BMS2-12 Somatic Senses-Assoc. Prof. Cenk Serhan ÖZVEREL.pdf

Transcript

12/1/22

• Somatic Senses

Somatic Senses

• Touch
• Pressure
• Temperature
• Pain

Assoc. Prof. Dr. Cenk Serhan Özverel

• Special Senses
• Smell
• Taste
• Hearing
• Equilibrium
• vision

[email protected]

Somatic Senses

Classification of Somatic Senses
• 3 physiologic types;

• *Nervous mechanisms that collect sensory information from all over
the body.
• These senses are in contradistinction to the special senses, which
mean specifically vision, hearing, smell, taste, and equilibrium.

• (1) the mechanoreceptive somatic senses, which include both tactile
and position sensations that are stimulated by mechanical
displacement of some tissue of the body;
• (2) the thermoreceptive senses, which detect heat and cold;
• (3) the pain sense, which is activated by factors that damage the
tissues.

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Other Classifications of Somatic Sensations.
• Exteroreceptive sensations à FROM OUTSİDE OF THE BODY
• Proprioceptive sensations à relating to the physical state of the
body, including position sensations, tendon and muscle sensations,
pressure sensations from the bottom of the fee
• Visceral sensations à From viscera of body
• Deep sensations à Deep tissues

Tactile Receptors.
• At least 6 types
• Some of them are free nerve endings à pressure and touch
• Meisner’s corpuscle à Great sensitivity touch receptor. An
elongated encapsulated nerve ending of a large (type A ) myelinated
sensory nerve fiber.
• nonhairy parts of the skin
• Fingertips
• Lips

Detection and Transmission of Tactile Sensations
• Interrelations Among the Tactile Sensations of Touch, Pressure, and
Vibration.
• All detected by the same types of receptors.
• 3 principal differences among them:
• (1) Touch sensation generally results from stimulation of tactile receptors in
the skin or in tissues immediately beneath the skin;
• (2) Pressure sensation generally results from deformation of deeper tissues;
and
• (3) Vibration sensation results from rapidly repetitive sensory signals, but
some of the same types of receptors as those for touch and pressure are
used.

• Meissner’s corpuscles with expanded tip tactile receptors, à
Merkel’s discs
• hairy parts of the skin

• hair end-organ à slight movement of any hair on the body
stimulates a nerve fiber entwining its base
• Detects mainly
• (a) movement of objects on the surface of the body
• (b) initial contact with the body.

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• Different type of somatic sensory nerve endings

• Ruffini’s endings, à multibranched, encapsulated endings
• signaling continuous states of deformation of the tissues, such as heavy
prolonged touch and pressure signals.

• Pacinian corpuscles à immediately beneath the skin and deep in the
fascial tissues of the body

Transmission of Tactile Signals in Peripheral Nerve
Fibers.
• Almost all specialized sensory receptors (Meissner’s corpuscles, Iggo dome
receptors, hair receptors, pacinian corpuscles, and Ruffini’s endings )à via
A-beta nerve fibers.
• Velocity à 30 to 70 m/sec.
• Free nerve ending à via Delta-A myleinated fibers.
• Velocity à 5-30 m/sec

Detection of Vibration
• All tactile receptors can detect.
• Pacinian corpuscles à can detect up to 30 to 800 cycles per second
à transmit their signals over type A-beta nerve
fibers,
à1000 impulses per second

• Some tactile nerve endings transmit à via Type C unmyelinated fibers.
• Velocity à 2 m/sec

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Sensory Pathways for Transmitting Somatic
Signals into the Central Nervous System
• Almost all sensory information from the somatic segments of the
body enters the spinal cord through the dorsal roots of the spinal
nerves.
• However, from the entry point into the cord and then to the brain,
the sensory signals are carried through one of two alternative sensory
pathways:
• (1) the dorsal column–medial lemniscal system
• (2) the anterolateral system.

Differences

• Dorsal column–medial lemniscal system à large, myelinated nerve
fibers that transmit signals to the brain at velocities of 30 to 110
m/sec,
• whereas the anterolateral system à smaller myelinated fibers that
transmit signals at velocities ranging from a few meters per second up
to 40 m/sec.

• These two systems come back together in the level of thalamus.
• The dorsal column–medial lemniscal system à carries signals
upward to the medulla of the brain mainly in the dorsal columns of
the cord àThen, after the signals synapse and cross to the opposite
side in the medulla, they continue upward through the brain stem to
the thalamus by way of the medial lemniscus.
• Conversely, signals in the anterolateral system, immediately after
entering the spinal cord from the dorsal spinal nerve roots, synapse in
the dorsal horns of the spinal gray matter, then cross to the opposite
side of the cord and ascend through the anterior and lateral white
columns of the cord. They terminate at all l evels of the lower brain
stem and in the thalamus.

• Types of sensations transmitted by two systems:
• Dorsal Column—Medial Lemniscal System

• 1. Touch sensations requiring a high degree of localization of the stimulus
• 2. Touch sensations requiring transmission of fine gradations of intensity
• 3. Phasic sensations, such as vibratory sensations
• 4. Sensations that signal movement against the skin
• 5. Position sensations from the joints
• 6. Pressure sensations related to fine degrees of judgment of pressure
intensity

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• Types of sensations transmitted by two systems:
• Anterolateral System

1. Pain
2. Thermal sensations, including both warmth and cold sensations
3. Crude touch and pressure sensations capable only of crude localizing ability
on the surface of the body
4. Tickle and itch sensations
5. Sexual sensations

• Projection of the dorsal column–medial lemniscal system through the
thalamus to the somatosensory cortex.

