Chapter_55 Cortical and Brain Stem Control.pdf

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Cortical and Brain Stem Control
of Motor Function

Copyright © 2011 by Saunders, an imprint of Elsevier Inc.
 Motor Cortex

divided into 3 sub areas
primary motor cortex
– unequal topographic representation.
– fine motor movement elicited by stimulation.
premotor area
– topographical organization similar to primary
motor cortex.
– stimulation results in movement of muscle
groups to perform a specific task.
– works in concert with other motor areas.
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 Motor Cortex (Cont.)

supplemental motor area
– topographically organized.
– simulation often elicits bilateral movements.
– functions in concert with premotor area to
provide attitudinal, fixation or positional
movement for the body.
– it provides the background for fine motor
control of the arms and hands by premotor and
primary motor cortex.

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 Motor areas of the cortex

Figure 55-3

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 Functional Organization of the Primary
Motor Cortex

Figure 55-2
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 Specialized Areas of the Motor Cortex

Broca’s area
– damage causes decreased speech capability.
– closely associated area controls appropriate
respiratory function for speech.
eye fixation and head rotation area
– for coordinated head and eye movements
hand skills area
– damage causes motor apraxia the inability to
perform fine hand movements.

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 Transmission of Cortical Motor Signals

direct pathway
– corticospinal tract.
– for discrete detailed movement.
indirect pathway
– signals to basal ganglia, cerebellum, and brainstem
nuclei.

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 The Corticospinal Tract
originates in the primary motor cortex (30%),
and supplementary motor areas (30%), and
somatic sensory areas (40%).

majority of fibers cross to opposite side in
medulla and descend in the lateral
corticospinal tracts.

corticospinal fibers synapse with
interneurons anterior motor neurons and a
few sensory relay neurons in the cord gray
matter.

giant pyramidal cells (Betz cells) give rise
to large fibers with fast transmission rates
(70m/sec)
Figure 55-4
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 Corticospinal Fibers

34,000 Betz cell fibers, make up only about
3% of the total number of fibers.
97 % of the 1 million fibers are small diameter
fibers.
– conduct background tonic signals
– feedback signals from the cortex to control
intensity of the various sensory signals to the brain

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 Other Pathways from the Motor Cortex

Betz collaterals back to cortex sharpen the
boundaries of the excitatory signal.
fibers to caudate nucleus and putamen
fibers to the red nucleus, which then sends axons
to the cord in the rubrospinal tract
reticular substance, vestibular nuclei and pons
then to the cerebellum
therefore the basal ganglia, brain stem and
cerebellum receive a large number of signals from
the cortex
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 Other Motor Pathways

Figure 55-5

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 Incoming Sensory Pathways to Motor Cortex

subcortical fibers from adjacent areas of the cortex
especially from somatic sensory areas of parietal
cortex and visual and auditory cortex.
subcortical fibers from opposite hemisphere which
pass through corpus callosum.
somatic sensory fibers from ventrobasal complex
of the thalamus (i.e. cutaneous and proprioceptive
fibers).

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 Incoming Sensory Pathways to Motor
Cortex (Cont.)

ventrolateral and ventroanterior nuclei of thalamus
for coordination of function between motor cortex,
basal ganglia, and cerebellum.
fibers from the intralaminar nuclei of thalamus
(control level of excitability of the motor cortex),
some of these may be pain fibers

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 Red Nucleus and the Rubrospinal Tract

substantial input from primary motor cortex
primary motor cortex fibers synapse in the lower
portion of the nucleus called the magnocellular
portion which contains large neurons similar to Betz
cells
magnocellular portion gives rise to rubrospinal tract
magnocellular portion has somatotopic organization
similar to primary motor cortex

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 Red Nucleus and the Rubrospinal Tract

stimulation of red nucleus causes relatively fine
motor movement but not as discrete as primary
motor cortex
accessory route for transmission of discrete signals
from the motor cortex

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 Sensory Feedback is Important for
Motor Control

feedback from muscle spindle, tactile receptors, and
proprioceptors fine tunes muscle movement
length mismatch in spindle causes auto correction
compression of skin provides sensory feedback to
motor cortex on degree of effectiveness of intended
action

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 Excitation of Spinal Motor Neurons

motor neurons in cortex reside in layer V.
excitation of 50-100 giant pyramidal cells is
needed to cause muscle contraction.
most corticospinal fibers synapse with
interneurons.
some corticospinal and rubrospinal neurons
synapse directly with alpha motor neurons in the
spinal cord especially in the cervical enlargement.
these motor neurons innervate muscles of the
fingers and hand

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 Lesions of the Motor Cortex

primary motor cortex - loss of voluntary control of
discrete movement of the distal segments of the
limbs.
basal ganglia - muscle spasticity from loss of
inhibitory input from accessory areas of the cortex
that inhibit excitatory brainstem motor nuclei.

