1 / 63

MOTOR SYSTEMS REVIEW Dr. G. R. Leichnetz

MOTOR SYSTEMS REVIEW Dr. G. R. Leichnetz. Pyramidal System. A representation of the body’s musculature is somatotopically-organized on the precentral gyrus and paracentral lobule, known as the motor homunculus .

dschuller
Télécharger la présentation

MOTOR SYSTEMS REVIEW Dr. G. R. Leichnetz

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. MOTOR SYSTEMS REVIEW Dr. G. R. Leichnetz

  2. Pyramidal System

  3. A representation of the body’s musculature is somatotopically-organized on the precentral gyrus and paracentral lobule, known as the motorhomunculus. The corticospinal tractoriginates from the dorsolateral precentral gyrus (arm/hand region) and paracentral lobule (leg). The corticobulbar tract originates from the ventrolateral precentral gyrus (head). Lower extremity Upper extremity Precentral Gyrus Origin of Corticospinal Tract (body) Paracentral lobule Head Origin of Corticobulbar Tract (head) Motor Homunculus

  4. Motor cortex, layer V The corticospinal (pyramidal) tract axons (upper motor neurons) originate in lamina V of the motor cortex and descend thru the internal capsule and brainstem (crus cerebri, basilar pons, medullary pyramid) to the caudal medulla where 90% or more cross in the pyramidal decussation to the opposite side of the spinal cord (then called the lateral corticospinal tract). A few corticospinals remain on the same side (ant. corticospinal tract) but cross at the level of termination. Crus cerebri, midbrain Basilar pons Medullary pyramid Pyramidal decussation Lateral corticospinal tract Anterior corticospinal tract

  5. The lateral corticospinal tract is somatotopically-organized and is the largest tract in the dorsolateral quadrant of the lateral funiculus, with sacral most lateral and cervical most medial. Lateral corticospinal tract C Kahn et al, Correlative Neurosurgery

  6. Head Region, VL Precentral gyrus The corticobulbar tract originates from lamina V large pyramidal neurons in the head region of the motor cortex (ventrolateral precentral gyrus), and descends into the brainstem, projecting bilaterally to all cranial nerve motor nuclei. Corticobulbar Tract (genu) III IV Cranial nerve motor nuclei Most corticobulbars terminate on interneurons in the reticular formation near cranial nerve motor nuclei, but some go directly to lower motor neurons within the motor nuclei. VI V NA VII XII

  7. Lesion of Corticobulbar Tract Corticobulbar tract lesion Corticobulbars to facial nucleus are unique. Lower half of the FN only receives crossed innervation.

  8. Corticobulbar innervation of the hypoglossal nucleus is primarily crossed. Corticobulbar tract lesion (UMN lesion) leads to contralateral paralysis of tongue; tongue deviated contralaterally. Hypoglossal nucleus or XIIth nerve lesion (LMN lesion) leads to ipsilateral paralysis of tongue; tongue deviated ipsilaterally. Corticobulbar tract lesion Hypoglossal nerve lesion Tongue deviates toward the paralyzed side

  9. Pyramidal Lesions

  10. Cortical vascular infarct involving the precentral gyrus (arm & head regions) and Broca’s speech area (middle cerebral artery).

  11. Capsular hemiplegia- involving genu (corticobulbars) and post. limb (corticospinals) of the internal capsule (middle cerebral artery).

  12. Weber’s Syndrome (Alternating Oculomotor Hemiplegia) involving crus cerebri of the midbrain (corticospinals and corticobulbars) and oculomotor nerve (branches of post. cerebral artery) Ipsilateral exotropia, ptosis, mydriasis (pupillary dilatation) with contralateral spastic hemiplegia (positive Babinski).

  13. Alternating abducent hemiplegia involving the basilar pons (corticospinals) and abducens nerve (br.’s of basilar artery) Ipsilateral esotropia with contralateral spastic hemiplegia.

  14. Medial Medullary Syndrome- Alternating hypoglossal hemiplegia involving the medullary pyramid (corticospinals) and hypoglossal nerve (anterior spinal artery). Medial lemniscus also involved. Ipsilateral tongue paralysis (tongue deviates to side of lesion) with contralateral hemiplegia. Contralateral loss of conscious proprioception, vibratory sense.

  15. Brown-Sequard Syndrome (Spinal Cord Hemisection) Produces ipsilateral spastic paralysis (lateral corticospinal tract lesion) with ipsilateral loss of conscious proprioception (dorsal column lesion), and contralateral loss of pain and temp. (lateral spinothalamic tract lesion) FG CST LSTT

  16. Amyotrophic Lateral Sclerosis (ALS) (Lou Gehrig’s Disease) Affects both upper and lower motor neurons Demyelinization (sclerosis) of the lateral corticospinal tract. Twitches (fasciculations), uncontrolled small discharges, and atrophy occur in muscle groups as motor neurons in the brainstem and spinal cord degenerate. Slurred speech, difficulty swallowing. No sensory impairment. No cognitive or memory impairment.

