1. Prepared by Jeffrey W. Grimm Western Washington University
PowerPoint Presentation for Biopsychology, 8th Edition by John P.J. Pinel
Prepared by Jeffrey W. Grimm
Western Washington University
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Chapter 8
The Sensorimotor System
How You Move
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3. Three Principles of Sensorimotor Function
Hierarchical Organization
Association cortex at the highest level, muscles at the lowest
Parallel structure – signals flow between levels over multiple paths
Motor Output is Guided by Sensory Input
Learning Changes the Nature and Locus of Sensorimotor Control
e.g. conscious to automatic
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FIGURE 8.1 A general model of the sensorimotor system.
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5. Sensorimotor Association Cortex
Posterior parietal association cortex
Dorsolateral prefrontal association cortex
Each composed of several different areas with different functions
Some disagreement exists about how to divide the areas up
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6. Posterior Parietal Association Cortex
Integrates information about
Body part location
External objects
Receives visual, auditory, and somatosensory information
Outputs to motor cortex
Including dorsolateral prefrontal association cortex, secondary motor cortex, and frontal eye field
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FIGURE 8.2 The major cortical input and output pathways of the posterior parietal association cortex.
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8. Damage to the Posterior Parietal Cortex
Apraxia – disorder of voluntary movement – problem only evident when instructed to perform an action – usually a consequence of damage to the area on the left
Contralateral neglect – unable to respond to stimuli contralateral to the side of the lesion – usually seen with large lesions on the right
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FIGURE 8.3 Contralateral neglect is sometimes manifested in terms of gravitational coordinates, sometimes in terms of object-based coordinates.
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10. Dorsolateral Prefrontal Association Cortex
Input from posterior parietal cortex
Output to secondary motor cortex, primary motor cortex, and frontal eye field
Evaluates external stimuli and initiates voluntary reactions – supported by neuronal responses
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11. Secondary Motor Cortex
Input mainly from association cortex
Output mainly to primary motor cortex
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12. Identifying the Areas of Secondary Motor Cortex
At least eight different areas:
Three supplementary motor areas
SMA and preSMA, and supplementary eye field
Two premotor areas
Dorsal and ventral
Three cingulate motor areas
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FIGURE 8.5 Four areas of secondary motor cortex—the supplementary motor area, the premotor cortex, and two cingulate motor areas—and their output to the primary motor cortex.
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14. Identifying the Areas of Secondary Motor Cortex Continued
Secondary motor cortex may be involved in programming movements in response to input from dorsolateral prefrontal cortex
Active during imagining or planning of movements
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Mirror Neurons
Active when performing an action or watching another perform the same action
In monkey studies, mirror neurons fired while
grasping or watching another grasp a particular object but not other objects
grasping or watching another grasp an object for a specific purpose but not for another purpose
Possible neural basis of social cognition (knowledge of others’ mental processes – e.g., intentions)
Likely to be found in humans
Indirect evidence from functional brain-imaging studies
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FIGURE 8.6 Responses of a mirror neuron of a monkey.
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Primary Motor Cortex
Precentral gyrus of the frontal lobe
Major point of convergence of cortical sensorimotor signals
Major point of departure of signals from cortex
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18. Conventional View of Primary Motor Cortex Function
Somatotopic – more cortex devoted to body parts that make complex movements
Motor homunculus
Until recently, each neuron was thought to encode the direction of movement
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FIGURE 8.7 The motor homunculus: the somatotopic map of the human primary motor cortex. (Adapted from Penfield & Rasmussen, 1950.)
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20. Current View of Primary Motor Cortex Function
Regions of primary motor cortex support initiation of species-typical movements
Neurons direct to target of movement, rather than simply a pre-coded direction
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21. Effects of Primary Motor Cortex Lesions
Small lesions often with minimal effects
Large lesions may disrupt a patient’s ability to move one body part independently of others
Large lesions may also produce stereognosia
deficit in stereognosia (ability to identify an object by touch)
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22. Cerebellum and Basal Ganglia
Interact with different levels of the sensorimotor hierarchy
Coordinate and modulate
May permit maintenance of visually guided responses despite cortical damage
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Cerebellum
10% of brain mass, but more than 50% of its neurons
Input from primary and secondary motor cortexes
Input from brain stem motor nuclei
Feedback from motor responses
Involved in timing, fine-tuning, and motor learning
May also do the same for cognitive responses
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Basal Ganglia
A heterogenous collection of interconnected nuclei
Part of neural loops that receive cortical input and send output back via the thalamus
Modulate motor output and cognitive functions including learning
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25. Descending Motor Pathways
Two dorsolateral
Corticospinal
Corticorubrospinal
Two ventromedial
Cortico-brainstem-spinal tract
Both corticospinal tracts are direct
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Dorsolateral Tracts
Most synapse on interneurons of spinal gray matter
Corticospinal – descend through the medullary pyramids, then decussate
Betz cells – synapse on motor neurons projecting to leg muscles
Control of wrist, hands, fingers, toes
Corticorubrospinal – synapse at red nucleus and cross before the medulla
Some control muscles of the face
Distal muscles of arms and legs
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FIGURE 8.8 The two divisions of the dorsolateral motor pathway: the dorsolateral corticospinal tract and the dorsolateral corticorubrospinal tract.
