1. Cerebellum Yung-Yang Lin Institute of Brain Science National Yang-Ming University
Reference:

2. Outline Anatomy Cellular structure Synaptic organization
Functional properties
Balance and eye movement
Body and limb movement
Somatosensory information
Feed-forward mechanims
Planning movement
Cognitive function
Motor learning
Pathology

3. Cerebellum 10% of the total volume of the brain3
Cerebellum
10% of the total volume of the brain
More than half of all its neurons
Highly regular manner
Organized projection
Receiving projection from brain and spinal cord
Projecting to different motor systems
Motor system modulation
Evaluating disparities between intention and action
Adjusting the operation of motor centers
Three aspects of the cerebellum’s organization
Providing with extensive information
Focusing on the premotor and motor system
Modifying the synaptic transmission in the circuit modules

4. Different views of cerebellum4
Ventral view
output
output
input
Dorsal view
input
Midsagittal view
Deep nuclei

5. Composition of cerebellum5
Composition of cerebellum
Outer  gray matter (cerebellar cortex)
Inner  white matter
3 pairs of deep nuclei
Fastigial nucleus
Interpose nucleus (globose nucleus, emboliform nucleus)
Dentate nucleus
Cerebellar tracts
Inferior cerebellar peduncle (afferent projection)
Middle cerebellar peduncle (afferent projection)
Superior cerebellar peduncle (efferent projection)

6. Anatomically distinct lobes6
Distinct lobes (horizontal)
Anterior lobe
Primary fissure
Posterior lobe
Posterolateral fissure
Flocculonodular lobe
Distinct lobes (longitudinal)
Vermis
Intermediate part of hemisphere
Lateral part of hemisphere

7. Projections of cerebellum7
Projections of cerebellum

8. Cellular structure of cerebellum8
3 layers
Molecular layer
Purkinje cell layer
Granular layer
5 neuronal types
Inhibitory (GABA)
Stellate neuron
Basket neuron
Purkinje neuron
Golgi neuron
Excitatory (Glu)
Granule cell 8

9. 9
Synaptic glomerulus

10. Excitatory input of cerebellum10
Excitatory input of cerebellum
Mossy fiber
Originate: nuclei in the spinal cord and brain stem
Carry : sensory information
Terminate on: dendrites of granule cells
Climbing fiber
Originate: inferior olivary nucleus
Carry: somatosensory, visual, or cerebral cortical information
Terminate on: cell bodies and proximal dendrites of purkinje neurons

11. 11

12. 12
Output of granule cell
Parallel fibers

13. Excitatory inputs to Purkinje cells13
Excitatory inputs to Purkinje cells
Parallel fibers
1 Purkinje cells receives million inputs
Climbing fibers
1 climbing fiber contacts 1-10 Purkinje cells
Arranged topographically
Inhibitory inputs to Purkinje cells
Stellate interneurons
Basket interneurons
Golgi interneurons

14. Synaptic organization of cerebellum14
Synaptic organization of cerebellum

15. The geometry of the principal connections15
Purkinje cell
(+)
(+)
Parallel fiber
Granule cell
Climbing fiber
Mossy fiber

16. Complex spike Simple spike16
Complex spike
An initial large amplitude spike followed by a high-frequency burst of smaller amplitude action potential
Evoked by climbing fibers
Simple spike
A brief excitatory postsynaptic potential that generates a single action potential
Evoked by parallel fibers
Simple spike
Complex spike

17. Mossy and climbing fibers encode peripheral and descending information17
Mossy and climbing fibers encode peripheral and descending information
Mossy fiber
Granule cell
Parallel fiber
Simple spike
Change in firing frequency
Spontaneous activity
(ex. Sensory stimuli)
Encode the magnitude and
duration of peripheral stimuli
Change in firing frequency
Climbing fiber
Complex spike

18. Synchronization of complex spikes in the Purkinje neurons18
Synchronization of complex spikes in the Purkinje neurons

19. Climbing fibers modulate parallel fibers19
Climbing fibers modulate parallel fibers
Mossy fiber
Granule cell
Parallel fiber
Simple spike
Change in firing frequency
Spontaneous activity
(ex. Sensory stimuli)
Encode the magnitude and
duration of peripheral stimuli
Change in firing frequency
Climbing fiber
Complex spike

20. 20
Climbing fiber activity produces long-lasting effects on the synaptic efficacy of parallel fibers
Climbing fiber action potentials reduce the strength of the parallel fiber input to the Purkinje neurons.
Activity in climbing fibers can induce selective long-term depression (LTD) in the synaptic strength of parallel fibers.

