1. Motor Systems Muscles and Lower Motor Neurons
Motor systems of the CNS
Pyramidal
Cerebellum
Extrapyramidal
Motor Disorders
Basal Ganglia Disorders:
Parkinson’s Disease
Huntington’s Disease
Tourette’s syndrome
2. “To move is all that mankind can do..for such the sole execution is muscle, whether in whispering a syllable or in felling a forest.” Charles Sherrington, 1924
3. Muscles Smooth muscles
Glands, arteries, digestive system
Striated muscles
Cardiac muscles
Skeletal muscles
4. Spinal Cord Motor Programs
Reflexes
Proprioceptors
Painful stimuli
Central Pattern Generators
5. Central pattern generators
6. Cortex Goal-directed behavior
Activation of many cortical areas
Parietal cortex, somatosensory, frontal cortex, visual cortex
Motor planning
Prefrontal cortex
Movement selection
Premotor and supplementary motor areas
Movement initiation
Primary motor cortex
Somatotopic organization
9. Primary Motor Cortex
10. Corticospinal tract�aka pyramidal system
11. Brainstem motor nuclei Reticular Formation
Reflexes (sneezing, coughing, vomiting)
Posture control
12. Major descending spinal tracts
14. Cerebellum� Motor sequencing
Motor learning
Ballistic movements
15. Damage to the cerebellum Jerky, erratic, uncoordinated movement (Ataxia)
Dysdiadochokinesis
Altered gait
Intension tremors
Nystagmus
16. Basal Ganglia�Extrapyramidal Motor system Caudate
Putamen
Globus pallidus
Subthalamus
Substantia Nigra
Modulation of motor control
Modulation of cognitive control
20. Brain circuits
21. Basal Ganglia- Thalamic- Cortical- Loops
22. Basal Ganglia- cortical loops Direct pathway: Excite cortex
Indirect pathway: Inhibit cortex
23. Two hypothesis regarding the direct and indirect pathways 1) Direct activates the desired motor program whereas the indirect inhibits unwanted motor programs
2) The direct and indirect act on the same motor program, allowing for greater control of movement
24. Dopamine modulates the basal ganglia Dopamine excites the direct pathway (via D1 receptors)
Dopamine inhibits the indirect pathway (via D2 receptors)
25. Consider what happens if there is an imbalance in direct/indirect pathway activation Overactivation of the direct pathway, or underactivation of the indirect pathway leads to excessive movements, or undesired movements
Overactivation of the indirect pathway or underactivation of the direct pathway leads to a poverty of movement
26. Basal Ganglia Disorders Parkinson’s syndrome
Hemiballismus
Huntington’s syndrome
Tourette’s syndrome
27. Motor disorder terms Akinesia
Difficulty in initiating willed movements
Hypokinesia
Paucity of movement
Bradykinesia
Slowness of movement
Dyskinesia
Dysfunctional movement
Hyperkinesia
Excessive movement
28. Parkinson’s Disease
29. Parkinson’s Disease 1817 James Parkinson “shaking palsy”
Akinesia and bradykinesia
Resting tremor
Muscle rigidity
Shuffling gait
Postural instability
Loss of facial muscle tone
31. Loss of DA cells in the substantia nigra
33. Basal Ganglia Dysfunction D1 DA receptors facilitate transmission of the direct pathway
D2 DA receptors reduce transmission of the indirect pathway
Underactive Direct: akinesia
Overactive Indirect: Bradykinesia
36. Lewy bodies
37. What causes the neuropathology? Genetic and environmental factors
Early onset (may be related more to genetic factors)
Late onset
38. The frozen addicts
39. Mitochondrial dysfunction and mishandling of abnormal proteins may be a common pathogenic event
41. Treatments�Historical Look 19th century-1960
Surgery
Motor cortex, spinal pathways, frontal lobotomy
1940s & 1950s
Pallidotomy, basal ganglia surgeries
Drug therapies
L-dopa
42. Treatments�Current Surgeries
Pallidotomies (internal)
Subthalamotomy
Thalamotomy (most effective for tremor)
Drug treatments
L-dopa
Deprenyl (MAO B inhibitor)
Tissue Transplantation
Adrenal tissue
Fetal tissue
Pig tissue (xenografts)
Co-administration of trophic factors
43. Basal Ganglia- Thalamic- Cortical- Loops
44. Deep Brain Stimulation
45. Treatments�Current Surgeries
Pallidotomies (internal)
Thalamotomy
Subthalamotomy
Drug treatments
L-dopa
Deprenyl (MAO B inhibitor)
Tissue Transplantation
Adrenal tissue
Fetal tissue
Pig tissue (xenografts)
Co-administration of trophic factors
47. Treatments�Current Surgeries
Pallidotomies (internal)
Thalamotomy
Subthalamotomy
Drug treatments
L-dopa
Deprenyl (MAO B inhibitor)
Tissue Transplantation
Adrenal tissue
Fetal tissue
Pig tissue (xenografts)
Co-administration of trophic factors
48. Freed paper discussion First prospective study comparing transplantation with a control
Issues of sham surgery
Measure symptom severity at 12 months
UPDRS
Schwab and England scale
Subjective global rating by patients
49. Freed paper (cont) Results
Improvement in UPDRS and Schwab & England scales, but only in younger Parkinson’s patients
