Cerebellum PDF

Summary

This document is a presentation on the cerebellum, including its structure, function, and associated clinical disorders. It details the cerebellum's anatomy, highlighting its cellular components including the Purkinje cells, granule cells, basket cells, and Golgi cells. The different types of cerebellar circuits and their role in various body functions are also explored.

Full Transcript

Cerebellum
Anne K. Galgon PT, PhD, NCS
Eric S. Pelletier PT DPT PCS
 Objectives
Identify specific structures of the cerebellum and connections
Identify and describe the function of the cerebellum
Identify the functional divisions of the cerebellum
Identify the specific neurons of the cerebellum and their functions
Describe impairments of cerebellum function.
 Cerebellar Function
Maintenance of balance and posture
Coordination of Voluntary Movements
Motor Adaptation and Learning
Cognitive Functions**
 Cerebellar Anatomy
Cerebellum means “little brain”
Accounts for 10% brain volume
Contains >50% of neurons in brain
Two Hemispheres that communicate with each other
– degree of somatotopic organization
o Hemispheres separated by the vermis
Folia – small ridges that run medial to lateral on the
surface (means “leaves”)
Cerebellum Sagittal View
Thalamus
 Cerebellar Lobes
Flocculonodular Lobe
o Located deep to the posterior lobe
o Touches the brainstem

Anterior Lobe
o Superior
o Separated from posterior lobe by primary fissure

Posterior Lobe
 Cerebellar Lobes

The primary fissure
Separates the
Anterior and Posterior Lobes
Cerebellar Lobes
Cerebellar Lobes and Regions

This is a schematic
representation of the
cerebellum

From Schenkman ML et al. Clincial Neuroscience for Rehabilitation. Pearson (2013), p. 148.
Regions

Paravermis

Lateral hemispheres
 Cerebellar Nuclei
Fastigial
Interposed Nuclei
o Emboliform
o Globose
Dentate

From Schenkman ML et al. Clincial Neuroscience for Rehabilitation. Pearson (2013), p. 149
 Cerebellar Nuclei
Fastigial
o Most medially located
o Receives input from the vermis and from cerebellar
afferents that carry vestibular, proximal somatosensory,
auditory, and visual information.
o Projects to the vestibular nuclei and the reticular
formation.
 Cerebellar Nuclei
Interposed Nuclei
o Globose
o Emboliform
o Receive input from the intermediate zone and from cerebellar
afferents that carry spinal, proximal somatosensory, auditory, and
visual information
o Project to the contralateral red nucleus (the origin of the rubrospinal
tract)
Function of Rubrospinal Tract?
 Cerebellar Nuclei
Dentate Nucleus
o Largest of the nuclei
o Receives afferent fibers from medulla
o Projects to the contralateral red nucleus and the
ventrolateral (VL) thalamic nucleus.
 Vestibular Nuclei
Located in the rostral Medulla/
caudal Pons
Functionally like the cerebellar
nuclei
o Connectivity patterns the same as cerebellar
nuclei

Receive input from the
flocculonodular lobe and from the
vestibular labyrinth
Project to various motor nuclei and
originate the vestibulospinal tracts
Cerebellar Peduncles
Form walls of the fourth ventricle
Inferior Cerebellar Peduncle
o Restiform Body (spinocerebellar fibers)
o “Ropelike Body”
o Justirestiform (vestibular cerebellar fibers)

Middle Cerebellar Peduncle
o Brachium Pontis
o Massive connections to the pons

Superior Cerebellar Peduncle
o Brachium Conjunctivum
Anterior spinocerebellar fibers
Cerebellothalamic fibers
 Cerebellar Peduncles
Inferior cerebellar peduncle
o afferent fibers from the medulla, as well as efferents to the
vestibular nuclei. (Posterior spinocerebellar and
vestibulocerebellar)
o Mainly carry inputs

Middle cerebellar peduncle
o connect with pons, contain afferent fibers
o Mainly carry inputs

Superior cerebellar peduncle
o efferent fibers from the cerebellar nuclei, as well as some
afferents from the spinocerebellar tract
o connect with midbrain, contain mostly efferent fibers
o Mainly carry outputs
Cellular Anatomy: Histology
 Microanatomy of the Cerebellum
Unique circuits for temporal and spatial processing of
information (coordination of movement)
Excitatory output of deep cerebellar nuclei Influenced by;
o Excitatory inputs of afferent collaterals
o Inhibitory influences of efferent cells

Temporal processing through timing variances
Spatial processing through various body components pp.
442-443 Haines
 Cerebellar Cellular Anatomy
Three Cell Layers
o Molecular Layer
o Purkinje Cell Layer
o Granule Cell Layer
 Neuronal Cell Types
Purkinje
Granule
Basket
Stellate
Golgi
 Neuronal Cell Types
Purkinje
Granule
Basket
Stellate
Golgi
 Purkinje Cell Layer
Purkinje Cells
o Extensive dendritic tree
Dendrites extend only to
molecular layer
Numerous spines
o Axons synapse with the deep
cerebellar nuclei
Axons of this type are the only
ones that leave the cerebellar
cortex
o Modify the output of the cerebellum
o GABA is neurotransmitter – inhibitory

