Lecture 5. Neurophysiology .pdf

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Neurophysiology
Introduction

Our Topics
• Organization of the Nervous System
• Spinal Cord
• Brain stem

• Cerebellum
• Different parts of Brain
• Cells of the Nervous System

• General Features of Sensory Systems

The Nervous System
A complex network that allows to
communicate with its environment.
• Sensory components (afferent), which
detect changes in environmental stimuli,
• Integrative components, receive, store,
and process sensory information and then
orchestrate the appropriate motor
responses.
• Motor components (efferent), which
generate movement, contraction of
cardiac and smooth muscle, and glandular
secretions.
ORGANIZATION OF THE NERVOUS SYSTEM

Central Nervous System (CNS)
• The CNS includes the brain and spinal cord.

Fig. 3.1 Midsagittal section of the brain. Relationships are shown between the lobes of the cerebral cortex, the cerebellum,
the thalamus and hypothalamus, the brain stem, and the spinal cord.

Spinal Cord
• The spinal cord is segmented,
with 31 pairs of spinal nerves
that contain both sensory
(afferent) nerves and motor
(efferent) nerves.
• Sensory nerves carry
information to the spinal cord
from the skin, joints, muscles,
and visceral organs in the
periphery via dorsal root.
• Efferent nerves carry
information from the spinal cord
to the periphery include both
somatic motor nerves and
autonomic nerves.

Descending and ascending pathways in the
spinal cord
It is related to
• Somatic motor functions,
• Visceral functions
• Reflexes
• Somatosensory functions
(touch, proprioception),
temperature,noxious
stimuli senses)

Brain Stem
• The medulla, pons, and midbrain
are collectively called the brain
stem.

• Medulla: It contains
autonomic centers that regulate
• Breathing,

• Blood pressure,
• Cardioregulatory and
• Swallowing, Coughing, Vomiting
reflexes

Pons
• Together with centers in the
medulla, participates in balance
and maintenance of posture
• Some of breathing center
located in here.
• In addition, the pons relays
information from the cerebral
hemispheres to the cerebellum
• The pontine micturition center
is the exit site for impulses
going to the bladder.
• Superior olive complex, part of
the auditory pathway, located
in here

Midbrain
• It participates in control of eye
movements and eye reflexes.
• It also contains nuclei of the
auditory and visual systems.

Clinical box
• Auditory
midbrain implant
(AMI) is using to
stimulate the
inferior colliculus
in deaf patients
who cannot
benefit
sufficiently from
cochlear
implants.

The brain auditory pathway

Cerebellum
Integrates;
• Sensory information about position from the
spinal cord,
• Motor information from the cerebral cortex,
• Balance information from the vestibular
organs of the inner ear.
The functions;
• Coordination of movement, planning and
execution of movement,
• Maintenance of posture,
• Coordination of head and eye movements.

Thalamus
• The thalamus processes almost
all sensory information going to
the cerebral cortex (except
smell) .

• Almost all motor information
coming from the cerebral
cortex to the brain stem and
spinal cord via thalamus.

Hypothalamus
The hypothalamus lies ventral to
the thalamus and contains centers
that regulate ;
• Body temperature,
• Food intake,
• Water balance
• The hypothalamus is also an
endocrine gland that controls the
hormone secretions of the
pituitary gland.

The hypothalamus secretes releasing and release-inhibiting
hormones into hypophysial portal blood that cause release
(or inhibition of release) of the anterior pituitary hormones.
The hypothalamus also contains neurons that secrete
antidiuretic hormone (ADH) and oxytocin.

Cerebral Hemispheres
The cerebral hemispheres consist of ;
• The cerebral cortex,
• Underlying white matter,
• Deep nuclei such as Basal ganglia
and Limbic system).
The main functions of the cerebral
hemispheres are;
• Perception,
• Higher motor functions,
• Cognition,
• Memory, and
• Emotion

Cerebral
cortex
• It consist
of 4 lobe;
Frontal,
Parieal,
Temporal,
Occipital

Basal ganglia
• It receive input from all lobes of
the cerebral cortex and send
projections, via the thalamus, to
the motor cortex to assist in
regulating movement.
• It have an inhibitory effect on
many motor systems.

Hippocampus, and amygdala
• They are part of the limbic
system.
• The hippocampus is involved
in memory;
• The amygdala is involved with
the emotions and
communicates with the
autonomic nervous system via
the hypothalamus

• The amygdala determines
emotional responses to odors.
• It is the main center of creation
of emotions such as excitement,
anxiety and pleasure due to
scents.

CELLS OF THE NERVOUS SYSTEM

Nature volume 457, pages675–677 (2009)

Dendrites; are tapering processes that
arise from the cell body. They receive
information and contain receptors
for neurotransmitters.
Axons; each neuron has a single axon,
which can be quite long.
Axon contains of microtubules
that rapidly move materials between the
cell body and the axon terminus.

