III.   Biological Systems (PSYBIO)

Microtubule Binary Arrays (MBA) are one of the three (3) primary Solid State Memory Systems (MEM) of all hydro-carbon species life forms. Microtubule Binary Arrays (MBA) are highly stable polymer arrays of α- and β-tubulin dimer protein pairs that possess a natural binary (0 or 1) behavior arranged in circular patterns of thirteen (13) pairs that extends for a few hundred rows as part of centriole, or many tens of thousands of rows in the case of their structural use within axons.

Tubulin dimer (α- and β) proteins are made up of approximately four hundred fifty (450) amino acids and possess the important and consistent behaviour of switching from an open “1” or closed “0” position depending on the presence and position of electrons near its structure. Microtubules are then tube like configurations of thirteen (13) pairs of tubulin dimers per row with the “tube” filled with pure neutral water molecules.

The position of tubulin dimers per row within a microtubule being in a “closed” or “open” position is determined by the time of its assembly and is fixed for the life of the microtubule.

The machine language instructing how the tubulin dimer are to be assembled within a microtubule of centriole and endoplasmic reticulum is via RNA encoded with Base2 Codon (6 nucleotides) or B2C language, transcripted from DNA or messenger RNA produced directly by neural cells when producing new neurons or dendrite extensions.

The reverse or reading of position of tubulin dimer in rows of microtubule may be read back into messenger RNA also using the Base2 Codon (6 nucleotides) or B2C language in the case of transferring instruction from key microtubule such as centriole and endoplasmic reticulum.

The programming of the microtubule of axons and dendrites of a neuron is via the Base4Codon (12 nucleotides) or B4C language of RNA / DNA.

When electrons are passed through the neutral water of a microtubule, not only will the electron stream be allowed to reach the end with minimal interference, but the rows of tubilin dimer will react by contracting or remaining neutral producing a unique pulse or vibrational wave, based on the unique fixed arrays of tubilin within the microtubule. The greater the strength of electrons, the greater the unique micro pulse and vibration.

The unique vibration produced by the contraction events within a microtubule is used by neurons to produce sympathetic, building and contrasting micro pulses which using the laws of physics permit complex mathematical calculations to be resolved using wave calculus.