Purkinje Cells are the ONLY
output cells for the
cerebellar cortex
 Granule Cells
Axons of Granule cells
project to the folia where
they bifurcate and form the
parallel fibers
Higher density of parallel
fibers relative to one Purkinje
cell
Excitatory synapses with
Purkinje cells
 Basket Cells
Found in the molecular
layer
Dendrites extend into
superficial molecular layer
and receive excitatory
input from parallel fibers
Axons extend across folia
(perpendicular to parallel
fibers) and send collateral
branch to Purkinjes
o Inhibitory
 Stellate Cells
Found in Molecular Layer
Axons extend across the
folia perpendicular to
parallel fibers
o Stellate cells receive excitatory input
from parallel fibers

Inhibitory synapses on
Purkinje
o Have discrete influence on dendrites
 Golgi Cells
Deep to the Purkinje cells
Dendrites extend to
molecular layer
o Excitatory connections with parallel
fibers

Axons enter granule layer
o Inhibitory to granule cells
 Cerebellar Glomerulus
Complex synaptic structure
Formed by
o Golgi cells axons
o Granular cell dendrites (RED)
o Mossy Fibers (Red below, Blue right)
 Cerebellar Cellular Fibers
4 fibers Types
o Mossy fibers (vast majority)
o Climbing fibers (olivocerebellar)
o Parallel fibers (terminals of
granule cells)
o fibers from :
Hypothalamus
Pontine raphe nuclei
Locus ceruleus
 Mossy Fibers
Excitatory afferent fibers that determine the output of
Purkinje Fibers.
Formed by efferent axons from
Pontine nuclei
Spinal cord
Vestibular nuclei
Reticular formation (Brainstem)

Synapse with granule cell dendrites
Make excitatory connections within glomeruli
1 mossy fiber connects to 600 granule cells which in turns
connect to greater than 5000 Purkinje cells
Mossy Fibers
 Climbing Fibers
Formed by afferent axons from
Inferior olivary nucleus (in medulla)
Olivary nuclei act as a major staging area for motor and sensory information
entering the cerebellum
Enter through inferior cerebellar peduncle

Synapse with purkinje cell dendrites
Collateral branches make excitatory connections deep
cerebellar nuclei
o Slow firing rate, strong enough to initiate action potential
o Open Calcium channels affecting metabolism of Purkinje cell
Mechanism that is responsible for motor learning.

1 climbing fiber can connect to as many as 300 Purkinje
cells
Climbing Fibers
 Cerebellar Circuits
Mossy fibers influence cerebellar output via two pathways:
o a direct pathway to the cerebellar nuclei
o a less direct pathway through the cerebellar cortex.

Climbing fibers are thought to convey error signals to the Purkinje cells
Excitatory inputs from :
o Granule cells ( Parallel fibers)
o Mossy fibers
o Climbing Fibers
o Aminergic fibers

Inhibitory inputs from :
o Purkinje cells
o Stellate and basket cells
o Golgi cells
 Afferent-Efferent Communication
Inferior Olive serves as relay center for sensory information into
cerebellum
o Descending input via the cortex and spinal cord Error detection system,
Cerebellum analyzes the afferent information Compares planned movement
to sensory experiences and
Output from cerebellum via Purkinje cells signals for online adjustments
o Refinement of motor activities
of movements
Impairment to Purkinje cells and inferior olive
o Causes ataxia, loss of coordination, dysphagia, dysarthria
 Functional Divisions
Based on connections made within
CNS
Vestibulocerebellum
o Congruent with flocculonodular lobe and vermis

Spinocerebellum
Cerebrocerebellum
 Vestibulocerebellum
Functional name for the Flocculonodular lobe
Receives afferent input from:
o Vestibular Nuclei
o Vestibular apparatus
Projects to
o Vestibular nuclei
Output reaches LMNs via
o Vestibulospinal tract
Regulates equilibrium

Example: Person reaches for a book from a high shelf, vestibulocerebellum
provides anticipatory contraction of lower limb and back muscles to
maintain balance. If absent, the person would fall forward
 Vestibulocerebellum
Green Represent EFFERENT
FIBERS
Magenta Represent
AFFERENT FIBERS
Orange-Yellow Represent
Motor Tracts to Trunk and
Limbs Flocculonodular
Lobe
 Spinocerebellum
Functional name for the vermis and paravermal region
Receives input from:
o Spinal cord
o Vestibular nuclei
o Auditory and vestibular info from brainstem nuclei
Projects output to:
o Vestibular nuclei
o Reticular nuclei (via fastigial nucleus)
o Motor Cortex (via fastigial nucleus)
o Red Nucleus (via globose and emboliform nuclei)
Regulates gross limb movements
Example: Spinocerebellum coordinates the upper limb
movement as the person reaches for the book. Without this input
– the movement would be jerky and inaccurate.
 Spinocerebellum
Magenta Represent AFFERENT
FIBERS from the
spinocerebellar tracts
Orange-Yellow Represent
Descending Tract Fibers
Green Represents output to
cerebellar cortex
 Cerebrocerebellum
(Pontocerebellum)
Functional name for the lateral cerebellum
Receives input from:
o Cerebral cortex (via pontine nuclei)
Projects output to:
o Motor and premotor cortices (via dentate nucleus and motor thalamus)
o Red Nucleus
Extends to LMNs via
o Lateral corticospinal tract
o Corticobulbar tract
o Rubrospinal tract
Regulates distal limb voluntary movements
Example: Cerebrocerebellum would coordinate the finger and thumb
movements necessary to grasp the book.
From Lundy-Ekman L. Neuroscience: Fundamentals for Rehabilitation, 3rd Ed.
Saunders Elsevier (2007), p. 263.
Cerebellar Vasculature
Branches of Basilar and Vertebral Arteries

