Student Cerebellum and BG NS II 2024 PDF

Summary

This document covers the basal ganglia and cerebellum, including types of movement disorders like Parkinson's and Huntington's. It details the anatomy, connections, and functions of these brain structures, and their role in motor control, along with clinical connections and medical interventions. Excellent reference material on basal ganglia and cerebellum.

Full Transcript

The Basal
Ganglia
and
Cerebellu
m
Remember
the big
picture…
Basal
Ganglia
Basal =
Ganglia =

Caudate + Putamen = Striatum
Globus Pallidus (internal and external)
Subthalamic Nucleus (STN)
Substantia nigra =

Thalamus
Inputs to Basal Ganglia

Cerebral Cortex
Substantia Nigra of Midbrain
Outputs:

Superior colliculus
Thalamus
A) Direct Pathway
B) Indirect Pathway
BOX 18B Basal Ganglia Loops and Non-Motor Brain Functions
2 Major
Hypokinetic
types of
BG
Disorders Hyperkinetic
General Movement Problems
Associated with Basal Ganglia
Movement Disorders

Tremor Tics
Chorea Ballismus
Dystonia Dyskinesia
Hemiballismus Akinesia
Athetosis Bradykinesia
Hyperkinetic Disorders
Hyperkinetic Disorders:
TREMOR: involuntary movements involving both the agonist and
antagonist resulting in rhythmic or alternating movements of a
joint
Resting tremor
Associated with Parkinson’s Disease

VS. Intention tremor – caused by cerebellar lesion
Occurs with action, particularly reaching
Hyperkinetic Disorders:
DYSTONIA: sustained involuntary contractions of agonist and
antagonist muscles of a particular body segment
Causes abnormal posturing or twisting movements
Dystonia video
Hyperkinetic Disorders:
ATHETOSIS: slow, involuntary, writhing, twisting, “wormlike”
movements
Frequently more in distal UEs
Athetosis video
Hyperkinetic Disorders:
HEMIBALLISMUS: large amplitude sudden, violent, flailing motions
of the arm and leg of one side of the body
Primarily axial and proximal musculature
Hemiballismus video
Hyperkinetic Disorders:
TICS: abrupt, repetitive movements or vocalizations
Tourette’s Disorder
Tourette's video
Hyperkinetic Disorders:
CHOREA: involuntary, rapid, irregular, jerky movements
Involves multiple joints
Most apparent in UEs
Hyperkinetic Disorders:
Huntington’s Disease
aka Huntington’s Chorea
Signs: Dementia and CHOREA
Hereditary and progressive
Onset 40-50 years
Death approximately 15 years after onset
Treatment: anticonvulsants, antipsychotics
Chorea video
 Figure 19-15 Horizontal sections of
cortex illustrating (a) normal size of
caudate nucleus in people without HD
and (b) atrophy of the head of the
caudate nucleus and enlargement of
the anterior horn of the lateral ventricle
as manifested in people with
Huntington's disease (HD).
Medical Management of HD
Hereditary condition
Presents typically at ages 35-55
Progression of symptoms from hyperkinetic to eventual rigidity at
end of life; includes changes in affect and cognition, with
eventual dementia
Treatment:
Genetic counseling
Pharmacological once unwanted movements begin
Examination and Intervention in HD
United Huntington's Disease Rating Scale (UHDRS)
Assessment of activities of daily living
Tests of strength, tone, and gait
Mental state and psychological status assessment

People with HD are underserved in rehabilitation
Hypokinetic Disorders
Hypokinetic Disorders
AKINESIA: Inability to initiate movement; associated with fixed
postures; freezing phenomenon
BRADYKINESIA: decreased amplitude and velocity of voluntary
movement
RIGIDITY: increase in muscle tone causing resistance to PROM
Lead pipe: uniform, constant resistance
Cogwheel: series of brief catches
Hypokinetic Disorder –
Parkinson’s Disease
Incidence
1 in 100 people over age 70
Affects men and women equally
Typically develops after age 65
10-15% diagnosed before age 50
Etiology
Cause is unknown
Strong support for environmental cause (more prevalent in industrial
and agricultural countries)
Genetic link in people diagnosed before 50
Parkinson’s Disease
Pathology
Death of dopamine-producing cells in substantia nigra
Death of cells occurs long before onset of symptoms
80% of dopamine-producing cells die before signs of disease
appear
Figure 19-12 Substantia nigra of the midbrain. In the normal condition, the
substantia nigra pars compacta is seen as a black pigmented area. In the
midbrain of people with PD, there is a loss of the black pigmented cells in
substantia nigra pars compacta and, therefore, a loss of dopamine (DA)
production.
Hypokinetic Disorder –
Parkinson’s Disease
Cardinal Signs:
Tremor PD tremor
Rigidity
Cogwheel
Lead pipe
Akinesia
Bradykinesia
Freezing
Postural Instability
Loss of postural reflexes
Parkinson’s Disease
Other Symptoms
Forward flexed posture
Masked face
Decreased volume of speech
Increased speed of speech
Monotone speech
Festinating gait Demonstration of gait
Decreased arm swing
Difficulty with initiation and termination
Micrographia
Autonomic
Parkinson’s Disease
Medical Management
Medication
Levodopa – helps balance dopaminergic and cholinergic
neurons
Surgery
Pallidotomy
Deep Brain Stimulation (DBS)
Parkinson’s Disease
Medical Management - Medication
Levodopa – helps balance dopaminergic and cholinergic neurons
by replacing dopamine
Helps reduce signs of the disease
Challenges with Levodopa
Side effects: psychosis, hallucinations, DYSKINESIA or
DYSTONIA
On/Off phenomenon: periods of normal movement and periods
of immobility
https://youtu.be/3-wrNhyVTNE
May relate to time of day or time of dosage
Tolerance: over time, the response to L-dopa decreases
Parkinson’s Disease
Medical Management - DBS
Deep Brain Stimulation
(DBS)
Implantation of electrodes
into BG
Location depends on
symptoms
Continuous high-frequency
e-stim inhibits firing of
overactive thalamic neurons
DBS on/off
Parkinson’s Disease
Subjective Measure
Parkinson’s Disease Questionnaire (PDQ-39)
Measures participation
8 domains
Mobility
ADLs
Emotions
Stigma
Social support
Cognition
Communication
Bodily discomfort
Cerebellu
m
Cerebellum – The Great
Comparator
ERROR CORRECTION

