CNS Material by Prof Eze Nwanni PDF

Summary

This document provides an overview of the central nervous system's (CNS) neurophysiology, including the development of the brain and spinal cord, and their various regions and sections. It discusses the neural tissues and their functions, and also the peripheral nervous system, which also contains the 12 pairs of cranial nerves and 31 pairs of spinal nerves. Information on nerve cells, myelination, and the classification of nerve fibers is also included.

Full Transcript

27/4/23
CENTRAL NERVOUS SYSTEM (NEUROPHYSIOLOGY)
(Professor Ezenwanne)

Development of the brain and spinal cord
This starts with a primitive neural tube (simple neural tube). This is a tubular structure composed
of a cell layer and a central canal. Then, there is expansion in 3 ways, of unequal growth. This
gives rise to 3 areas: the forebrain, midbrain and hindbrain.

The lining cells multiply and give rise to nervous tissue of the developing brain and spinal cord,
while the canal gives rise to the ventricles of the brain and the central canal of the spinal cord.
Further development causes more complication and differentiation of the Central Nervous
System into areas such as:

Forebrain (Prosencephalon)
○ Telencephalon
Basal ganglia
Neopallium (cerebral hemisphere) (newer part)
Rhinencephalon (older part) (vital for olfaction)
○ Diencephalon
Thalamus
Hypothalamus

Midbrain (Mesencephalon)
○ Anterior part
Cerebral peduncles
Tegmentum
○ Posterior part
Tectum
Superior corpora quadrigemina (superior colliculus)
Inferior corpora quadrigemina (inferior colliculus)
 Hindbrain (Rhombencephalon)
○ Cephalic part (metencephalon)
Pons
Cerebellum
Cerebellar peduncles (superior, middle and inferior)
○ Caudal part (myencephalon)
Medulla

The tail of the neural tube also develops into the spinal cord. The neural tissues of the nervous
system have overall functions, categorized under the following headings:
Provision of sensation or sensory information
Integration of sensory information
Provision of coordination of voluntary and involuntary response
Regulation or control

Along with the endocrine system, these responses are boiled down into control, coordination
and communication. The two systems have a lot of differences though, such as speed, mode
of transmission, intensity of effect, intended response (endocrine is for metabolism) and sphere
of influence.
Integration refers to the collation and coalescing of input, for precise computation,
interpretation and analysis, used to determine the appropriate response(s) to that input.
For convenience of study, the nervous system is divided into 4 areas:
Sensory division - gathering of sensory information from all the sensory systems of the
body, and transmitting it to the integration center
Motor division - to control and coordinate bodily motor activities/motor activities of
effector tissues
Processing division - integration of incoming signals and determination of appropriate
response
Storage division - relevant for memory and thought. Synapses are very important here

General organization and functional plan
The brain is made up of 3 different regions:
Brain stem - made of the medulla, pons and midbrain
Cerebellum
Cerebrum - cortex, basal ganglia, thalamus, hypothalamus

The nervous system as a whole is divided into central (brain and spinal cord) and peripheral
(sensory/afferent and motor/efferent nerves).
A nerve impulse is the basis for the communication of information in the nervous system. It is
the language of the nervous system.
A nerve cell is the building block of the nervous system; the structural unit
Peripheral nervous system
This consists of two divisions, 12 pairs of cranial nerves and 31 pairs of spinal nerves. These
nerves form the link between the CNS and all organs and systems of the body.

Spinal nerves - each of these is in communication with the spinal cord via two Roots:
the posterior root and ventral root, from the dorsal and ventral horns of the spinal cord
respectively. The sensory nerves make use of the dorsal root, but they never go into the
spinal cord directly. Rather, they reside in the dorsal root ganglion and send their fibers
into the spinal cord. Motor nerves, on the other hand, use the ventral root and reside in
the gray matter of the spinal cord. There's no ventral root ganglion
Cranial nerves - these have no definite root system, and are identified using roman
numerals (Cranial Nerve I to Cranial Nerve XII)

Cranial Nerve Type Functions

I - Olfactory nerve Sensory Smell
nerve

II - Optic nerve Sensory Sight
nerve

III - Oculomotor nerve Motor nerve Eye movement for focusing

IV - Trochlear nerve Motor nerve Eye movement (up and down

V - Trigeminal nerve Mixed nerve Facial sensations, chewing

VI - Abducens nerve Motor nerve Eye movement (lateral),
proprioception

VII - Facial nerve Mixed nerve Taste, facial expressions, eye
 movement, salivary secretion

