BMS2-11 Sensory Receptors-Assoc. Prof. Cenk Serhan ÖZVEREL .pdf

Full Transcript

12/1/22

Sensory Receptors
Sensory Receptors
Assoc. Prof. Dr. Cenk Serhan Özverel
[email protected]

• Imput to nervous system
• Detect sensory stimuli
– touch,
– sound,
– light,
– pain,
– cold,
– warmth.

Types of Sensory Receptors
and the Stimuli They Detect

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• (1) mechanoreceptors, which detect mechanical
compression or stretching of the receptor or of tissues
adjacent to the receptor;

• (4) electromagnetic receptors, which detect light on the
retina of the eye;

• (2) thermoreceptors, which detect changes in temperature,
with some receptors detecting cold and others warmth;
• (3) nociceptors (pain receptors), which detect damage
occurring in the tissues, whether physical damage or
chemical damage;

Differential Sensitivity of Receptors
• How do two types of sensory receptors detect
different types of sensory stimuli?

• (5) chemoreceptors, which detect taste in the mouth, smell
in the nose, oxygen level in the arterial blood, osmolality of
the body fluids, carbon dioxide concentration, and other
factors that make up the chemistry of the body.

• Example:
• Rods and cones à light
• Osmoreceptors à osmolality of the body fluids

• Each type of receptor is highly sensitive to
one type of stimulus for which it is designed

• Pain receptors à NEVER by touch or pressure
stimuli, BUT à severe

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Modality of Sensation—The “Labeled
Line” Principle
• Example:

• Receptor 1
• Receptor 2

Nerves

Determined by the point it leads

• If a p ain fiber is stimulated, the person perceiv es pain
regardless of what type of stimulus excites the fiber. Th e
stimulus can be electricity, overheating of the fiber, crushing
of the fiber, or stimulation of the pain nerve ending by
damage to thetissue cells.

• Receptor 3

• Example:

• Example:

• if a touch fiber is stimulated by el ectrical excitation of a touch
receptor or in any other way, th e person perceiv es touch
because touch fibers lead to specific touch areas in the brain.

• Similarly, fibers from th e retina of the ey e t erminate in th e
vision areas of the brain, fibers from the ear terminate in the
auditory areas of the brain, and temperature fibers t erminat e
in the temperature areas.

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Transduction of Sensory Stimuli
into Nerve Impulses
• This specificity of nerve fibers for transmitting only
one modality of sensation is called the labeled line
principle.

• Local Electrical Currents at Nerve Endings—
Receptor Potentials
• All sensory receptors have one feature in common
• Whatever th e type of stimulus that excites the receptor, its
immediate effect is to change the membrane electrical
potential of the receptor.
• This change in potential is called a receptor potential.

Mechanisms of Receptor Potentials

Mechanisms of Receptor Potentials

• Receptors excitation:
– (1) by mechanical deformation of the receptor, which
stretches the receptor membrane and opens ion channels;
– (2) by application of a chemical to the membrane, which
also opens ion channels;

– (3) By change of the temperature of the membrane, which
alters the permeability of the membrane; or

– (4) By the effects of electromagnetic radiation, such as
light on a retinal visual rec eptor, which eith er directly or
indirectly changes the receptor membrane charact eristics
and allows ions to flow through membrane channels.

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• In all 4 situations;

• Maximum Receptor Potential Amplitude.

– End result is à Change in membrane potential
– Ions flow

– Maximum amplitude à 100 millivolts,
– Only at an extremely high intensity of sensory stimulus.

– thereby to change the transmembrane potential.