50. Transplants reduced motor symptoms
51. Transplants increased striatal dopaminergic activity
52. Transplants established connections and became functional
53. Adverse side effects Dyskinesia developed in 15% of patients
54. Freed paper What would you do differently in this study?
Do you think that the adverse outcomes were too risky?
56. Success of transplants depend on many factors Age of fetal tissue
Amount of tissue
Placement of tissue
Suspension of fetal tissue
Age of patient
Difficulty creating a standardized procedure
57. Treatments�Current Surgeries
Pallidotomies (internal)
Thalamotomy
Subthalamotomy
Drug treatments
L-dopa
Deprenyl (MAO B inhibitor)
Tissue Transplantation
Adrenal tissue
Fetal tissue
Pig tissue (xenografts)
Co-administration of trophic factors
58. Treatments�Future Stem cells
Gene Therapies
59. DA neurons from embryonic stem cells in a non-human primate
60. Transplanted cells differentiate into dopaminergic neurons
61. Huntington’s Disease Symptoms become evident in 30s or 40s
Chorea
Eventual bradykinesia, immobility, and death
Cognitive impairments, dementia, psychiatric disorders (depression, anxiety, obsessive-compulsive disorder, psychosis)
62. Huntington’s disease Loss of GABA neurons in striatum
Reduces activity of indirect loop
Progression—more extensive damage and loss of movement
63. Huntington’s Neuropathology Here you can see the neuropathology, with loss of cells in the striatum ,as well as cortex, a bit. And widening of the lateral ventricles.Here you can see the neuropathology, with loss of cells in the striatum ,as well as cortex, a bit. And widening of the lateral ventricles.
64. Huntington’s disease Genetic
Dominant
Chromosome 4, multiple trinucleotide repeats (CAG) (protein: Huntingtin protein)
Longer the repeats, the earlier the symptoms
65. Huntingtin protein May alter glucose metabolism (Burke et al., 1996)
Huntingtin may facilitate the production and transport of BDNF, which is necessary for survival of neurons in the striatum
Animal studies show that altered huntingtin protein leads to apoptotic cell death
67. Nancy Wexler
Genetic Test to determine if the individual is a carrier of this mutation
Would you want to know?
68. Treatments No treatment to stop progression
DA antagonists may reduce symptoms early in the disorder
Environmental factors may delay onset and progression
69. Environmental-Gene interactions Animal studies show that environmental enrichment delays onset and progression
70. Tourette’s syndrome Motor tics
Simple
complex
Vocal tics
Simple
complex
72. Tourette Syndrome
73. “When I was nine-years old, an imp took up residence in me. One afternoon he prodded the left side of my face from the inside, causing my lips to purse and curl askew toward my squinting left eye. Without yet knowing why, I rapidly blinked and shrugged. I grunted. I threw back my head and squeaked while my fists smacked my bruised abdomen.”
74. Tourette’s syndrome First published account: 1825 Jean-Mark Itard
1885: George Albert Edward Brutus Gilles de la Tourette
Estimated 100,000 Americans with TS
Occurs 3-4 times more in males than females.
Onset usually in late childhood
Increased incidence of ADHD and OCD
76. Pathophysiology Imaging studies:
Reduction in volume and other abnormalities in basal ganglia
