Introduction to Neurology PDF

Summary

This document provides an introduction to neurology, focusing on the nervous system's structure and function.

Full Transcript

neurology Introduction to neurology

Nerve tissue
Nerve tissue is the main tissue component of the nervous system and is primarily
composed of neurons and supporting glial cells.

1. neurons
 structure of a neuron

 Types of neurons:

1
 neurology Introduction to neurology

2. Supporting glial cells
 Overview of glial cells

N.B.
Each myelinating Schwann cell insulates only ONE axon.
Glial cells guard the axons of the nerve cells as COPS:
CNS axons are myelinated by Oligodendrocytes; PNS axons are insulated by Schwann
cells.

 Blood-brain barrier

2
 neurology Introduction to neurology

Myelin
 Insulating layer of modified plasma membrane that wraps around axons of nerve in a
spiral structure
 Increases the space constant and the conduction velocity of signals traveling down axons
 Decreases membrane capacitance and increases membrane resistance

 Node of Ranvier
▪ Unmyelinated regions between two adjacent myelinated segments of axons in the CNS
and PNS
▪ Contain a large amount of Na+ channels: allows saltatory conduction increases the
velocity of action potentials

 Demyelination:
▪ It's a process in which myelin sheaths of nerves become damaged, which impairs
electrical conduction
▪ Central demyelination occurs within the CNS (e.g., seen with multiple sclerosis,
progressive multifocal leukoencephalopathy, leukodystrophies).
▪ Peripheral demyelination affects the PNS (e.g., seen with Guillain-Barre syndrome).

3
 neurology Introduction to neurology

organization of the nervous system

o Brain, spinal cord

o consists of the nerves and ganglia outside the brain and spinal cord, including the cranial
nerves, spinal nerves, and their roots, peripheral nerves, and neuromuscular junctions.

CENTRAL NERVOUS SYSTEM
 The CNS is formed of 2 parts:

1. intracranial part:
1- Two cerebral hemispheres
They are connected to each other by the corpus callosum.

4
neurology Introduction to neurology

The surface of Each hemisphere is divided into 4 lobes:
✓ Frontal. ✓ Temporal.
✓ Parietal. ✓ Occipital.

Outer gray matter Inner white matter
cerebral cortex depth of the cerebral hemisphere
composed of neural cell bodies &
composed of myelinated axons
unmyelinated axons

It contains certain areas that control it conducts impulses to & from
specific functions. the cerebral cortex.

5
 Neurology Introduction to neurology

2- basal ganglia
 The basal ganglia are a group of nuclei that lie beneath the cortex
 Distributed over the telencephalon, diencephalon, and mesencephalon (midbrain).

 Overview of the basal ganglia

Basal ganglia Location Clinical significance

Caudate nucleus Molecular changes in Huntington disease lead to neuronal loss
Striatum Telencephalon
Putamen in the striatum.

Globus pallidus Wilson disease (hepatolenticular degeneration) leads to an
Lentiform
impaired function of the lentiform nucleus due to copper
nucleus Putamen Diencephalon
accumulation.

Subthalamic nucleus Effect of lesion: contralateral hemiballismus

Parkinson disease is characterized by neuronal degeneration in
Substantia nigra Mesencephalon
the substantia nigra.

6
neurology Introduction to neurology

7
 neurology Introduction to neurology

3- brain stem

part Cranial nerve motor nuclei
Midbrain 3&4
Pons 5, 6, 7
Medulla 9, 10, 11, 12

 NB: The 1, 2 & 8 cranial nerves have no motor nuclei, They are sensory nerves concerned
with special sensation.

8
 neurology Introduction to neurology

4- cerebellum
 It lies at the back & the bottom of the cranium behind the brain stem, in The posterior
cranial fossa.

9
 neurology Introduction to neurology

2. spinal part:

 It lies in the spinal canal.
 It ends at the lower border of the 1st lumbar vertebra (L1).

Cervical 8 segments
Thoracic 12 segments
Lumbar 5 segments
Sacral 5 segments
coccygeal 1 segment
Conus medullaris:
the lowermost 3 segments of the spinal cord (S 3, 4, 5).
Epiconus:
the 4 segments above the conus medullaris (L4, 5, S1, 2).

Spinal
cord


 a collection of lumbo–sacral roots that fills the lower part of spinal canal.
Cauda
 It starts at the lower border of the 1st lumber vertebra (L1).
Equina

10
neurology Introduction to neurology

11
 Neurology Introduction to neurology

THE MOTOR SYSTEM

ORIGIN TERMINATION CONTROL FUNCTIONS

✓ Initiation of the voluntary motor
The Pyramidal in the cerebral
at the AHCs of the it controls the
cortex activity.
System different levels of opposite side of the
(motor area 4 & ✓ inhibition of the deep reflexes.
(UMN): premotor area 6).
the spinal cord body.
✓ inhibition of the muscle tone.
✓ Regulation of the voluntary motor
The Extra at the AHCs of the it controls the activity.
from the
pyramidal different levels of opposite side of the ✓ regulation of the emotional &
basal ganglia.
System the spinal cord. body. associated movements.
✓ inhibition of the muscle tone.
✓ Co-ordination of the voluntary motor
The Cerebellar at the AHCs of the activity initiated by the pyramidal
from the it controls the same
different levels of
System cerebellum.
the spinal cord.
side of the body. system.
✓ maintenance of equilibrium.

