Caudad: Towards the tail or posterior end.

Caudad Equina: The roots of the Upper Sacral Nerves that extend beyond the end of the Spinal Cord, at the first Lumbar Vertebra in the form of a bundle of filaments within the Spinal Canal resembling a horse's tail.

Caudal: Situated in or directed toward the hind part of the body.

Caudate Nuclius: One of four Basal Ganglia in each Cerebral Hemisphere that comprises a mass of Gray Matter in the Corpus Striatum. Forms part of the floor of the Lateral Ventricle, and is seperated from the Lentiform Nucleus by the Internal Capsule.

CerebroSpinal Fluid: A liquid that is comparable to Serum but contains less dissolved material. It is secreted from the blood into the Lateral Ventricles of the Brain by the Choroid Plexus.

It circulates through the Ventricles to the spaces between the Mennings about the Brain and Spinal Cord, and is resorbed into the blood through the SubArachnoid Sinuses, and it serves chiefly to maintain uniform pressure within the Brain and Spinal Cord.

The Cerebral Cortex Arteries

• The Anterior Cerebral Artery: Arises from the Internal Carotid Artery, forms the Anterior portion of the Circle Of Willis where it is linked to the artery on the opposite side by the Anterior Communicating Artery, and passes on to supply the medial surfaces of the Cerebrum.
• The Middle Cerebral Artery: Arises from the Internal Carotid Artery, passes along the Lateral Fissure and supplies the Lateral surfaces of the Cerebral Cortex.
• The Posterior Cerebral Artery: Arises by the terminal forking of the Basilar Artery, where it forms the Posterior portion of the Circle Of Willis and passes on to supply the lower surfaces of the Temporal and Occipital Lobes.

Ventral:
Being or located near, on, or towards the front of the human body

Vermis:
• The Median Lobe or part of the Cerebellum
• Either of two parts of the Median Lobe of the Cerebellum:
  • One slightly prominent on the upper surface, called the Superior Vermis
  • The lower surface, sunk in the Vallecula, called the Inferior Vermis

ForeBrain:
The Anterior of the three major divisions of the developing Vertebrate Brain.
- the corresponding part of the adult Brain that includes the Rostrad.

Especially the Cerebral Hemispheres and more Caudally, the Thalamus and the HypoThalamus. [See: DienCephalon (TelenCephalon)].

Rostrad:
In a Rostral direction; the Dorsal layer of the Fascia

Rostral:
Anterior or Ventral to the Pons

Rostrum:
The reflected Anterior portion of the Corpus Callosum below the Genu.

Scanning Speech:
The slow enunciation with a tendency to hesitate at the beginning of a word or syllable is common in advanced disease.

Aphasia:
The loss or impairments of the power to use or comprehend words. Usually resulting from a Brain Lesion.

SpinoThalamic Tract:
Any of the four Nerve Tracts of the Spinal Cord that are arranged in pairs with one member of a pair on each side and that ascend to the Thalamus, by way of the BrainStem.

• One on each side of the Anterior Median Fissure that carries Nerve Impulses relating to the Sense of Touch. Also called Anterior SpinoThalamic Tract or Ventral SpinoThalamic Tract.

• One on each Lateral part of the Spinal Cord that carries Nerve Impulses relating to the Senses of Touch, Pain, and Temperature. Also called Lateral SpinoThalamic Tract.

SpinoCerebellar Tract:
Any of four Nerve Tracts which pass from the Spinal Cord to the Cerebellum and of which two are situated on each side external to the crossed CorticoSpinal Tracts:

• A Posterior Tract on each side that arises from cells in Clark's Column, especially on the same side and passes to the Inferior Cerebellar Peduncle and Vermis of the Cerebellum, also called Dorsal SpinoCerebellar Tract.

• An Anterior Tract on each side that arises from cells mostly in the dorsal column of Gray Matter on the same or opposite side and passes through the Medulla Oblongata and Pons to the Superior Cerebellar Peduncle and Vermis. Also called Anterior SpinoCerebellar Tract.

PeriVentricular - situated or occuring around a Ventricle of the Brain, and within the White Matter.

#16

Black's Medical Dictionary

____________________________________
FILE __TABLE_OF_CONTENTS________PAGE
16-00__The Brain & Nervous Systems____99
______Basal Nuclei, Pons, Cerebellum__100 - 101
______Multilpe Sclerosis Is__________466
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The Brain and Spinal Cord together form the Central Nervous System, with Twelve Cranial Nerves passing on each side from the Brain and thirty-one nerves from the Spinal Cord, called the Peripheral Nervous System.

