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Chapter 14: The Cutaneous Senses

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Chapter 14: The Cutaneous Senses Somatosensory System There are three parts Cutaneous senses - perception of touch and pain from stimulation of the skin ... – PowerPoint PPT presentation

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Title: Chapter 14: The Cutaneous Senses


1
Chapter 14 The Cutaneous Senses
2
Somatosensory System
  • There are three parts
  • Cutaneous senses - perception of touch and pain
    from stimulation of the skin
  • Proprioception - ability to sense position of the
    body and limbs
  • Kinesthesis - ability to sense movement of body
    and limbs

3
Mechanoreceptors
  • Two types located close to surface of the skin
  • Merkel receptor fires continuously while stimulus
    is present.
  • Responsible for sensing fine details
  • Meissner corpuscle fires only when a stimulus is
    first applied and when it is removed.
  • Responsible for controlling hand-grip

4
  • Figure 14.1 A cross section of glabrous (without
    hairs or projections) skin, showing the layers of
    the skin and the structure, firing properties and
    perceptions associated with the Merkel receptor
    and Meissner corpuscle - two mechanoreceptors
    that are near the surface of the skin.

5
Mechanoreceptors - continued
  • Two types located deeper in the skin
  • Ruffini cylinder fires continuously to
    stimulation
  • Associated with perceiving stretching of the skin
  • Pacinian corpuscle fires only when a stimulus is
    first applied and when it is removed.
  • Associated with sensing rapid vibrations and fine
    texture

6
  • Figure 14.2 A cross section of glabrous skin,
    showing the structure, firing properties and
    perceptions associated with the Ruffini cylinder
    and the Pacinian corpuscle - two mechanoreceptors
    that are deeper in the skin.

7
Pathways from Skin to Cortex
  • Nerve fibers travel in bundles (peripheral
    nerves) to the spinal cord.
  • Two major pathways in the spinal cord
  • Medial lemniscal pathway consists of large fibers
    that carry proprioceptive and touch information.
  • Spinothalamic pathway consists of smaller fibers
    that carry temperature and pain information.

8
Maps of the Body on the Cortex
  • Body map (homunculus) on the cortex in S1 and S2
    shows more cortical space allocated to parts of
    the body that are responsible for detail.
  • Plasticity in neural functioning leads to
    multiple homunculi and changes in how cortical
    cells are allocated to body parts.

9
  • Figure 14.4 (a) The sensory homunculus on the
    somatosensory cortex. Parts of the body with the
    highest tactile acuity are represented by larger
    areas on the cortex. (b) The somatosensory cortex
    in the parietal lobe. The primary somatosensory
    area, S1 (light shading), receives inputs from
    the ventrolateral nucleus of the thalamus. The
    secondary somatosensory area, S2 (dark shading),
    is partially hidden behind the temporal lobe.
    (Adapted from penfield Rasmussen, 1950).

10
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11
  • Figure 14.5 (a) Each numbered zone represents the
    area in the somatosensory cortex that represents
    one of the monkeys five fingers. The shaded area
    on the zone for finger 2 is the part of the
    cortex that represents the small area on the tip
    of the finger shown in (b). (c) The shaded region
    shows how the area representing the fingertip
    increased in size after this area was heavily
    stimulated over a 2-month period. (From Merzenich
    et al., 1988)

12
Perceiving Details
  • Measuring tactile acuity
  • Two-point threshold - minimum separation needed
    between two points to perceive them as two units
  • Grating acuity - placing a grooved stimulus on
    the skin and asking the participant to indicate
    the orientation of the grating
  • Raised pattern identification - using such
    patterns to determine the smallest size that can
    be identified

13
  • Figure 14.7 Methods for determining tactile
    acuity (a) two-point threshold (b) grating
    acuity.

14
Receptor Mechanisms for Tactile Acuity
  • There is a high density of Merkel receptors in
    the fingertips.
  • Merkel receptors are densely packed on the
    fingertips - similar to cones in the fovea.
  • Both two-point thresholds and grating acuity
    studies show these results.

