Post on 06-May-2015
transcript
Staff Seminaron
Coordination of movement
Prof. Vajira Weerasinghe
Dept of Physiology
Prof. Nimal Senanayake
Dept of Medicine
Y2S2 Locomotion module
Objectives
1. Discuss the role of the cerebellum on motor coordination
2. Explain giving examples how coordination is affected in neurological disease
Role of cerebellum on motor coordination
Introduction
• the cerebellum and basal ganglia are large collections of nuclei that modify movement on a minute-to-minute basis
• these regions have marked similarities between them in the overall pattern of their connections with the cerebral cortex
- both receive information from the motor cortex
- both send information back to cortex via the thalamus
Introduction
• the cerebellum sends excitatory output to the motor cortex, while the basal ganglia sends inhibitory output
• the balance between these two systems allows for smooth, coordinated movement
- a disturbance in either system will manifest itself as a movement disorder
structure
• Cerebellum is divided into 3 lobes by 2 transverse fissures– anterior lobe– posterior lobe– flocculonodular lobe
• Anterior cerebellum and part of posterior
cerebellum – receives information from the spinal cord
• Rest of the posterior cerebellum – receives information from the cortex
• Flocculonodular lobe – involved in controlling the balance through vestibular
apparatus
• lateral zone– this is concerned with overall planning of
sequence and timing
• intermediate zone– control muscles of upper and lower limbs
distally
• vermis– controls muscles of axial body, neck, hip
Inputs
• corticopontocerebellar• from motor and premotor cortex (also sensory cortex)• these tracts supplies the contralateral cerebellar cortex
• olivocerebellar• from inferior olive
– excited by fibres from» motor cx» basal ganglia» reticular formation» spinal cord
Inputs (cont’d)
• vestibulocerebellar• to the flocculonodular lobe
• reticulocerebellar• to the vermis
• spinocerebellar tracts– dorsal spinocerebellar tracts
• from muscle spindle, prorpioceptive mechanoreceptor (feedback information)
– ventral spinocerebellar tarcts• from anterior horn cell
– excited by motor signals arriving through descending tracts (efference copy)
Outputs
• through deep cerebellar nuclei: dentate, fastigial, interpositus– 1. vermis -> fastigial nucleus -> medulla, pons– 2. intermediate zone
-> nucleus interpositus-> thalamus -> cortex
-> basal ganglia-> red nucleus
-> reticular formation– 3. lateral zone -> dentate nucleus
-> thalamus -> cortex
Neuronal circuitry of the cerebellum
• Main cortical cells in cerebellum are known as Purkinje Cells (large cells).
• There are about 30 million such cells.
• These cells constitute a unit which repeats along the cerebellar cortex.
• Somatotopic representation of the body is present in cerebellar cortex although it is not as clear as cerebral cortex.
Topographical representationvermis
intermediatezone
Functional unit of the cerebellar cortex
• a Purkinje cell
• a deep nuclear cell
• inputs
• output from the deep nuclear cell
Purkinje cell
Inputfrom Inferiorolive
Inputfrom otherafferents
Climbingfibre
Mossy fibre
Granule cells
Deep nuclearcell
Output
excitationexcitation
inhibition
• Even at rest, Purkinje cells & deep nuclear cells discharge at 40-80 Hz
• afferents excite the deep nuclear cells
• Purkinje cells inhibit the deep nuclear cells
• GABA is involved as the neurotransmitter
Functions of cerebellum
• planning of movements
• timing & sequencing of movements
• particularly during rapid movments such as during walking, running
• from the peripheral feedback & motor cortical impulses, cerebellum calculates when does a movement should begin and stop
Overview of motor system hierarchy
1. Motor areas in the cerebral cortex
Overview of motor system hierarchy
1. Motor areas in the cerebral cortex
2. Brainstem
Overview of motor system hierarchy
1. Motor areas in the cerebral cortex
2. Brainstem
3. Spinal cord
motor circuits
rhythmic movements reflexes voluntary movements
Overview of motor system hierarchy
1. Motor areas in the cerebral cortex
2. Brainstem
3. Spinal cord
motor circuits
rhythmic movements reflexes voluntary movements
Overview of motor system hierarchy
1. Motor areas in the cerebral cortex
2. Brainstem
3. Spinal cord
motor circuits
rhythmic movements reflexes voluntary movements
Cerebellum Basal ganglia
Overview of motor system hierarchy
1. Motor areas in the cerebral cortex
2. Brainstem
3. Spinal cord
motor circuits
rhythmic movements reflexes voluntary movements
Cerebellum Basal gangliaThalamus
‘Error correction’• cerebellum receives two types of information
– intended plan of movement• direct information from the motor cortex
– what actual movements result• feedback from periphery
– these two are compared: an error is calculated
– corrective output signals goes to• motor cortex via thalamus• brain stem nuclei and then down to the anterior horn cell through extrapyramidal tracts
• ‘Prevention of overshoot’– Soon after a movement has been initiated– cerebellum send signals to stop the
movement at the intended point (otherwise overshooting occurs)
• Ballistic movements– movements are so rapid it is difficult to decide
on feedback
– a high-velocity musculoskeletal movement, such as a tennis serve or boxing punch, requiring reciprocal coordination of agonistic and antagonistic muscles
– rapid movements of the body, eg. finger movements during typing, rapid eye movements (saccadic eye movements)
– therefore the movement is preplanned
planning of movements
• mainly performed by lateral zones• sequencing & timing
– lateral zones communicate with premotor areas, sensory cortex & basal ganglia to receive the plan
– next sequential movement is planned– predicting the timings of each movement
• compared to the cerebrum, which works entirely on a contralateral basis, the cerebellum works ipsilaterally
Motor learning
• the cerebellum is also partly responsible for learning motor skills, such as riding a bicycle
- any movement “corrections” are stored as part of a motor memory in the synaptic inputs to the Purkinje cell
- research studies indicate that cerebellum is a pattern learning machine
- cellular basis for cerebellum-dependent motor learning is know to be a type of long-term depression (LTD) of the Purkinje cell synapses