• Relation of the Receptor Potential to Action
Potentials.
– Receptor potential rises above the threshold
– Eliciting action potentials in the nerve fiber attached to the receptor,
– Action potentials occur

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• Receptor Potential of the Pacinian
Corpuscle—An Example of Receptor Function

– Central nerve fiber extending through its core
– Surrounding this are multiple concentric capsule layers, so
compression anywhere on the outside of the corpuscle will
elongate, indent, or otherwise deform the central fiber

• Relation Between Stimulus Intensity and the
Receptor Potential

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Adaptation of Receptors

• pacinian corpuscle adapts very rapidly, hair receptors adapt
within a second or so, and some joint capsule and muscle
spindle receptors adapt slowly

• Common feature
• They adapt to any constant stimulus after a period of time
• Continuous Sensory stimulus is applied à receptor responds
at a high impulse rate at first and then at a progressively
slower rate until finally th e rate of action potentials decreases
to very few or often to none at all.

• Mechanoreceptors adopt quick and completely

Nerve Fibers That Transmit Different Types of
Signals and Their Physiologic Classification

– But some do not (‘Nonadapting receptors’)

• Example:
– Longest time 2 days
– Carotid and aortic baroreceptors

• Conversely, some of the non-mechanoreceptors—the
chemoreceptors and pain receptors, for instance— probably
never adapt completely.

• Some signals need to be transmitted to or from the central
nervous system extremely rapidly. Otherwise information
would be useless.

• Nerve fibers diameter à 0.5-20 micrometers
• Larger the diameter, the greater the conducting velocity.
• Conduction velocity à 0.5-120 m/sec

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General Classification of Nerve Fibers.
• A and C
• A à alpa, beta, gamma and delta fibers.
• Aà large and medium-sized myelinated fibers of spinal
nerves.

• Cà small unmyelinated nerve fibers that conduct impulses at
low velocities.

Alternative Classification Used by
Sensory Physiologists.
• A-alpha fibers into two subgroups.
• A-beta and A-gamma cannot be distinguished.

• Group Ia
• Fibers from the annulospiral endings of muscle spindles
(average about 17 microns in diameter; these are Alpha-type
A fibers in the general classification).

• Group Ib
• Fibers from the Golgi tendon organs (average about 16
micrometers in diameter; these also are Alpha-type A fibers).

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• Group II
• Fibers from most discrete cutaneous tactile receptors and
from the flower-spray endings of the muscle spindles (average
about 8 micrometers in diameter; these are beta- and
gamma-type A fibers in the general classification).

• Group IV
• Unmyelinated fibers carrying pain, itch, temperature, and
crude touch sensations (0.5 to 2 micrometers in diameter;
they are type C fibers in the general classification).

• Group III
• Fibers carrying temperature, crude touch, and pricking pain
sensations (average about 3 micrometers in diameter; they
are delta-type A fibers in the general classification).

Transmission of Signals of Different
Intensity in Nerve Tracts—Spatial and
Temporal Summation

Spatial Summation
• Increasing signal strength is transmitted by using progressively
greater numbers of fibers.

• The different gradations of intensity can be transmitted
either by using increasing numbers of parallel fibers or by
sending more action potentials along a single fiber.

• SPATIAL SUMMATION
• TEMPORAL SUMMATION

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Temporal Summation.
• By increasing the frequency of nerve impulses in each fiber.

• Threshold and Subthreshold Stimuli—
Excitation or Facilitation.

Relaying of Signals Through Neuronal
Pools
• Organization of Neurons for Relaying Signals.

• “Discharge” and “facilitated” zones of a neuronal pool.

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Divergence of Signals Passing Through
Neuronal Pools

Divergence of Signals Passing Through
Neuronal Pools

• Often it is important for weak signals entering a neuronal pool
to excite far greater numbers of nerve fibers leaving the pool.
• This phenomenon is called divergence.
• Two major types of divergence occur and have entirel y
different purposes.
– 1-Amplifying type of divergence
– 2-Divergence into multiple tracts

Convergence of Signals

Neuronal Circuit with both Excitatory
and Inhibitory Output Signals

• Multiple inputs uniting to excite a single neuron.

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Reverberatory (Oscillatory) Circuit as a
Cause of Signal Prolongation

Continuous Signal Output from Some
Neuronal Circuits

THE END

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