  17. Poliomyelitis (LMN lesion of the anterior horn motor neurons of the spinal cord) produces an ipsilateral flaccid paralysis with hypotonia, hyporeflexia and atrophy.

  18. Oculomotor System

  19. Types of Eye Movements Conjugate Vestibulo-ocular (VOR) Saccades- voluntary (FEF) and reflexive (SC) Smooth Pursuit- tracking Optokinetic- moving visual scene Disconjugate Convergence- “near response”

  20. Vestibulo-ocular projections to the oculomotor, trochlear, and abducens nuclei coordinate reflexive eye movements that compensate for head movements (to maintain fixation). Vestibulo-ocular Reflex (VOR) III IV Medial longitudinal fasciculus Vestibular complex VI

  21. Saccadic Eye Movements Voluntary saccadic eye movements are initiated in the frontal eye field. Reflexive saccadic eye movements are initiated in the superior colliculus. SC SC

  22. The intermediate and deep (motor) layers of the SC are in registry with the visual map in the superficial layer. There is a retinotopicmap of the visual world on the surface of the SC S I The intermediate layer is integrative; receives input from the FEF, cerebellum & basal ganglia, affecting motor output in deep layer. The deep layer is “motor” and is in registry with the visual map in the superficial layer. D When the SC initiates a reflexive saccade to look at an object, it can precisely target the location of the object in the visual world, so it can initiate an eye movement of appropriate amplitude and direction to bring the image onto the fovea of the retina.

  23. The FEF and SC project to preoculomotor centers in the brainstem reticular formation. The preoculomotor centers for vertical saccades are located in the rostral midbrain reticular formation (riMLF, downward; INC, upward), and for horizontal saccades in the medial pontine reticular formation (PPRF). Vertical Saccades IV III VI PPRF Horizontal Saccades

  24. Premotor centers for vertical saccades: riMLF- downward (lesion results in downgaze paralysis) INC- upward (lesion results in upgaze paralysis) Subthalamic Nucleus Substantia Nigra

  25. Horizontal Gaze Center: PPRF Abducens Nucleus The center for horizontal saccades (PPRF) is located in the medial pontine reticular formation at the level of the abducens nucleus. It contains premotor neurons that project to lateral rectus motor neurons in the abducens nucleus, and also projects to the cervical spinal cord for “gaze” (eye movement + head movement). Thus a lesion in PPRF results in an ipsilateral paralysis of conjugate horizontal gaze.

  26. Smooth Pursuit System Smooth pursuit eye movements are slow eye movements used to follow a moving object across the visual field. To maintain fixation, the eyes must move at the same speed as the visual target (eye movement matches target velocity). Therefore, the pursuit system involves seeing the object (visual cortex), analyzing its motion (pre-occipital cortex, area MT), and orchestrating eye movements (cerebellum) that are the same velocity as the target.

  27. Smooth Pursuit Pathway Visual Cortex to MT Visual Area (V5) to DLPN to “oculomotor part” of the posterior lobe vermis Lesion of these structures can result in pursuit deficits Visual Cortex Oculomotor Vermis Oculomotor vermis DLPN Dorsolateral pontine nucleus Posterior lobe

  28. Optokinetic System When the visual scene is moving (eg. riding on a train) to maintain fixation on an object (eg. following telephone poles) produces oscillating eye movements which consist of a slow component that follows the object and then a fast component where eyes snap back to attach to the next pole. Produces optokinetic eye movements, similar to nystagmus, called optokinetic nystagmus, OKN. The neural network for these eye movements involves the pretectum (receives visual input from the retina), which projects to the reticulotegmental nucleus (NRTP) of the pons, which then relays the information to the cerebellum (flocculonodular lobe).

  29. Optokinetic Pathway Retina and/or visual cortex to pretectal area to nucleus reticularis tegmenti pontis (NRTP) to flocculonodular cortex Lesion of these structures can produce OKN deficits. Visual cortex Retina Flocculus Flocculonodular lobe

  30. Vergence Eye Movements Vergence eye movements are the only disjunctive type of eye movement. In convergence, both medial rectus muscles contract. The pathway subserving convergence is not well known. But what is known is that the neural pathway reaches the two medial rectus cell groups in the oculomotor nucleus w/o going through the MLF (convergence is preserved in an MLF lesion, ie. INO). Convergence is part of the “nearresponse,” ie. focussing on a near object, involves: convergence accommodation (lens thickening) pupillary constriction

  31. Oculomotor Lesions

  32. Oculomotor (IIIrd) Nerve Palsy, left eye Ptosis right left Mydriasis Exotropia From: Fix, High-Yield Neuroanatomy With lesion of the left oculomotor nerve (C.N. III), the left eye is abducted (due to unopposed action of the lateral rectus). There is ipsilateral ptosis (paralysis of levator palpebrae) and the ipsilateral pupil is dilated (mydriasis; disruption of parasymp. fibers to constrictor pupillae).