While a complex chain of Nerves and Ganglia lying within the chest and abdomen, and acting to a large extent independently of the other two systems, though closely connected with them, make up the Autonomic Nervous System(ANS), and govern the activity of the Viscera.

The Cerebrum: forms the great bulk of the Brain and consists of two Hemispheres which occupy the entire vault of the Cranium and are incompletely seperated from each other by a deep median cleft, the Longitudinal Cerebral Fissure.

The Corpus Callosum: is a thick band of more than 200 million transverse Nerve Fibers, which is the only connection between the Hemispheres of the Cerebrum. It lies at the bottom of the Longitudinal Cerebral Fissure.

The outer 3mm or thereabouts of the Cerebral Hemispheres consists of Gray Matter largely made up of Ganglion Cells.

While in the deeper part the White Matter consists of Myelinated Nerve Fibers connecting different parts of the surface and passing down to the lower parts of the Brain.

Among the White Matter lie several rounded masses of Gray Matter, the Lentiform and Caudate Nuclei. In the center of each Cerebral Hemisphere is an irregular cavity, the Lateral Ventricle.

Each of which communicates with that on the other side and behind with the Third Ventricle through a small opening, the InterVentricular Foramen, or Foramen of Monro.

The Basal Ganglia (Nuclei) consists of two large masses of Gray Matter imbedded in the base of the Cerebral Hemispheres. Between these two masses lies the Third Ventricle.

From which the Infundibulum, which projects downwards into the Pituitary Body, and above lies the Pineal Gland. This region lies above the important HypoThalamus.

The MidBrain or MesenCephalon, is a stalk about 20mm long connecting the Cerebrum with the HindBrain. Down its center lies a tube, the Cerebral Aqueduct, or Aqueduct of Sylvius, connecting the Third and the Fourth Ventricles.

Above this aqueduct lie the Corpora Quadrigemina, and beneath it are the Crura Cerebri (CorticoSpinal Tract), strong bands of White Matter in which important Nerve Fibers pass downwards from the Cerebrum.

The Pons is a mass of Nerve Fibers, some of which run crosswise and others are the continuation of the Crura Cerebri (Cerebral Peduncle) downwards.

The Cerebellum lies towards the back, underneath the Occipital Lobes of the Cerebrum.

The Medulla Oblongata is the lowest part of the Brain, in structure resembling the Spinal Cord, with White Matter on the surface and Gray Matter in its interior.

This is continuous through the large opening in the skull, the Foramen Magnum, with the Spinal Cord. Between the Medulla, Pons, and Cerebellum lies the Fourth Ventricle of the Brain.

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Structure

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The Brain is made up of Gray Matter and White Matter. In the Cerebrum & Cerebellum the Gray Matter is arranged mainly in a layer on the surface, though both have certain Gray masses imbedded in the White Matter.

In the other parts, the Gray Matter is found in definite masses called Nuclei, from which the Nerves spring.

The Gray Matter consists mainly of cells in which all the activities of the Brain begin.

These cells vary considerably in size and shape in different parts of the Brain, though all give off a number of Processes, some of which form Nerve Fibers.

The cells on the surface of the Cerebral Hemispheres, for example, are very numerous, being set in layers five or six deep. In shape these cells are Pyramidal, giving off Processes from the Apex, and from the center of the base.

From various projections elsewhere on the cell. The Gray Matter is everywhere penetrated by a rich supply of blood vessels and the Nerve Cells and blood vessels are supported in a fine network of fibers, known as Neuroglia.

The White Matter consists of Nerve Fibers, each of which is attached, at one end, to a cell in the Gray Matter.

While at the other end, it splits up into a tree like structure round another cell in another part of the Gray Matter in the Brain or Spinal Cord.

The fibers have insulating sheaths (Myelin)of a fatty material, which in mass, gives the White Matter its color, and they convey messages from one part of the Brain to the other (Association Fibers),

Or, grouped into bundles, leave the Brain as Nerves, or pass down into the Spinal Cord, where they end near and exert a control upon cells from which in turn spring the nerves to the body.

Both Gray and White Matter are bound together by a felt work called Neuroglia. The general arrangement of fibers can be best understood by describing the course of a Motor Nerve Fiber.

