Neurophysiology PDF

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This document is a lecture on neurophysiology, covering topics such as the nervous system, types of nerve fibers, synapses, and factors affecting synaptic transmission. The materials are presented in a structured format with diagrams and tables.

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Neurophysiology
Dr. Adel Hussien
Prof. of Medical Physiology
Physiology dept.-Faculty of
Medicine – Minia University
 Introduction to physiology of CNS
Learning objectives:
By the end of this lecture student will be able to
1- Illustrate the functional classification of the nervous
system
2- Describe types of nerve fibers and properties of each one
3- Discuss what is synapse, its types, mechanism of
synaptic transmission and synaptic potential
4- Discuss properties of synaptic transmission and factors
affecting it
5- Know some examples for chemical transmitters at
synapses
 Introduction to physiology of CNS

Nervous system controls all the activities of the body.
It is quicker than other control system in the body, (
quicker than endocrine system).
Nervous system is divided into two parts:
1. Central nervous system

2. Peripheral nervous system
 1- CENTRAL NERVOUS SYSTEM
Central nervous system (CNS) includes brain and spinal
cord.
It is formed by neurons and supporting cells called neuroglia
Structures of brain and spinal cord are arranged into two
layers, namely gray matter and white matter.
Gray matter is formed by nerve cell bodies and
the proximal parts of nerve fibers, arising from nerve
cell body.
White matter is formed by remaining parts of
nerve fibers
N.B. In brain, white matter is placed in the inner part and gray
matter is placed in the outer part. In spinal cord, white
matter is in the outer part and gray matter is in the inner part.
Brain is situated in the skull. It is continued as spinal cord in the
vertebral canal through the foramen magnum of the skull bone.
Brain and spinal cord are surrounded by three layers of meninges called
the
1- Outer dura mater,
2- Middle arachnoid mater and
3- Inner pia mater.

The space between arachnoid mater and pia mater is known as
subarachnoid space.
This space is filled with a fluid called cerebrospinal fluid.
Brain and spinal cord are actually suspended in the cerebrospinal fluid.
 General structure of the CNS
Brain includes:
- Cerebrum
- Cerebellum
- Midbrain
- Pons
- Medulla oblongata
Spinal Cord includes:
- Cervical part
- Thoracic part
- lumbar part
- Sacral part
- Coccygeal part
 2- PERIPHERAL NERVOUS SYSTEM

Peripheral nervous system (PNS) is formed by neurons and their
processes that arises from CNS and supplies all regions of the body.
It consists of cranial nerves, arising from brain and spinal nerves,
arising from the spinal cord.

It is divided into two subdivisions:

A. Somatic nervous system

B. Autonomic nervous system
A. Somatic Nervous System
Somatic nervous system is concerned with somatic functions.
It includes the nerves supplying the skeletal muscles.
Somatic nervous system is responsible for muscular activities and
movements of the body

B. Autonomic Nervous System
Autonomic nervous system is concerned with regulation of visceral
functions. So, it is called involuntary nervous system.
Autonomic nervous system consists of two divisions,
sympathetic division and parasympathetic division.
The unit of structure and function of the nervous system is the neuron

Neuron is similar to any other cell in the body, having nucleus and all the
organelles in cytoplasm. However, it is different from
other cells by two ways:
1. Neuron has branches or processes called axon and dendrites
2. Neuron does not have centrosome. So, it cannot undergo division.
N.B. Dendrite transmits impulses towards the nerve cell body. Usually,
the dendrite is shorter than axon.

Axon transmits impulses away from the nerve cell body.
Dendrites and axons are usually called nerve fibers.
On the basis of function, nerve cells are classified into
two types:

1. Motor or efferent neurons
neurons which carry the motor impulses from central nervous system to
peripheral effector organs like muscles, glands, blood vessels, etc.
Generally, each motor neuron has a long axon and short dendrites.