15
Cortical Mechanisms for Tactile Acuity
  • Body areas with high acuity have larger areas of
    cortical tissue devoted to them.
  • This parallels the magnification factor seen in
    the visual cortex for the cones in the fovea.
  • Areas with higher acuity also have smaller
    receptive fields on the skin.

16
  • Figure 14.10 Two-point thresholds for males.
    Two-point thresholds for females follow the same
    pattern. (From S. Weinstein, 1968.)

17
  • Figure 14.11 Receptive fields of monkey cortical
    neurons that fire (a) when the fingers are
    stimulated (b) when the hand is stimulated and
    (c) when the arm is stimulated. (d) Stimulation
    of two nearby points on the finger causes
    separated activation on the finger area of the
    cortex, but stimulation of two nearby points on
    the arm causes overlapping activation in the arm
    area of the cortex. (From Kandel Jessell, 1991
    (a-c).

18
Perceiving Vibration
  • Pacinian corpuscle (PC) is primarily responsible
    for sensing vibration.
  • Nerve fibers associated with PCs respond best to
    high rates of vibration.
  • The structure of the PC is responsible for the
    response to vibration - fibers without the PC
    only respond to continuous pressure.

19
  • Figure 14.12 (a) When a vibrating pressure
    stimulus is applied to the Pacinian corpuscle, it
    transmits these pressure vibrations to the nerve
    fiber. (b) When a continuous pressure stimulus is
    applied to the Pacinian corpuscle, it does not
    transmit the continuous pressure to the fiber.
    (c) Lowenstein determined how the fiber fired to
    stimulation of the corpuscle (at A), and to
    direct stimulation of the fiber (at B) (Adapted
    from Lowenstein, 1960)

20
Perceiving Texture
  • Katz (1925) proposed that perception of texture
    depends on two cues
  • Spatial cues are determined by the size, shape,
    and distribution of surface elements.
  • Temporal cues are determined by the rate of
    vibration as skin is moved across finely textured
    surfaces.
  • Two receptors may be responsible for this process
    - called the duplex theory of texture perception

21
Perceiving Texture - continued
  • Past research showed support for the role of
    spatial cues.
  • Recent research by Hollins and Reisner shows
    support for the role of temporal cues.
  • In order to detect differences between fine
    textures, participants needed to move their
    fingers across the surface.

22
  • Figure 14.13 (a) Participants in Hollins and
    Reisners (2000) experiment perceived the
    roughness of two fine surfaces to be essentially
    the same when felt with stationary fingers, but
    (b) could perceive the difference between the two
    surfaces when they were allowed to move their
    fingers.

23
  • Figure 14.16 (a) Response of fibers in the
    fingertips to touching a high-curvature stimulus.
    The height of the profile indicates the firing
    rate at different places across the fingertip.
    (b) The profile of firing to touching a stimulus
    with more gentle curvature. (From Goodwin, 1998)

24
The Physiology of Tactile Object Perception -
continued
  • Monkeys somatosensory cortex also shows neurons
    that respond best to
  • grasping specific objects.
  • paying attention to the task.
  • Neurons may respond to stimulation of the
    receptors, but attending to the task increases
    the response.

25
  • Figure 14.18 Receptive fields of neurons in the
    monkeys somatosensory cortex. (a) This neuron
    responds best when a horizontally oriented edge
    is presented to the monkeys hand. (b) This
    neuron responds best when a stimulus moves across
    the fingertip from right to left. (From Hyvarinin
    Poranen, 1978)

26
  • Figure 14.19 The response of a neuron in a
    monkeys parietal cortex that fires when the
    monkey grasps a ruler but that does not fire when
    the monkey grasps a cylinder. The monkey grasps
    the objects at time 0. (From Sakata Iwamura,
    1978)

27
  • Figure 14.20 Firing rate of a neuron in area S1
    of a monkeys cortex to a letter being rolled
    across the fingertips. The neuron responds only
    when the monkey is paying attention to the
    tactile stimulus. (From Hsiao, OShaughnessy,
    Johnson, 1993)

28
Pain Perception
  • Pain is a multimodal phenomenon containing a
    sensory component and an affective or emotional
    component.
  • Three types of pain
  • Nociceptive - signals impending damage to the
    skin
  • Types of nociceptors respond to heat, chemicals,
    severe pressure, and cold.
  • Threshold of eliciting receptor response must be
    balanced to warn of damage, but not be affected
    by normal activity.