SCA – Superior Cerebellar Artery

AICA – Anterior Inferior Cerebellar Artery

PICA – Posterior Inferior Cerebellar Artery
 Superior Cerebellar A.
Supplies
o Middle Cerebellar Peduncle
o Superior Cerebellar Peduncle
o Deep Cerebellar Nuclei
o Cerebellar White Matter

Infarction Causes:
o Limb and Gait Ataxia
o Abnormal saccades
o Nystagmus
Anterior Inferior Cerebellar Artery
Supplies
o Medulla and Pons
o Inferior Middle
peduncle
o Inferior Peduncle
o Flocculus
o Vermis
o Inferior Cerbellar
Cortex

Infarctions Cause
o Limb and gait ataxia
Posterior Inferior Cerebellar Artery
Supply
o Dorsolateral Medulla
o Inferior/Posterior Vermis
o Inferolateral surface of
cerebellum
o Dentate Nucleus

Infarctions cause
o Rotatory dizziness
o Nausea, vomiting,
imbalance, nystagmus
 Cerebellum Clinical Disorders
Lesions of Cerebellum affect the
ipsilateral side of the body
Signs of Cerebellar Dysfunction
o Ataxia/Ataxic Gait
o Nystagmus
o Dysdiadochokinesia
o Dysmetria
o Decomposition of Movement
o “Intentional tremor”
 Ataxia
Area Involved: Any lesion causes ataxia
Ataxia is voluntary, normal-strength, jerky, and inaccurate movements
Vermal and flocculonodular lesions lead to truncal ataxia
Paravermal lesions result in gait and limb ataxia
Lateral cerebellar lesions cause hand ataxia
Testing for speed and accuracy
Finger to finger or finger to nose

Demonstrating intentional tremor
 Vestibulocerebellar Lesions
Signs
o Ataxic Gait
Patient will fall toward side of the lesion
Cerebellar Gait (http://www.youtube.com/watch?v=eBvzFkcvScg)
o Nystagmus
o Vertigo
o Emesis
 Spinocerebellar/Cerebrocerebellar Lesions
Dysdiadochokinesia – loss of timing between agonist and antagonist
o Cannot perform rapid alternating movements
o Sequence of individual muscle contraction is impaired

Dysmetria – performance deteriorates as the motor act progresses
o Different than intention tremor

Hypermetria – forceful rebound of limb
Decomposition – performance of motor activity by moving only one
joint at a time because of an inability to control the entire movement
o Helps improve movement
o Ataxia – disruption in the precision of motor acts
 Videos
Abnormal Coordination Exam ;
o Hand Rapid Alternating Movements Dysdiadochokinesia
o http://www.youtube.com/watch?v=ylcWsoBOGzk

Dysmetria
o http://www.youtube.com/watch?v=jnQcKAYNuyk

Abnormal Coordination Exam ; Finger-to-nose
o http://www.youtube.com/watch?v=-dFMisBl1aM
 Comparison of basal ganglia and
cerebellum.

Assignment 5

Spinocerebellar Sensory input
 Comparison of lesions in basal ganglia
versus cerebellum.

Assignment 5 Basal ganglia Cerebellum
o Resting tremor o Intention tremor
o Bradykinesia or hypokinesia o Normal velocity of movement
(reduced amplitude of (but patients tend to slow down
movement) as a strategy to be accurate)
o Hyperkinesia o No hyperkinesia
o Rigidity o Hypotonia
o No ataxia o Ataxia
o Secondary disequilibrium o Loss of equilibirum
o No nystagmus o Nystagmus
 Clinical Case
A 47 year old woman is seeing a physical therapist for an initial
examination. Her primary complaint is of increasing right sided
clumsiness and shaking. She reports that the onset of these symptoms
has been gradual and began approximately 4 months ago.
Examination findings reveal the following:
o Normal somatosensation, autonomic function, and muscle strength t/o
o Coordination normal left upper and lower extremity
o Right side – rapid alternating movements are slow and uncoordinated, intention tremor occurs during
finger to nose and heel to shin tests.
o Right dysmetria on finger-to –nose test.
o Abnormal involuntary eye movements.
 Question 1
What is the location of the lesion (structure and which side)?