2. Sensory or afferent neurons.
neurons which carry the sensory impulses from periphery to central
nervous system. Generally, each sensory neuron has a short axon and
long dendrites.
 Classification of Nerve Fibers
1. DEPENDING UPON STRUCTURE
Based on structure, nerve fibers are classified into two types:
i. Myelinated Nerve Fibers
Myelinated nerve fibers are the nerve fibers that are covered by myelin
sheath.
ii. Non-myelinated Nerve Fibers
Nonmyelinated nerve fibers are the nerve fibers which are not covered
by myelin sheath.
2. DEPENDING UPON DISTRIBUTION
Nerve fibers are classified into two types, on the basis of distribution:
i. Somatic Nerve Fibers
Somatic nerve fibers supply the skeletal muscles of the body.
ii. Visceral or Autonomic Nerve Fibers
Autonomic nerve fibers supply the various internal organs of the body.
3. DEPENDING UPON ORIGIN
On the basis of origin, nerve fibers are divided into two types:
i. Cranial Nerve Fibers
Nerve fibers arising from brain are called cranial nerve fibers.
ii. Spinal Nerve Fibers
Nerve fibers arising from spinal cord are called spinal nerve fibers.
4. DEPENDING UPON FUNCTION
Functionally, nerve fibers are classified into two types:
i. Sensory Nerve Fibers
Sensory nerve fibers carry sensory impulses from different parts of the
body to the central nervous system.
These nerve fibers are also known as afferent nerve fibers.
ii. Motor Nerve Fibers
Motor nerve fibers carry motor impulses from central nervous system to
different parts of the body.
These nerve fibers are also called efferent nerve fibers.
5. DEPENDING UPON SECRETION OF NEUROTRANSMITTER
Depending upon the neurotransmitter substance secreted, nerve fibers are
divided into different types:
i. Adrenergic Nerve Fibers
Adrenergic nerve fibers secrete noradrenaline.
ii. Cholinergic Nerve Fibers
Cholinergic nerve fibers secrete acetylcholine.
6. DEPENDING UPON DIAMETER AND CONDUCTION OF
IMPULSE
On the basis of diameter (thickness) of the fibers and velocity of
conduction of impulses:
i. Type A nerve fibers
ii. Type B nerve fibers
iii. Type C nerve fibers.
Velocity of impulse through a nerve fiber is directly proportional to the
thickness of the fiber.
Type A nerve fibers are the thickest fibers and type C nerve fibers
are the thinnest fibers. Except type C fibers, all the nerve fibers
are myelinated.
Type A nerve fibers are divided into four types: alpha, beta,
gamma, and delta

Type Diameter (μ) Velocity of conduction
(meter/second)

Aα alpha 12 to 24 70 to 120
Aᵦ beta 6 to 12 30 to 70
Aγ gamma 5 to 6 15 to 30
Aδ delta 2 to 5 12 to 15
B 1 to 2 3 to 10
C < 1.5 0.5 to 2
 Synapse
Site where axon of one neuron terminates on dendrites, soma (cell body)
or axon of another neuron.
Notice that:
- Synapse is a place of contact (no continuity) between presynaptic and
postsynaptic neurons
- A small space separate the pre and postsynaptic neurons called the
synaptic cleft in which a chemical transmitter is released
Functional anatomy (structure) of synapse:
1- Terminal knobs
- Mitochondria
- Vesicles
- Attachment proteins
(V SNARE - T SNARE)

2- Synaptic cleft: 30-50nm
ECF: rich Na-Cl-Ca poor K
3- Postsynaptic membrane
Receptors
- Ionotropic: ligand gated channels
- Metabotropic: G protein coupled Receptors
 Types of synapses
According to site of contact:
1- Axo-dendritic
2- Axo-somatic
3- Axo-axonic

According to mode of transmission:
1- Electrical synapse: rare
contain gap junctions

2- Chemical synapse: common
use chemical transmitter
 Mechanism of synaptic transmission