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 Control of Motor Function by the Brainstem

brainstem as an extension of the spinal cord.
– performs motor and sensory functions for the face
and head (i.e.. cranial nerves).
– similar to spinal cord for functions from the head
down.
contains centers for stereotypic movement and
equilibrium.

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 Support of the Body Against Gravity

the muscles of the spinal column and the extensor
muscles of the legs support the body against
gravity.
these muscles are under the influence of brainstem
nuclei.
the pontine reticular nuclei excite the antigravity
muscles.
the medullary reticular nuclei inhibit the
antigravity muscles.

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Orientation of the Pontine
and Medullary Reticular
Nuclei

Figure 55-7
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 Pontine Reticular Nuclei

transmit excitatory signals through
pontinereticulospinal tract.
pontine reticular nuclei have a high degree of natural
excitability.
when unopposed they cause powerful excitation of
the antigravity muscles.

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 Medullary Reticular Nuclei

transmit inhibitory signals to the antigravity
muscles through the medullaryreticulospinal tract.
these nuclei receive collateral input from the
corticospinal tract, rubrospinal tract, and other
motor pathways.
these systems can activate the inhibitory action of
the medullary reticular nuclei and counterbalance
the signals from the pons.

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 Vestibular Apparatus

system of bony tubes and chambers in the
temporal bone.
– semicircular ducts.
– utricle.
– saccule.
within the utricule and the saccule are
sensory organs for detecting the orientation
of the head with respect to gravity called
the macula.
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 The Vestibular Apparatus

Figure 55-9
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 The Macula
the statoconia make the structure top
heavy so that itis capable of responding
to changes in head position.

gravity sensitive receptor
consists of gravity sensitive hair cells

Figure 55-9

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Hair Cells

have a series of protrusions called stereocilia
and one large protrusion called the
kinocilium.
these structures are directionally sensitive.

bending in one direction causes
depolarization, bending in the opposite
direction cause hyperpolarization.

Figure 55-10
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 Detection of Head Orientation

in each macula different hair cells are oriented in
different directions.
some are stimulated when the head bends forward,
some when the head bends backward, some when
the head bends to the side.
the pattern of excitation of the hair cells apprises
the brain of the orientation of the head with
respect to gravity.

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 Semicircular Canals

-all located at 900 toeach other
representing all 3 planes in space.

-each duct has an enlargement at
the end called an ampulla.

-within the ampulla is a sensory
structure called the crista
ampullaris.

-bending the crista ampullaris in a
particular direction excites the hair cells

Figure 55-11

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 Maintaining Equilibrium

information from the hair cells in the maculae of
the utricles and saccules is transmitted to the brain
via the vestibular nerve.
when the body is accelerated forward the hair cells
of the maculae bend in the opposite direction, this
causes one to feel as if they are falling backward.
reflexes cause the body to lean forward.

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 Semicircular Ducts Detect Angular
Acceleration

rotation of the duct detects rotational movements
of the head.
endolymph tends to remain stationary in the duct
because of inertia.
rotation of the duct in one direction causes relative
movement of endolymph in the opposite direction
activating the receptors in the cristaampullaris.
stop the rotation, the opposite happens.

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 Response of a hair cell when
a semicircular canal is stimulated.

Figure 55-12

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 Predictive Function of the Semicircular Ducts

semicircular ducts predict situations in which
equilibrium will be affected and this information is
sent to the brain.
corrective measures are initiated before the
equilibrium is affected.
neck proprioceptors and visual input also contribute
to the maintenance of equilibrium.

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 Neuronal Connections of the Vestibular
Apparatus

Figure 55-13

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