor state with the ideal dimensions to suit its physical nature.
Mae-Wan Ho has described the field in the brain as a sequence of nested torii with each layer vibrating to a different frequency and the ratio of the frequencies between adjacent layers as being equal to Φ, the golden ratio again. This ensures that there is minimal resonance between layers of the field and hence least interference but maximal independence between layers of the field. Good design.
Signals are sent to and from the brain via the nerves but again using scalar waves as the transmission medium: Scalar waves and nerves.