Transmission in the Dorsal
Column–Medial Lemniscal System
• Anatomy of the Dorsal Column–Medial Lemniscal
System

• The dorsal column–medial lemniscal pathway for
transmitting critical types of tactile signals.

Somatosensory Cortex
• 50 distinct areas called Brodmann’s areas based on histological
structural differences.

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• Two somatosensory cortical areas

Layers of the Somatosensory Cortex and Their
Function
• 6 layers of neurons
• 1. The incoming sensory signal excites neuronal layer IV first; then
the signal spreads toward the surface of the cortex and also toward
deeper layers.

• Representation of the different areas of the body in somatosensory
area I of the cortex

• 3. The neurons in layers II and III send axons to related portions of
the cerebral cortex on the opposite side of the brain through the
corpus callosum.
• 4. The neurons in layers V and VI send axons to the deeper parts of
the nervous system.
• Và basal ganglia, brain stem, and spinal cord
• VIà thalamus

• 2. Layers I and II receive diffuse, nonspecific input signals from lower
brain centers that facilitate specific regions of the cortex

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Overall Characteristics of Signal Transmission and
Analysis in the Dorsal Column–Medial Lemniscal
System
• Basic Neuronal Circuit in the Dorsal Column– Medial Lemniscal
System.

Transmission of Less Critical Sensory Signals in
the Anterolateral Pathway
• Include pain, heat, cold, crude tactile, tickle, itch, and sexual
sensations.
• Do not require highly discrete localization
• Do not require discrimination of fine gradations of intensity.

Characteristics of Transmission in the
Anterolateral Pathway.
• Anterior and lateral divisions of the
anterolateral sensory pathway.

• (1) the velocities of transmission are only one-third to one-half those in
the dorsal column–medial lemniscal system, ranging between 8 and 40
m/sec;
• (2) The degree of spatial localization of signals is poor;
• (3) The gradations of intensities are also far less accurate, most of the
sensations being recognized in 10 to 20 gradations of strength, rather than
as many as 100 gradations for the dorsal column system;
• (4) The ability to transmit rapidly changing or rapidly repetitive signals is
poor.

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Pain
• Protective mechanism

• Slow pain àlow burning pain, aching pain, throbbing pain, nauseous pain,
and chronic pain.

• 2 major types

• Fast pain 0.1 sec
• Slow pain
1 sec

• Fast pain à sharp pain, pricking pain, acute pain, and electric pain
•
à Ex: needle is stuck into the skin, when the skin is cut with a knife,
or when the skin is acutely burned.

Pain Receptors and Their Stimulation

Dual Pathways for Transmission of Pain
Signals into the Central Nervous System

• Free Nerve Endings
• Three Types of Stimuli Excite Pain Receptors— Mechanical, Thermal,
and Chemical.

• a fast- sharp pain pathway
• a slow-chronic pain pathway.

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• Peripheral Pain Fibers—“Fast” and “Slow” Fibers.
• Fast sharp painà Elicited by either mechanical or thermal pain
stimuli;
• Transmitted in the peripheral nerves to the spinal cord by small type
A-delta fibers at velocities between 6 and 30m/sec
• Conversely, the slow-chronic type of pain is elicited mostly by
chemical types of pain stimuli but sometimes by persisting
mechanical or thermal stimuli. This slow-chronic pain is transmitted
to the spinal cord by type C fibers at velocities bet ween 0.5 and 2
m/sec.

Pain Suppression (“Analgesia”) System in the
Brain and Spinal Cord
• The degree to which a person reacts to pain varies tremendously
• capability of the brain itself to suppress input of pain signals to the
nervous system by activating a pain control system, called an
analgesia system.

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Referred Pain

Headache

• Often a person feels pain in a part of the body that is fairly remote
from the tissue causing the pain. This is called referred pain.

• Headaches are a type of pain referred to the surface of the head from
deep head structures.
• Some headaches result from pain stimuli arising inside the cranium,
but others result from pain arising outside the cranium, such as from
the nasal sinuses.

• Areas of headache resultıng from different causes

Types of Intracranial Headache
• Headache of Meningitis.
• One of the most severe headaches
• Causes inflammation of all the meninges, including the sensitive areas
of the dura and the sensitive areas around the venous sinuses. Such
intense damage can cause extreme headache pain referred over the
entire head.

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• Headache Caused by Low Cerebrospinal Fluid Pressure.

• Migraine Headache.

• Removing as little as 20 milliliters of fluid from the spinal canal,
particularly if the person remains in an upright position, often causes
intense intracranial headache.

• May result from abnormal vascular phenomena, although the exact
mechanism is unknown.
• Alcoholic Headache..
• toxic to tissues,
• dehydration

Extracranial Types of Headache
• Headache Resulting from Muscle Spasm.
• Emotional tension often causes many of the muscles of the head,
especially those muscles attached to the scalp and the neck muscles
attached to the occiput, to become spastic, and it is postulated that
this is one of the common causes of headache.

• Headache Caused by Eye Disorders

• Difficulty in focusing one’s eyes clearly may cause excessive
contraction of the eye ciliary muscles in an attempt to gain clear
vision. Even though these muscles are extremely small, it is believed
that tonic contraction of them can cause retro-orbital headache.

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Thermal Sensations
• The human being can perceive different gradations of cold and heat,
from freezing cold to cold to cool to indifferent to warm to hot to
burning hot.
• Thermal gradations are discriminated by at least three types of
sensory receptors:
• Cold receptors,
• warmth receptors,
• pain receptors.

The end

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