VIII - Vestibulocochlear Mixed nerve Hearing, balance (equilibrium)
nerve

IX - Glossopharyngeal Mixed nerve Taste, salivary secretion,
nerve swallowing, other sensations

X - Vagus nerve Motor nerve Movement and secretion of
abdominal and thoracic organs
(visceral reflexes), swallowing

XI - Accessory nerve Motor nerve Head, shoulder, larynx
movement, speaking

XII - Hypoglossal nerve Motor nerve Tongue movement

The brainstem is a part that's posterior to the brain and continuous with the spinal cord. It
consists of 3 parts:
Midbrain
Pons
Medulla oblongata
It connects the brain to the spinal cord. Although it is very small, or is a very important area of
the brain as it helps to relay information between the two parts of the CNS. It has many
functions, such as:
It houses many control centers for involuntary activities
The relay between brain and spinal cord
Coordination of motor and sensory function
Regulation of cardiac function
Regulation of breathing
Regulation of sleep
Regulation of consciousness
Regulation of eating and swallowing
Regulation of respiration
Regulation of blood pressure
Neural tract carries signals which are relayed from the cerebrum to the cerebellum and
vice versa
Integrative functions like alertness, arousal, digestion, pain, sleep

Diseases of the brain stem can result in many abnormalities, such as those of cranial nerve
function, including visual and hearing difficulty, muscle weakness, vertigo, dulling of sensations,
coordination problems, dysphagia, speech problems and voice changes, breathing difficulty or
apnea, changes in or cessation of heart rate, etc

3/5/23
Draw and label a typical motor nerve and typical sensory nerve (assignment)

Nerve cells

These are highly modified cells, for the transmission of electrochemical signals within the
nervous system. They are the functional unit. Even within nerve cells, there are also
modifications such as length of dendrites or presence of dendrites. Neurons of the CNS are
profusely dendritic. The soma themselves also vary in size. As for the axons, some of them
have branches, called collaterals, with some neurons having several collaterals. Even
dendrites sometimes have a major branch which forms its own branches, acting as a collateral
The difference in arborization leads to a difference in sensory field, which is the area of tissue
subserved by dendrites

Myelination of fiber tracts in the nervous system
Studies show that various tracts (pathways) receive myelination at different stages. These
include:
The sensory pathway, which are usually the first to become myelinated (from the early
embryonic stage)
 The posterior columns of the spinal cord, which are the second (4th - 5th month of
fetal life)
The spinocerebellar tract, third
The motor pathways/corticospinal pathways/pyramidal tract. These become
myelinated from the second month of fetal life, but take up to two years to complete
myelination, making them the last

Functions of the myelin sheath
A school of thought says that they function to confine impulses to individual nerve
fibers
Another says that it ensures greater speed of conduction of the nerve fiber

Functional organization of the nerve cell

The neuron can be split into 4 zones:
Receptor zone or dendrite zone. There's multiple local potential changes constantly
taking place here. This is called graded electrogenesis. They are not conducted
Initial segment zone. This is where action potential is initiated from the integration of
the graded potential
Axonal zone. This is where transmission of the action potential occurs. It ensures the all
or none transmission of impulse, and maintains the unidirectional nature of transmission;
towards the nerve endings
Nerve ending zone. This region ensures the secretion of the appropriate
neurotransmitter substance. The arrival of action potential at this zone triggers the
release of neurotransmitters from the storage vesicles into the synaptic cleft via
exocytosis

Classification of nerve fibers
The greater the diameter of a nerve fiber, the greater the speed of conduction
Conduction velocity is higher in myelinated fibers than in non myelinated
 There are larger axons which are mostly concerned with proprioceptive sensation.
They are also concerned with somatic motor function
The larger the diameter of a nerve fiber, the greater the magnitude of its electrical
response
The larger the diameter, the lower the excitation threshold and the shorter the duration of
it's response

Basis of system of classification
Erlanger and Gasser classify based on diameter and conduction velocity in mammalian
nerve cells. Based on this, there are A, B and C group fibers. But this was not a
satisfactory system of classification, so they further split group A into A𝜶, A𝜷, A𝜹 and A𝜸

Fiber Type Diameter Conduction Velocity Nature

A𝜶 12 - 20 µm 70 - 120 m/s They are mostly for proprioception

A𝜷 5 - 12 µm 30 - 70 m/s Tactile sensations, pressure and other
motor functions

A𝜸 3 - 6 µm 15 - 30 m/s Motor fibers to muscle spindles

A𝜹 2 - 5 µm 12 - 30 m/s Pain, temperature and touch

B