21. Functional properties of cerebellum21
Functional properties of cerebellum
Balance and eye movement
Body and limb movement
Somatosensory information
Feed-forward mechanims
Planning movement
Cognitive function
Motor learning

22. Balance and eye movement22
Balance and eye movement
Vestibulocerebellum (flocculonodular lobe)
Receives input from : semicircular canals and otolith organs
Senses motion of head and position relative to gravity

23. Lesion Impairing Difficulty maintaining balance Pattern23
Lesion
Impairing
Eye movement during head rotation
Movement of limbs and body during standing and walking
Difficulty maintaining balance
Pattern
Separating their feed widely
Moving legs irregularly

24. Body and limb movement Spinocerebellum24
Body and limb movement
Spinocerebellum
Input: somatosensory information
Pathway
Direct pathway
Dorsal spinocerebellar tract
Ventral spinocerebellar tract
Central locomotor rhythm
Indirect pathway
Precerebellar neuclei

25. Sensory maps in cerebellum25
Sensory maps in cerebellum
Vermis
Head and trunk
Cerebellar hemisphere
Limb
Fractured somatotropy
The same body part in different locations

27. Somatotopy in deep cerebellar nuclei27
Arranging to receive projection
Two maps
Dorsal and ventral surfaces
Intermediate and lateral zone
Projecting arrangement
Magnocellular red nucleus
Primary motor cortex via thalamus
Intermediate zone (spinocerebellum)
Lateral zone (cerebrocerebellum)

28. The Spinocerebellum Modulates the Descending Motor Systems in the Brain Stem and Cerebral Cortex28
Vermis
Control motor cortex
Fastigal nucleus
Thalamus
Brain stem
reticular formation
Lateral
Vestibular nucleus
Spinal cord

29. Intermediate hemisphere29
Lateral hemisphere
Intermediate hemisphere
Dentate nucleus
interposed nuclei
Thalamus
Motor cortex
Control motor cortex

30. The Spinocerebellum Uses Feed-Forward Mechanisms to Regulate Movements30
Vilis and Hore, 1977
position
velocity
biceps
triceps 30

31. Lesion Cerebellar hypotonia Dysmetria (abnormal measure)31
Lesion
Cerebellar hypotonia
Reducing the excitability of motor neurons and muscle tone
Dysmetria (abnormal measure)
Disrupting the accuracy of reaching movement
Ataxic (loss of order)
The path of hand in reaching is curved
Terminal tremor
Hands oscillate irregularly around the target

32. 32
Cerebrocerebellum Is Involved in Planning Movement and Evaluating Sensory Information for Action
Cerebrocerebellum (Lateral hemisphere)
Part of a high-level internal feedback circuit
Regulating cortical motor programs
Pathway
cortical input  pontine nucluei 
middle cerebellar peduncle 
contralateral dentate nucleus 
lateral hemisphere
Lesions
disrupting motor planning and prolonging reaction time
Decomposition of movement

33. Cognitive functions in cerebellum33

34. Cerebellum participates in motor learning34
Normal
Patients

35. Distinctive symptoms and signs in cerebellar disease35
A lesion in the right cerebellar hemisphere
Delaying the initiation of movement

36. Decomposition of movement Tremor increasing36
Dysmetria
Inaccuracy in range
and direction
Decomposition of movement
Tremor increasing

37. 37
Dysdiadochokinesia
Irregular pattern of alternating movements

38. Thanks for attention

39. 39
Anatomy
The Cerebellum Has Three Functionally Distinct Regions
Cellular structure
Cerebellar Circuits Consist of a Main Excitatory Loop and an Inhibitory Side-Loop
Neurons in the Cerebellar Cortex Are Organized into Three Layers
Synaptic organization
The Purkinje Cells Receive Excitatory Input From Two Afferent Fiber Systems and Are Inhibited by Three Local Interneurons
Mossy and Climbing Fibers Encode Peripheral and Descending Information Differently
Climbing Fiber Activity Produces Long-Lasting Effects on the Synaptic Efficacy of Parallel Fibers
Functional property
The Vestibulocerebellum Regulates Balance and Eye Movements
The Spinocerebellum Regulates Body and Limb Movements
Somatosensory Information Reaches the Spinocerebellum Through Direct and Indirect Mossy Fiber Pathways
The Spinocerebellum Contains Sensory Maps
The Spinocerebellum Modulates the Descending Motor Systems in the Brain Stem and Cerebral Cortex
The Spinocerebellum Uses Feed-Forward Mechanisms to Regulate Movements

40. The Cerebrocerebellum Also Has Purely Cognitive Functions 40
The Cerebrocerebellum Is Involved in Planning Movement and Evaluating Sensory Information for Action
The Cerebrocerebellum Is Part of a High-Level Internal Feedback Circuit That Regulates Cortical Motor Programs
Lesions of the Cerebrocerebellum Disrupt Motor Planning and Prolong Reaction Time
The Cerebrocerebellum Also Has Purely Cognitive Functions
The Cerebellum Participates in Motor Learning
Pathology
Cerebellar Diseases Have Distinctive Symptoms and Signs