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Ventromedial Tracts
Corticospinal
Descends ipsilaterally
Axons branch and innervate interneuron circuits bilaterally in multiple spinal segments
Cortico-brainstem-spinal
Interacts with various brain stem structures and descends bilaterally carrying information from both hemispheres
Synapse on interneurons of multiple spinal segments controlling proximal trunk and limb muscles
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FIGURE 8.9 The two divisions of the ventromedial motor pathway: the ventromedial corticospinal tract and the ventromedial cortico-brainstem-spinal tract.
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Comparison of the Two Dorsolateral Motor Pathways and the Two Ventromedial Motor Pathways
Dorsolateral
One direct tract, one that synapses in the brain stem
Terminate in one contralateral spinal segment
Distal muscles
Limb movements
Ventromedial
One direct tract, one that synapses in the brain stem
More diffuse
Bilateral innervation
Proximal muscles
Posture and whole body movement
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31. Sensorimotor Spinal Circuits
Motor circuits of the spinal cord show considerable complexity
Independent of signals from the brain
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Muscles
Motor units – a motor neuron plus muscle fibers; all fibers contract when motor neuron fires
Number of fibers per unit varies – fine control, fewer fibers/neuron
Muscle – muscle fibers bound together by a tendon
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Muscles Continued
Acetylcholine released by motor neurons at the neuromuscular junction causes contraction
Motor pool – all motor neurons innervating the fibers of a single muscle
Fast muscle fibers – fatigue quickly
Slow muscle fibers – capable of sustained contraction due to vascularization
Muscles are a mix of slow and fast fibers
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Muscles Continued
Flexors – bend or flex a joint
Extensors – straighten or extend
Synergistic muscles – any two muscles whose contraction produces the same movement
Antagonistic muscles – any two muscles that act in opposition
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35. Receptor Organs of Tendons and Muscles
Golgi tendon organs
Embedded in tendons
Tendons connect muscle to bone
Detect muscle tension
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36. Receptor Organs of Tendons and Muscles
Muscle spindles
Embedded in muscle tissue
Detect changes in muscle length
Intrafusal muscle within each muscle spindle innervated by its own intrafusal motor neuron
Keeps tension on the middle, stretch-sensitive portion of the muscle spindle to keep it responsive to changes in the length of the extrafusal muscle
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FIGURE 8.13 The function of the intrafusal motor neurons.
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Reflexes
Stretch Reflex: monosynaptic, serves to maintain limb stability
e.g. Patellar tendon reflex is monosynaptic
Withdrawal Reflex is NOT monosynaptic
Reciprocal Innervation – antagonistic muscles interact so that movements are smooth – flexors are excited while extensors are inhibited, etc.
Recurrent Collateral Inhibition – feedback loop through Renshaw cells that gives muscle fiber a rest after every contraction
Walking – a complex reflex in some animals
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FIGURE 8.14 The elicitation of a stretch reflex.
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FIGURE 8.17 The excitatory and inhibitory signals that directly influence the activity of a motor neuron.
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41. Central Sensorimotor Programs
Perhaps all but the highest levels of the sensorimotor system have patterns of activity programmed into them, and complex movements are produced by activating these programs
Cerebellum and basal ganglia then serve to coordinate the various programs
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42. Central Sensorimotor Programs Are Capable of Motor Equivalence
A given movement can be accomplished various ways, using different muscles
Central sensorimotor programs must be stored at a level higher than the muscle (as different muscles can do the same task)
Sensorimotor programs may be stored in secondary motor cortex
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Sensory Information That Controls Central Sensorimotor Programs Is Not Necessarily Conscious
Evidence that patients could respond to visual stimuli of which they had no conscious awareness
Evidence that patients could not effectively interact with objects that they consciously perceived
Ebbinghaus Illusion: Conscious perception of disk size differs from motor response
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FIGURE 8.18 The Ebbinghaus illusion.
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45. The Development of Central Sensorimotor Programs
Central sensorimotor programs may be hierarchically organized and capable of using sensory feedback without direct control at higher levels
Programs for many species-specific behaviors established without practice
Fentress (1973) – mice without forelimbs still make coordinated grooming motions
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46. The Development of Central Sensorimotor Programs Continued
Practice can also generate and modify programs
Response Chunking
Practice combines the central programs controlling individual response
Shifting Control to Lower Levels
Frees up higher levels to do more complex tasks
Permits greater speed
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47. Functional Brain Imaging of Sensorimotor Learning
Functional brain-imaging studies in humans have generally supported the findings from more invasive studies of non-human primates
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FIGURE 8.19 The activity recorded by PET scans during the performance of newly learned and well-practiced sequences of finger movements. (Adapted from Jenkins et al., 1994.)
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