The Lower in the AHCs of the components:
at the voluntary ✓ Transmission of the motor impulse from
Motor Neuron different levels of AHCs, PN, NMJ &
muscles. the AHCs to the voluntary muscles.
(LMN) the spinal cord. Voluntary muscles.

20
 Neurology Introduction to neurology

Motor pathway
ORIGIN: the order starts in the Cerebral cortex.
TERMINATION: on the Voluntary muscle which will respond by movement.
From the origin to the termination , the impulse passes through 2 neurons:
✓ Upper Motor Neuron (UMN): Pyramidal tract.
✓ Lower Motor Neuron (LMN): AHCS, Nerves, NMJ, Muscles.

1. Upper motor neuron (UMN)
 Motor area "4" The voluntary motor impulse originates mainly in the large pyramidal cells (Betz cells) of motor area (4) &
"cerebral cortex" to a lesser extent in the cells of the premotor area (6).

The axons of these cells (carrying the impulse) descend in the depth of the Cerebral hemisphere in the
 Internal capsule
Corona radiata to pass in the Internal capsule, and continue their descent in the brain stem.

In the Brain Stem, some of the descending fibers separate to supply the motor nuclei of the cranial nerves
 Corticobulbar of BOTH sides except the lower 1/2 of the facial nucleus and all the hypoglossal nucleus which are supplied
only from the opposite pyramidal tract.
tract "brain stem"
These fibers are known as the corticobulbar tract as they do not reach the spinal cord.
The pathway from the cerebral cortex down to the AHCs in the spinal cord is known as corticospinal tract.
 Corticospinal In the lower medulla:
tract "spinal cord" ✓ 85 % of fibers cross (decussate) to descend in the white matter of the opposite side of the spinal cord.
✓ 15 % of the fibers descend directly in the white matter of the same side of the spinal cord.

21
Neurology Introduction to neurology

22
 neurology Introduction to neurology

2. Lower motor neuron (LMN)

They are special type of nerve cells situated anterior horns of the H-
shaped gray matter of the spinal cord.
 AHCS They receive the voluntary motor impulse from the corticospinal
pyramidal tract.
Their axons exit from the spinal cord as the anterior roots.

 Peripheral
They carry the motor impulse from the AHCs to the voluntary muscles.
motor nerves

 Neuromuscular junction.

 Voluntary muscles.

23
 neurology Introduction to neurology

Muscle Tone
 def: this is a spontaneous local axon stretch reflex.
 mechanism:
the length of any skeletal muscle is shorter than the distance between the origin and the
insertion, So any muscle is always in a state of Persistent spontaneous slight stretch.
spontaneous persistent stretch
↓
persistent activation the local axon reflex
↓
persistent (maintained) contraction of the muscle (tone).

 N.B. The Muscle tone receives inhibition from the Pyramidal & Extrapyramidal systems.
 EFFECT OF umnl & lmnl ON MUSCLE TONE:

loss of inhibition on the muscle tone
UMNL ↓
Increased muscle tone (spasticity) below the level of the lesion.

interruption of the reflex arc
LMNL ↓
Decreased muscle tone (flaccidity) at the level of the lesion.

24
 neurology Introduction to neurology

Deep Reflex (Tendon Jerk)
 def: this is an Induced local axon stretch reflex.
 mechanism:
sudden stretch of the muscle by tapping the tendon with a hammer
↓
activate the local axon reflex (suddenly & temporarily)
↓
sudden transient contraction of the muscle (jerk)

 N.B. The deep reflex receives inhibition from the Pyramidal system.
 EFFECT OF umnl & lmnl ON MUSCLE TONE:

loss of inhibition on the deep reflex
UMNL ↓
Increased deep reflex (hyperreflexia) below the level of the lesion

interruption of the reflex arc
LMNL ↓
Decreased deep reflex (hyporeflexia) at the level of the lesion

25
 neurology Introduction to neurology

Clonus
 Def: Rapid, Rhythmic, Regular contractions that result from Sudden sustained stretch of
the muscle tendon.
 It indicates Severe pyramidal lesion due to: loss of inhibition on the stretch reflex
 It is elicited in: ankle, patella and wrist
 It stops when: the stretch is stopped

26
 neurology Introduction to neurology

How would you clinically differentiate
between UMNL & LMNL??

UMNL LMNL

Paralysis or weakness below the Paralysis or weakness at the level of
Muscle power
level of the lesion. the lesion.

No wasting, & if present it is late Early & marked wasting due to loss
Muscle wasting
and due to disuse atrophy. of muscle tone.

Hypertonia (spasticity) below the Hypotonia (flaccidity) at the level of
Muscle tone
level of the lesion. the lesion.

Deep reflexes Hyperreflexia below the level. Hyporeflexia at the level.
Pathological
May be present. Absent.
deep reflexes
Clonus May be present. Absent.