1- Arrival of nerve impulse
2- Opening of Ca2+ channels
3- Release of chemical transmitter
4- Crossing synaptic cleft
5- Binding to receptor
6- Change postsynaptic
Membrane permeability
7- Development of post-synaptic
potential
8- Removal of the transmitter
 Postsynaptic potentials (PSP)
Definition: Local state of change in the postsynaptic membrane
potential

Types of postsynaptic potentials:

1- Excitatory postsynaptic potential (EPSP)

2- Inhibitory postsynaptic potential (IPSP)

3- Grand postsynaptic potential
1- Excitatory postsynaptic potential (EPSP)
Local state of partial depolarization at the postsynaptic membrane
Cause: binding of excitatory transmitter with its receptor….opening of
Na+ channels…..Na+ influx….partial depolarization
EPSPs can be summated* and reach threshold value and produce
propagated action potential
*types of summation
a. Spatial summation
Simultaneous stimulation of several
Presynaptic neurons on postsynaptic
membrane
b. Temporal summation
Multiple stimulations by one
Presynaptic neuron on postsynaptic
membrane
2- Inhibitory postsynaptic potential (IPSP)
Local state of partial hyperpolarization at the postsynaptic membrane
Cause: binding of inhibitory transmitter with its receptor….opening of
Cl &K channels or closure of Na+ and Ca2+ channels….partial
hyperepolarization

IPSPs can be summated by both types of summation
- Spatial summation
- Temporal summation
 Modulation of presynaptic potential
Occurs by a 3rd neuron terminates on the presynaptic neuron and may
lead to
1- Presynaptic inhibition
rd 3rd neuron Presynaptic neuron
If the 3 neuron is inhibitory..inhibitory
transmitter
Close Ca or Na channels or open K channels..
Decrease Ca entery..inhibition of release
of the chemical transmitter
2- Presynaptic facilitation
If the 3rd neuron is excitatory..excitatory transmitter
Increase cAMP…phosphorylate K channels.. Postsynaptic neuron

Close K channels…prolong depolarization..prolong opening of Ca
channels…Increase release of the chemical transmitter
 Mechanisms of synaptic inhibition
A- Direct postsynaptic inhibition Inhibitory presynaptic neuron

When inhibitory presynaptic neuron
relies directly on postsynaptic membranes

Postsynaptic neuron inhibited
B- Indirect presynaptic inhibition
excitatory presynaptic neuron
3rd inhibitory neuron

When inhibitory third neuron rely on
excitatory presynaptic nreuron

Postsynaptic neuron inhibited
 Properties (characters) of synaptic transmission

1- Forward direction (one way conduction):
only from presynaptic neuron to postsynaptic neuron not the reverse
2- synaptic delay:
0.5 msec delay representing the time needed for synaptic transmission
Number of synapses in reflex pathway = time of central delay / 0.5
3- Synaptic fatigue:
decrease rate of discharge at the postsynaptic neuron due to rapid
repetitive stimulation of the presynaptic neuron (decrease or block of
impulse transmission at the synapses)
Cause: a- exhaustion of synaptic vesicles
b- inactivation of postsynaptic receptors
Clinical value: prevent overexcitation in the CNS (in epileptic fits)
4- Synaptic plasticity:
Ability to change the function of synapse according to the demand
Synaptic transmission can be increased or decreased for short or long
duration
(1) Short term plasticity
a) Short term inhibition (habituation):
Gradual loss of response to a benign (habituated) stimulus when it is
repeated for several times at intervals
Cause: gradual inactivation of Ca channels…decrease intracellular
Ca….decrease release of the chemical transmitter from the presynaptic
neuron
b) Short term facilitation
- Post tetanic potentiation: brief rapid tetanizing stimuli…potsynaptic
discharge for few seconds to mins after stoppage of stimulation
Cause: repeated stimuli..increase intracelluar Ca…continuous releae of
the chemical transmitter (immediate memory)
- Sensitization: augmented response in the post synaptic neuron due to
application of a noxious stimulus with a benign stimulus to the
presynaptic neuron (short term memory)
- Cause : presynaptic facilitation
(2) Long term plasticity
(a) Long term potentiation: prolonged stimulation of postsynaptic
neuron due to repeated presynaptic stimulation, lasts for days or
weeks
Mechanism: occurs specifically in the hippocampus and responsible for
long term memory
Presynaptic stimulation…glutamalte…AMPA-NMDA
receptors….increase Na influx…..depolarization of postsynaptic neuron
(more than 20mV)….activation of NMDA receptors…increase Ca
entry…Ca-calmodulin complex….activate kinase enzymes….
- Activation of AMPA receptors…more Na influx
- Recruitment of more AMPA receptors into the postsynaptic membrane
- Release of certain chemical signals (arachidonic acid and NO gas)
from the postsynaptic neuron to act on the presynaptic neuron ….more
increase of glutamate
N.B. α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)
and N-methyl-D-aspartate (NMDA), respectively.
(b) Long term depression: prolonged depression of postsynaptic
neuron due to repeated presynaptic stimulation
- The postsynaptic membrane is depolarized to less than 20 mV so
NMDA receptors continuously closed and Ca influx does not occur
- Important for coordination (cerebellum)
 Factors affecting synaptic transmission