Integrates: executive commands + sensory feedback = moment-to-
moment adjustment of behavior

Outputs to circuits of UMNs

An organ of agility (movement of the mind and body)
Coordination of ongoing multi-jointed movement
Coordination of ongoing sequential cognitive processes
3 Basic Parts/Components of
Cerebellum
Component Anatomy Connections
Gray Matter
Cerebellar Folia
Cortex
Deep Nuclei Floor of 4th
ventricle
White Matter
Peduncles Middle (largest) Incoming from pons
Superior Outgoing
Inferior Incoming from spinal
cord and brainstem
Outgoing
Terminology Used to Discuss the Cerebellum

LOBES LONGITUDINAL ZONES FUNCTIONAL REGIONS
Flocculonodular Vermis Vestibulocerebellum
Anterior Intermediate/Paravermis Spinocerebellum
Posterior Lateral Pontocerebellum
 3 Major Functional Divisions
Division Anatomy Connections & Nuclei Function
Peduncles
Spinocerebellum Medial strip of Input from spinal Interposed Movements of
vermis and cord (through arms/legs
hemispheres inferior peduncle) Some cranial
movement
Cerebrocerebellu Lateral To/from cerebral Dentate Skilled
m hemispheres cortex (through movements of
superior and distal
middle peduncle) extremities,
especially when
there is a goal
directed plan
Vestibulocerebell Flocculus + Connects to Fastigial Calibrating and
um nodulus vestibular nuclei governing
in brainstem vestibular motor
(through inferior output
peduncle)
Cerebellar Circuitry: Inputs
From Cortex
Cortex -> Pons ->
Decussation -> Contralateral
Cerebellar Cortex and Nuclei
Therefore, cortex can only
communicate with
cerebellum indirectly
From Sensory System
From Brainstem
Inferior olive of medulla
Clinical Connections
Severity of cerebellar deficits may not reflect the magnitude of damage
Due to small and compact space
Difficult to determine location of a focal lesion
Cerebellar hemispheres are likely to become involved, even with
lesions of the vermis
FIGURE 19.9 Neurons and circuits of the cerebellum (Part 1)
FIGURE 19.10 Excitatory and inhibitory connections in the cerebellar cortex and deep cerebellar nuclei (Part 1)
FIGURE 19.10 Excitatory and inhibitory connections in the cerebellar cortex and deep cerebellar nuclei (Part 2)
Motor Learning and Plasticity
Works by modifying the strength of the inhibition of the
cortical inhibitory loop
Causes weakended input from the cerebellar cortex
Motor learning is a stronger input to the cerebellar deep
nuclei which allows the cerebellum to have more
influence over UMN circuits
Figure 19-9 Finger-to-nose test. (a)
The accuracy of performance of an
individual with an intact cerebellum. (b)
The dysmetria of an individual with
cerebellar dysfunction. The trajectory is
wavy instead of straight (dysmetria)
and is offset from the nose.
Clinical Connection:
Medulloblastoma
Highly malignant tumor occurring predominantly in children ages 4–8
Symptoms of listlessness, vomiting, headaches, and falling
Increased intracranial pressure causes papilledema
Clinical Connection:
Neocerebellar Syndrome
Most common encountered type of cerebellar disease in humans
Causes include cardiovascular pathology, tumors, multiple sclerosis and
degenerative diseases
Characterized by intention tremor, hypotonia, asthenia, asynergia, and
ataxia
Differentiating Cerebellar From
Somatosensory Ataxia
Not all ataxia is caused by cerebellar lesions.
To differentiate between somatosensory and cerebellar ataxia,
movement coordination should be compared with eyes open and eyes
closed.

Copyright © 2018 by Elsevier, Inc. All rights reserved. 54
Medical Intervention
In general intervention is complicated and prognosis of restoration of
normal function is poor
 Clinical Diagnoses

https://youtu.be/17ch1guvoLA (PD)

https://youtu.be/m6SxJUjJGlc (HD)
Bring it all together.
Motor control of the body
is primarily controlled by
cortical signals sent to
LMNs
This relationship is
modulated by the inputs
of the basal ganglia and
cerebellum
Learning requires error
Questions?

Reflection.