Transcript Chapter 8

Chapter 8
The Neurological Control of Movement
Levels of Control of Movement

Movements can range from simple to complex:
• The simplest movements are reflexive
• Other movements are more complex than reflexes,
but less complex than other skills
• More complex movements can
be learned
Stimulation and Control of
Movement
Stimulated by the motor neurons of the CNS.
 Neural control of a particular movement
operates on several different levels:

• Most basic level of control is the spinal cord
• Next level involves brain stem structures
• Highest level of control involves the cerebral cortex
structures such as the dorsolateral prefrontal cortex, the
primary and secondary motor cortex, and the
somatosensory cortex.
 Basal ganglia – Smoothes and refines movement
 Cerebellum - Plays a central role in translating
uncoordinated movements into a skilled action
The Motor Unit
Each branch of an axon synapses with a single muscle
fiber.
 Collectively, a motor neuron and the muscle fibers it
controls form a motor unit
 When the axon of a motor neuron has few branches
and controls only a few muscle fibers, fine motor
control is possible.
 When the axon has many branches and controls
many muscle fibers, gross motor movement is
possible.

Neural Control
of Muscle
Contraction
Motor impulse
Muscle action
pearson 1
Golgi Tendon Organs
Renshaw Cells
Inhibitory interneurons excited by an
motor neuron that causes it to stop firing,
preventing excessive muscle contraction.
 Combats muscle damage that can result
from fatigue, which results from muscles
contracting often in a short period of
time.

The Gamma Motor System

Contraction does not always lead to movement.

Gamma motor neuron - synapses with intrafusal muscle
fibers to produce continuous muscle tension – muscle
tone

This muscle tone is maintained at all times, except
during REM sleep.

The gamma motor system also gives us the ability to
anticipate certain movements and react quickly.
Cortical
Control of
Movement
Tracts
Originating
in the
Primary
Motor
Cortex
Tracts
Originating in
the Subcortex
The Cerebellum
The brain area responsible for developing rapid,
coordinated responses or habits.
 Ballistic movement - A habitual, rapid, wellpracticed movement that does not depend on
sensory feedback; controlled by the cerebellum.

Consequences of Cerebellar
Damage

Difficulty maintaining a stable posture, making
movements such as walking unsteady, slurred speech,
and uncoordinated eye movements.

Research suggests that the cerebellum plays a
significant role in cognitive behaviors in addition to
its role in fine-tuning motor movements and in
motor learning.

Neurons in the cerebellum
are sensitive to alcohol

Alcohol intoxication can lead to
signs of cerebellar malfunction.
The Basal Ganglia
Integrates movement via connections with
the primary motor cortex, the cerebellum,
substantia nigra, red nucleus, and other
motor centers in the brain.
 Damage to the basal ganglia results in
impairments in muscle tone, postural
instability, poorly integrated movements, and
difficulty performing voluntary movements.

Damage to the Motor System
Parkinson’s disease
 Muscular Dystrophy
 Polio
 Huntington’s
 ALS
 Multiple Sclerosis
 Cerbral Palsy

Other Movement Disorders

Apraxia - characterized by missing or inappropriate
actions not caused by paralysis or any other motor
impairment.

Constructional apraxia - characterized by difficulty
drawing pictures or assembling objects.

Limb apraxia - impairment in the voluntary use of a limb
caused by damage to the left parietal lobe or the
corpus callosum.

Apraxia of speech - characterized by difficulty speaking
clearly, caused by damage limited to Broca’s area.

Strabismus – eye muscles do not work together