Biological Rhythms Brain

Neuronal Rhythm (Brain Motility)

Reciprocal Movement of Brain’s Driving Force: - The entire temporal lobe has a medial translatory pull from the tentorium which pulls medially at a reciprocal 4 cycles/minute rate. That pull of tentorium is from the cross line structure (“table”) of the heart (below the superficial cardiac plexus that is pulled: one arm, then the other, by the traction of the pericardium on either arm of the cross-like structure. The traction of the pericardium from outside the chest is at the arches of the subclavians. Those arches are pulled at the SCM with a temporal traction. A system. - Hydrostatic pressure is the system behind the CRI. The system is ventricular expansion and contraction is from sagittal sinus choroid plexus production of CSF at the rate of 7-14 cycles/minute because of: Heart cross is large cross-like structure that pulls on subclavian arteries, that pull on Circle of Willis, which is reciprocal and in trun turns on and turns off production at the choroid plexus that can regulate pressures.

The Brainstem as an intermediary component of the brain, has 3 planar motion with more sagittal plane motion with coronal and transverse plane movements at the superior aspects of the brainstem, almost totally longitudinal at the inferior aspects of the brainstem. Typically, medulla is the place of transition motility and pons has 50% sagittal plane motion with 30% coronal plane and 20% transverse plane motion, medulla has 30% of each of pons 3 planar movement, and the remaining 10% is pure longitudinal with the foramen magnum region being pure longitudinal motion. There is a motility of the Cranial Nerves that is longitudinal and similar to the peripheral nerve motility. The Spinal Cord motility is vertical with a longitudinal inferior motion during flexion phase and a longitudinal superior motion during extension phase. The Peripheral Nerves motility is longitudinal along their axis and has a displacement of 4mm with flexion and 4mm with extension phase, which results in a total of 8 mm excursion from motility. This means that in flexion phase, there is an inferior longitudinal motility during ½ of flexion phase, with a superior longitudinal mobility during the second half of flexion phase, which reaches neutral between phases. During extension phase there is a superior longitudinal motility during the first half of the extension phase, and an inferior longitudinal motility during the second half of extension phase, reaching neutral between phases.

There is an excursion with an axis for each lobe and each unique phenomenon function correlated structure in the brain, that all together produce an axis for total brain motility. At the resultant axis, there is no displacement of tissue, rather an interface with membranous and insular motility.