29
Types of Pain
  • Inflammatory pain - caused by damage to tissues
    and joints or by tumor cells
  • Neuropathic pain - caused by damage to the
    central nervous system, such as
  • Brain damage caused by stroke
  • Repetitive movements which cause conditions like
    carpal tunnel syndrome

30
  • Figure 14.21 Nociceptive pain is created by
    activation of nociceptors in the skin that
    respond to different types of stimulation.
    Signals from the nociceptors are transmitted to
    the spinal cord and then from the dorsal root of
    the spinal cord in pathways that lead to the
    brain.

31
Direct Pathway Model of Pain Perception
  • Early model that stated nociceptors are
    stimulated and send signals to the brain
  • Problems with this model
  • Pain can be affected by a persons mental state.
  • Pain can occur when there is no stimulation of
    the skin.
  • Pain can be affected by a persons attention.

32
Gate Control Model of Pain Perception
  • The gate consists of substantia gelatinosa
    cells in the spinal cord (SG- and SG).
  • Input into the gate comes from
  • Large diameter (L) fibers - information from
    tactile stimuli
  • Small diameter (S) fibers - information from
    nociceptors
  • Central control - information from cognitive
    factors from the cortex

33
Gate Control Model of Pain Perception - continued
  • Pain does not occur when the gate is closed by
    stimulation into the SG- from central control or
    L-fibers into the T-cell.
  • Pain does occur from stimulation from the
    S-fibers into the SG into the T-cell.
  • Actual mechanism is more complex than this model
    suggests.

34
Cognitive and Experiential Aspects of Pain
  • Expectation - when surgical patients are told
    what to expect, they request less pain medication
    and leave the hospital earlier
  • Placebos can also be effective in reducing pain.
  • Shifting attention - virtual reality technology
    has been used to keep patients attention on
    other stimuli than the pain-inducing stimulation

35
Cognitive and Experiential Aspects of Pain -
continued
  • Content of emotional distraction - participants
    could keep their hands in cold water longer when
    pictures they were shown were positive
  • Experiment by Derbyshire to investigate
    hypnotically induced pain.
  • Participants had a thermal stimulator attached
    the to palm of their hand.

36
Experiment by Derbyshire et al. - continued
  • Three conditions
  • Physically induced pain
  • Hypnotically induced pain
  • Control group that imagined painful stimulation
  • Both subjective reports and fMRI scans showed
    that hypnosis did produce pain perception.

37
  • Figure 14.24 The results of deWied and Verbatens
    (2001) experiment showing that participants kept
    their hands in cold water longer when looking at
    positive pictures than when looking at neutral or
    negative pictures.

38
Opioids and Pain
  • Brain tissue releases neurotransmitters called
    endorphins.
  • Evidence shows that endorphins reduce pain.
  • Injecting naloxone blocks the receptor sites
    causing more pain.
  • Naloxone also decreases the effectiveness of
    placebos.
  • People whose brains release more endorphins can
    withstand higher pain levels.

39
  • Figure 14.28 (a) Naloxone reduces the effect of
    heroin by occupying a receptor site normally
    stimulated by heroin. (b) Stimulating sites in
    the brain that cause the release of endorphins
    can reduce the pain by stimulating opiate
    receptor sites. (c) Naloxone decreases the pain
    reduction caused by endorphins, by keeping the
    endorphins from reaching the receptor sites.

40
Pain in Social Situations
  • Experiment by Eisenberger et al.
  • Participants watched a computer game.
  • Then, they were asked to play with two other
    players who did not exist but were part of the
    program.
  • The players excluded the participant.
  • fMRI data showed increased activity in the
    anterior cingulate cortex and participants
    reported feeling ignored and distressed.

41
Pain in Social Situations - continued
  • Experiment by Singer et al.
  • Romantically involved couples participated.
  • The womans brain activity was measured by fMRI.
  • The woman either received shocks or she watched
    while her partner received shocks.
  • Similar brain areas were activated in both
    conditions.
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