Superficial Lost if the lesion is above the Lost if the lesion involves the supply
reflexes segmental supply of the reflex. of the reflex.

Positive, i.e. dorsiflexion of the big Plantar flexion of the toes, or, no
toe ± fanning of the other toes response.

Plantar reflex
(Babinski)

May be present in irritative lesion of
Fasciculations Absent
the AHCs.

27
 neurology Introduction to neurology

THE SENSORY SYSTEM
 There are 3 types of sensations in the body:
A. Somatic sensations:

They are conducted to the CNS via the somatic nerves.
They include:

✓ Pain
Superficial sensations ✓ Temperature
✓ Touch

Deep sensations ✓ Vibration sense ✓ Muscle sense
(proprioceptive) ✓ Joint sense ✓ Nerve sense

✓ Tactile localization
✓ Two points discrimination
Cortical sensations
✓ Stereognosis
✓ Graphosthesia

B. Visceral sensations:

They are conducted to the CNS via the "autonomic nerves.
They include all sensations coming from the internal viscera, e.g. heart & intestines.

C. Special sensations:

They are conducted to the CNS via the cranial nerves.
They include: Smell, Vision, Hearing.

Somatic Sensations
All somatic sensations (superficial or deep) pass through 3 order Neurons from receptors in
the skin & deep structures to reach the Cortical sensory area of the opposite side:

1st order neuron Always Dorsal root ganglion (DRG)

2nd order neuron varies according to the type of sensation.

3rd order neuron always in the thalamus of the opposite side

28
 neurology Introduction to neurology

1. Pathways of Superficial Sensations
 Pathway of Pain & Temperature:

1st order neuron is: cell of the dorsal root ganglion (DRG).

1st order The afferent sensory nerve relays in the DRG.
The efferent sensory nerve enters the spinal cord in Lissauer's tract to
neuron
relay in the cells of the Substantia Gelatinosa of Rolandi (SGR), at the
posterior horn of the gray matter

The 2nd order neuron is the cell of SGR & its axon.
2nd order This axon crosses to the OPPOSITE side & ascends in Lateral Spinothalamic
neuron tract of the spinal cord, and then in Lateral Lemniscus of the brain stem, to
relay in the thalamus.

The 3rd order neuron starts in the cell of the thalamus.
3rd order
Its axon ascends to pass through the internal capsule conducting the
neuron
impulse to the cortical sensory area in the parietal lobe.

 Pathway of Touch:

has the same pathway as pain, temperature, BUT:
Crude touch: In the 2nd order neuron: it ascends ventral Spinothalamic tract of the
OPPOSITE side of spinal cord.

Fine touch has the same pathway as deep sensation.

29
 neurology Introduction to neurology

2. Pathway of deep Sensations
1st order neuron is: cell of the dorsal root ganglion (DRG).
The afferent sensory nerve relays in the DRG.
The efferent sensory nerve enters the spinal cord & ascends in Gracile
1st order & Cuneate tracts within the posterior column of the SAME side (along
with fibers carrying fine touch) to relay in Gracile & Cuneate nuclei in
neuron
the medulla:

Gracile Tract carries fibers from Lower ½ of body & lies medially

Cuneate Tract carries fibers from upper ½ of body & lies laterally.

The 2nd order neuron is the cell of gracile & cuneate nuclei & its axon.
2nd order
This axon crosses to the opposite side & ascends in the medial
neuron
lemniscus through the brain stem, to relay in the thalamus.

The 3rd order neuron starts in the cell of the thalamus.
3rd order
Its axon ascends to pass through the internal capsule conducting the
neuron
impulse to the cortical sensory area in the parietal lobe.

3. Pathway of cortical Sensations
These are a mixture of refined superficial &deep sensations arriving to the thalamus via
the 1st & 2nd order neuron conducted from the thalamus to the cortical sensory area
(1,2,3) in the parietal lobe.

30
 neurology Introduction to neurology

Left image: the dorsal column (gracile fasciculus and cuneate fasciculus) carries information of fine touch, vibration,
pressure, and proprioception (gracile fasciculus: primarily from the lower half of the body; cuneate fasciculus: primarily from
the upper half of the body).

Right image: the anterolateral column (anterior spinothalamic tract and lateral spinothalamic tract) carries information of
crude touch, pressure, pain, and temperature.

1) Anterior spinothalamic tract: The first neuron is located within the spinal ganglia. Axons from the first neuron split and
ascend or descend several segments (a). Having reached another segment, they synapse to the second neuron in the posterior
horn of the spinal cord, and the axons decussate to the contralateral side of the spinal cord within the anterior white
commissure (b). Further ascend in the anterior spinothalamic tract (c, d). Synapse to the 3rd neuron in the thalamus (e).

2) Lateral spinothalamic tract: The first neuron is located within the spinal ganglia. Synapse to the 2nd neuron in the gray
matter on the same segment. The axon of the 2nd neuron decussates to the contralateral side of the spinal cord within the
anterior white commissure (a). Ascend in the lateral spinothalamic tract (b, c, d). Synapse to the 3rd neuron in the thalamus
(e). Both pathways end in the somatosensory cortex and transmit information that enters consciousness.

31