Arising in a cell on the surface in front of the Central Sulcus, such a fiber passes inwards towards the center of the Cerebral Hemisphere, the collected mass of fibers as they lie between the Lentiform Nucleus and Optic Thalamus being known as the Internal Capsule.

Hence the fiber passes down through the Crus Cerebri, giving off various small connecting fibers as it passes downwards.

After passing through the Pons it reaches the Medulla, and at this point crosses to the opposite side (Decussation Of The Pyramids).

Entering the Spinal Cord, it passes downwards to end finally in a series of branches which meet and touch (Synapse) similar branches from one or more of the cells in the Gray Matter of the Cord.

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Function

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The maximum mass of Brain tissue is reached at the age of 20, and then steadily decreases. The Cerebrum is associated with intellectual faculties and also exerts a guiding influence over the rest of the Nervous System.

However, it is not necessary for actual life. The Cerebellum maintains balance, is concerned with the regulation of muscular movements and in preserving the equilibrium of the body.

Between 1820 and 1840 it became established that in people who have lost the power of speech during life, the Brain shows some disease in the Left Frontal Lobe after death.

In 1861 Broca made the first definite discovery in Cerebral localization by proving that the faculty of speech is governed by a center in the region of the Inferior Frontal Gyrus named (after him) Broca's Convolution.

His discovery was followed later by the important observation of Hughlings Jackson that certain forms of Epilepsy, associated with movements beginning in a definite limb are caused by disease affecting the part of the Brain that borders on the Central Sulcus.

This discovery was confirmed and extended by many experimenters and physicians. Grunbaum and others have shown that definite areas near the Central Sulcus are associated with the movement of definite parts.

The Occipital Lobes are associated with the sense of Sight. The Temporal Lobes with Hearing and the inner surface of the same Lobe with the senses of Taste and Smell.

The purely intellectual faculties are probably associated with The Frontal Lobes, which seem to govern nothing else.

#16
p466

MS is a disease of the Brain and Spinal Cord which though slow in its onset, in time may produce marked symptoms, such as paralysis and tremors, and may ultimately render people suffering from it confirmed invalids.

It consists of hardened patches, from the size of a pin-head to that of a pea or larger scattered here and there irregularly through the Brain and Cord each patch being made up of a mass of the connective tissue (Neuroglia), which should be present only in sufficient amount to bind the Nerve Cells and Fibers together.

In the earliest stage, the insulating sheaths of the Nerve Fibers in the hardened patches break up are absorbed, and leave the Nerve Fibers bare, the connective tissue being later reformed between these.

Although one of the most common Central Nervous System diseases in Europe - there are around 50,000 affected individuals in Britian alone, the cause is still not known.

The disease comes on in young people (onset being rare after the age of 40), apparently without any previous illness. It is more common in first and second children than in those later in birth order, and in small rather than big families.

There may be a hereditary factor, but this is by no means proven. If such exists it is of an obscure nature and linked more to a deficit in the person's reaction to infection than to any precise defect in the Nervous System.

The actual changes in the Nervous System appear to be due to the action of some substance which dissolves or breaks up the fatty matter of the nerve sheaths.

Symptoms depend greatly upon the part of the Brain and Cord affected by the Sclerotic Patches.

Temporary paralysis of a limb, or of an eye muscle, causing double vision and tremors upon exertion, first in the affected parts, and later in all parts of the body, are early symptoms.

Stiffness of the lower limbs causing the toes to catch on small irregularities in the ground and trip the person in walking, is often one of the first symptoms to be noticed and it is quite annoying.

Increased activity is shown in the reflex movements obtained by striking the tendons and by stroking the soles of the feet.

The latter reflex shows a characteristic sign (Babinski Sign) in which the great toe bends upwards and the other toes spread apart as the sole is stroked, instead of the toes collectively bending downwards as in the normal person.

Tremor of the eye movements (Nystagmus) is usually found. Trembling handwriting, interference with the functions of the Bladder, Giddiness and a peculiar Staccato or Scanning speech are common symptoms at a later stage.

Numbness and tingling in the extremeties occur commonly, particularly in the early stages of the disease.

As it progresses, the Paralyses, which were transitory at first, now become confirmed, often with great rigidity in the limbs. Many cases progress very slowly and show little or no tendency to shortening of the duration of life.

Treatment is unsatisfactory, because the most that can be done is to lead a life as free from strain as possible, to check the progress of the disease.

It is important to keep the nerves and muscles functioning and therefore the patient should remain at work as long as he or she is capable.