Control of Movement
One of the principle functions of generating internal representations of the world is to guide movement. Even simple actions require sensory information about what and where our actions are. Proprioreceptive information is needed.
The following is a general description of how movement is controlled:
- planning and initiation
- processing
- spinal outputs
- motor neurons
- myotomes describe the muscles innervated by specific spinal nerves
Special types of movement:
- proprioreception (or should this be under sensation?)
- head and eye movements
- speech
Planning and Initiation
The purpose of movement is determined by the dorsolateral frontal cortex.
Motor plans are thought up by the posterior parietal and premotor areas. The premotor cortex specifies spatial characteristics of movement based on sensory information from the parietal cortex.
The spatiotemporal details of muscle contractions required to execute planned actions are coordinated by motor circuits in the spinal cord.
primary motor cortex
- much devoted to the face and mouth (speech) and the hand
- very little for the rest of the body
pre-motor cortex
supplementary motor cortex
- involved in complex movements, both contralaterally and ipsilaterally; also engaged during mental rehearsal of complex movements
following stroke in some areas, volitional control is gone and someone can't smile symmetrically if told, though a joke will cause a symmetrical smile
Processing
Many structures are involved with processing motor control. These include:
- Thalamus, a central junction as information passes from the cerebellum, basal ganglia, subthalamic nuclei, and substantia nigra to the motor cortex. It also sends information back to the striatum in the basal ganglia.
- Cerebellum
- Basal ganglia - mediates many of the feedback loops involving other components of motor control
Spinal Output
Descending motor tracts can synapse in the spinal cord, mediating activity there, or exit the central nervous system through the ventral horn to innervate muscle.
- corticospinal tract
- corticobulbar tract
- medial longitudinal fasciculus
- rubrospinal tract
- reticulospinal tract
- vestibulospinal tract
- tectospinal tract
corticospinal tract
Motor commands for fine, learned, complex movements (ie finger/hand) arise in the motor cortex (30%); pre-motor cortex (30%), and parietal (somatosensory) cortex (40%), and descend through the corticospinal tracts.
Axons descend ipsilaterally through white matter of the internal capsule and the cerebral peduncles of the midbrain, breaking into fascicles as they enter the basilar pons. They then descend through pyramidal tracts of medulla, the site of decussation of the lateral corticospinal tract (85%), which extend the length of the spinal cord. The other 15% do not cross and descend in the anterior corticospinal tract. These upper motor neurons synapse in the ventral horn upon α motor neurons, which exit along the ventral root.
clinical correlate: sectioning the corticospinal tract in a monkey leads to a few days of finger dexterity loss, but after a few weeks there is little to show for it.
corticobulbar tract
The corticobulbar tract carries motor information from the cortex alongside the corticospinal tract, terminating on the reticular formation and on motor nuclei of the cranial nerves.
medial longitudinal fasciculus
The MLF is responsible for coordinating head and eye movements. It begins in the vestibular nuclei and runs along the midline of the brainstem to the cervical spinal cord, where it synapses on interneurons. Some fibres end in the abducens, trochlear, and oculomotor nuclei.
Problems in the MLF can lead to internuclear ophthalmoplegia, where horizontal gaze is disrupted in one eye past midline.
rubrospinal tract
arises in red nucleus in midbrain, which receives input from deep cerebellar nuclei and motor cortex
reticulospinal tract
projections from the cortex to the reticular formation; descends in lateral column
- terminates on spinal cord interneurons and gamma motor neurons
vestibulospinal tract
arises in vestibular nuclei, which receives input from the vestibular nerve and cerebellum
- lateral vst innervates alpha and gamma motor neurons
all along spinal cord, playing an important role in maintaining posture
- spinning around and trying to walk can result in staggering, the product of overactive vestibulospinal tract
- medial vst runs alongside MLF, innervating cervical spinal cord and responsible for head position
tectospinal tract
arises from cells in the superior colliculus in the midbrain
- some descending fibres become incorporated into the medial longitudinal fasciculus in the medulla
- other fibres descend in anterior funiculus of spinal cord and terminate at the cervical level, where they synapse on motor neurons
- controls reflex movements of upper trunk, neck, and eyes in response to visual stimuli.
Motor Neurons
Descending pathways synapse in the medial and lateral alpha motoneuronal nuclei. Medial nuclei are found at almost every level, while lateral nuclei are prominent in the upper and lower limb cord enlargements.
There is somatotopy here, with flexors being more anterior and extensors being posterior.
Motor neurons are massive cells with a huge dendritic tree. They reside in the brainstem or the ventral horn of the spinal cord. Each lower motor neuron innervates muscle fibres of the same type.
- α motor neurons innervate the main force-generating muscle fibres (extrafusal fibres)
- γ motor neurons innervate only fibres of muscle spindles.
All the neurons that innervate a single muscle form a motor neuron pool.
Upper motor neuron - used clinically to indicate a population of neurons with oligosynaptic input to lower motor neurons, the loss of which leads to relatively speicific motor findings. Usually refers to cells in the brain, but can also include those of the spinal cord.
Lower motor neurons originate in the brainstem or spinal cord; innervates muscles
Distinguishing Upper vs Lower Motor Neuron Problems:
| UMN | LMN | |
| muscle bulk | normal | atrophy |
| muscle tone | increased (spasticity) | normal or decreased |
| tendon reflexes | increased | normal or decreased |
| Babinski | positive | normal |
| other | - | fasciculations |
loss of neurons (polio, ALS, etc) causes remodeling of the motor units. Giant single contractions are seen, but reduced interference patterns
Motor Units
Each motor neuron commands a group of skeletal muscle cells. Each muscle cell belongs to only one motor unit, which can vary in size depending on muscle function. Extraocular muscles can have just a few fibres per unit, while some leg muscles can have several thousand muscle fibres per motor unit.
To Sort
monoamines modulate how motor neurons fire, in order to change the signals which are required to maintain muscle strength
injection of DOPA increases motor neuron firing frequency, as well as sustained firing after signal has been removed.
Stimulation of the MLR activates descending mono-adrenergic pathways, causing increased force in the 1B reflex (golgi tendon)