(A)Internal environmental changes
1- H+ ion concentration( pH of blood): synaptic transmission is very
sensitive to pH changes
Alkalosis: increase synaptic transmission
Cause: hyperventilation…may lead to convulsions
Acidosis: decrease synaptic transmission
Cause: diabetes mellitus….increase ketone bodies may lead to coma

2- Hypoxia: decrease synaptic transmission
Hypoxia for 3-5 sec….coma
Prolonged hypoxia…..brain damage
3- Hypoglycaemia: decrease synaptic transmission (glucose is the
main fuel for the nervous system)

4- Hormones: may facilitate or inhibit synaptic transmission

5- Electrolytes: decrease extracellular Ca2+ concentration…increase
excitability of post synaptic neuron and synaptic transmission…tetany
(B) Drugs
1- Drugs increase synaptic transmission
- Theophilline, theobromine, caffeine act by increasing depolarization
of postsynaptic membrane
- Strychnine inhibit the effect of GABA (inhibitory
transmitter)….more excitatory pathways…increase synaptic
transmission….may lead to convulsions, muscle spam and death
2- Drugs decrease synaptic transmission
Analgesics, anesthetics and hypnotics…due to hyperpolarization and
decrease synthesis and release of the transmitter
(C) Diseases
Tetanus: neurotoxin prevent release of GABA…severe muscle Spasm
(spastic paralysis) start in jaw muscles then respiratory muscles..death

Botulism: botulinium toxin may present in canned food...blocks the
release of Ach….flaccid paralysis
 Chemical transmitters

(1) Small molecules (rapidly acting transmitters)

- Responsible for acute rapid responses of the nervous system
- Examples include
Acetylecholine
Amines like norepinephrine , dopamine, serotonin, histamine
Amino acids, excitatory as glutamate and aspartate and inhibitory as
GABA and glycine
(2) Large molecules (slowly acting neuropeptides)
- Highly potent and more prolonged action than small molecules
transmitters
Types:
- Hypothalamic: releasing peptides TRH CRH
- Pituitary: GH, TSH, ADH
- Opioid peptides: endorphins. Enkephalins
- GIT peptides: gastrin, CCK, secretin
- Others: substance p, neuropeptide Y, angiotensinII , ANP
Which of the following is difference between IPSP and EPSP?
a. Being of shorter duration
b. Being unable to summate spatially
c. Moving the membrane potential away from threshold
d. Depending upon opening of voltage K + channels
Which of the following is not inhibitory for synaptic transmission?
a. Oxygen lack
b. Alkalosis
c. Acidosis
d. Prolonged activity of synapse
Enumerate 3 properties (characters) for synaptic transmission:
1-………………………………………………………
2-……………………………………………………….
3-……………………………………………………….