SENSORY SYSTEMS

SENSORY SYSTEMS
Sensory Pathways
• Sensory systems receive
information from the
environment via specialized
receptors in the periphery and
transmit this information
through a series of neurons and
synaptic relays to the CNS.

Synapses are made in relay nuclei between first- and second, second- and third,
and third- and fourth-order neurons. Second-order neurons cross the midline
either in the spinal cord (shown) or in the brain stem (not shown) so that
information from one side of the body is transmitted to the contralateral thalamus
and cerebral cortex.

1. Sensory receptors
Different sensory modalities are
detected by various receptors
• In the visual, taste, and auditory
systems; the receptors are
specialized epithelial cells
• In the somatosensory and
olfactory systems; the receptors
are also first-order, or primary
afferent, neurons

Sensory Transduction
• The basic function of the
receptors is the same: to
convert a stimulus (e.g., sound
waves, electromagnetic waves,
or pressure) into
electrochemical energy.
• The conversion process, called
sensory transduction, is
mediated through the receptor
potential.

Receptor Potential
• The receptor potential
increases or decreases
the probability an
action potential will
occur, depending on
whether it is
depolarizing or
hyperpolarizing
• They are graded
electronic potentials,
whose amplitude
correlates with the size
of the stimulus.

Types of Receptors
• Mechanoreceptors are
activated by pressure or
changes in pressure.
• The pacinian corpuscles in
subcutaneous tissue,
• Meissner corpuscles in
nonhairy skin (touch),
• Baroreceptors in the carotid
sinus (blood pressure),
• Hair cells on the organ of Corti
(audition) and in the
Semicircular canals (vestibular
system).

Types of Receptors
• Photoreceptors are activated by light
and are involved in vision.
• Chemoreceptors are activated by
chemicals and are involved in olfaction,
taste, and detection of oxygen and
carbon dioxide in the control of
breathing.
• Thermoreceptors are activated by
temperature or changes in temperature.
• Nociceptors are activated by extreme
stimulus of pressure, temperature, or
noxious chemicals.

2. First-order sensory afferent neurons
• The primary afferent
neuron usually has its
cell body in a dorsal
root or spinal cord
ganglion. Exceptions are
the auditory, olfactory,
and visual systems.
(In these system the
receptors are specialized
epithelial cells)

3. Second-order sensory
afferent neurons
• First-order neurons synapse on
second-order neurons in relay
nuclei, which are located in the
spinal cord or in the brain
stem.
• Interneurons, also located in
the relay nuclei, may be
excitatory or inhibitory.
• These interneurons process
and modify the sensory
information received from the
first-order neurons.

4. Third-order sensory afferent neurons.
• Third-order neurons typically reside
in relay nuclei in the thalamus.
• Again, many second-order neurons
synapse on a single third-order
neuron.
• The relay nuclei process the
information they receive via local
interneurons, which may be
excitatory or inhibitory.

4. Fourth-order sensory afferent neurons.
• Fourth order neurons reside in the
appropriate sensory area of the cerebral
cortex.
• For example, in the auditory pathway,
fourth-order neurons are found in the
primary auditory cortex;
• in the visual pathway, they reside in the
primary visual cortex; and so forth.
• There are secondary and tertiary areas, as
well as association areas in the cortex, all
of which integrate complex sensory
information.

The receptive field
• The receptive field is the area of the body that
changes the firing rate of a sensory neuron when
stimulated.
• If the sensory neuron's firing rate increases, the
receptive field is excitatory.
• If the sensory neuron's firing rate decreases, the
receptive field is inhibitory.
• The smaller receptive field, more precisely
sensation can be localized or identified.
• In higher order neurons, the receptive field
becomes more complex because more neurons
converge in the relay nucleus in the higher orders.

Sensory Coding
Stimulus intensity is encoded in three ways.
1. The number of receptors that are activated.
2. The differences in firing rates of sensory neurons in the pathway.
3. Activating different types of receptors; a light
touch of the skin may activate only mechanoreceptors, whereas an intense
damaging stimulus to the skin may activate mechanoreceptors and
nociceptors.

What happens if a receptor receives stimulation
that continues with the same intensity?
Adaptation

• Depending on the duration of stimulation and the type of receptor, its ability to
generate an impulse gradually decreases and eventually it cannot generate an impulse.
• This phenomenon is called adaptation of the receptor. For example; When a prosthesis
is placed on a person, the presence of foreign matter in the body becomes increasingly
unnoticeable.
• Receptors are divided into two groups according to their adaptation rate.

• Some of the
mechanoreceptors are phasic,
they are only when the
stimulus intensity changes, so
they cannot emit a continuous
signal.Pacinian corpuscles,
which detect rapid changes in
the stimulus or vibrations.
• Photoreceptors,
chemoreceptors,
thermoreceptors, pain
receptors and some of
mechanoreceptors are tonic
so continue to send impulses
to the brain as long as the
stimulus is present.

• Thanks for your attention…
• Next week we will continue with the topic Somatosensory System and
Pain (Page 80).