  33. Abducens (Sixth) Nerve Palsy, right eye right left Ipsilateral eye does not abduct From: Fix, High-Yield Neuroanatomy Lesion of the right abducens nerve (C.N. VI) results in paralysis of the right lateral rectus muscle. When looking to the right, the right eye will not abduct. Esotropia.

  34. Abducens Nucleus Lesion Cannot abduct the ipsilateral eye or adduct the contralateral eye Right Left Lesion of abducensnucleus produces ipsilateral paralysis of conjugate horizontal eye movements (cannot abduct ipsilateral eye due to lesion of lateral rectus motoneurons, and cannot adduct contralateral eye due to lesion of internuclear neurons that project to contralateral medial rectus motor neurons)

  35. MLF Lesion: right MLF Ipsilateral eye will not adduct. Right Right Left Abducens internuclear neurons project thru MLF to contralateral medial rectus motor neurons Lesion of MLF produces internuclear ophthalmoplegia, INO) cannot adduct eye ipsilateral to MLF lesion due to interruption of internuclear axons, but medial rectus will contract with convergence)

  36. MLF Lesion: Internuclear Ophthalmoplegia, right eye Ipsilateral eye does not adduct right left Fix Lesion of the right MLF disrupts axons of internuclear neurons whose cell bodies are located in the abducens nucleus and which project to the right medial rectus cell group of the oculomotor nucleus. On looking to the left, the ipsilateral eye (on the lesioned side) will not adduct on attempted conjugate horizontal eye movement to the opposite side.. But since the medial rectus cell group itself is intact, the ophthalmologist can get adduction in convergence. Lesion of the MLF also produces nystagmus (disrupts VOR).

  37. PPRF Lesion A lesion of the paramedian pontine reticular formation produces an ipsilateral paralysis of conjugate horizontal gaze. Ipsilateral conjugate horizontalgaze paralysis

  38. Frontal Eye Field Lesion on right right left From: Fix, High-Yield Neuroanatomy Lesion of the frontal eye field (area 8) on the right results in a paralysis of conjugate eye movements to the left. The eyes are deviated to the right (toward side of lesion). The FEF lesion disrupts projections to contralateral PPRF, resulting in a contralateral paralysis of conjugate horizontal gaze

  39. Cerebellum

  40. Cerebellum: Three Lobes Anterior Lobe- “paleocerebellum” proprioception Posterior Lobe- “neocerebellum” cortical (receives input from cortex via basilar pons) Flocculonodular Lobe- “archicerebellum” vestibular

  41. Cerebellar Afferents: Spinocerebellars Cuneocerebellars Pontocerebellars Vestibulocerebellars Olivocerebellars All of these inputs enter the cerebellum thru the inferior & middle cerebellar peduncles. Anterior lobe Basilar pontine nuclei Posterior lobe Vestibular complex Flocculo-Nodular lobe Accessory. (Lat.) Cuneate nucleus Inferior olivary nucleus Nucleus dorsalis

  42. All inputs, except olivocerebellars, terminate as “mossy fibers” on granule cells. Olivocerebellars terminate as “climbing fibers” directly on Purkinje cells. Purkinge cells project to deep cerebellar nuclei

  43. Purkinje cells of the cerebellar cortex project to deep cerebellar nuclei. E G F D D E F G

  44. Cerebellar efferents originate in the deep cerebellar nuclei. The deep cerebellar nuclei (dentate, globose, emboliform nuclei) project thru the superior cerebellar peduncle to contralateral red nucleus and VL nucleus of the thalamus. After the superior cerebellar peduncle decussates, there is a small contingent of cerebellar efferents that descend to “precerebellar nuclei” like the inferior olivary nucleus for feedback. Cerebellar Efferents To contralateral red nucleus and VL thalamus Decussation of superior cerebellar peduncle Deep cerebellar nuclei

  45. Cerebellar Lesions: deficits expressed ipsilaterally Ataxia- tendency to fall toward side of lesion IntentionTremor (Action Tremor) Dysdiadokinesia- inability to produce alternating antagonistic actions Past-pointing Nystagmus- flocculonodular lobe lesion

  46. Basal Ganglia

  47. Caudate nucleus The basal ganglia include: Caudate Putamen Globus pallidus Subthalamic nucleus Substantia nigra Striatum Subthalamic nucleus Putamen Globus pallidus Substantia nigra

  48. Striatum: Caudate and Putamen The striatum is organized into subsectors, the striosomes and matrix, that have differential connections. Caudate Nucleus Striosomes Matrix Putamen Haines, Fundamental Neuroscience D1 Dopaminergic receptors predominate in the striosomes; D2 receptors in the matrix From Parent, Carpenter’s Human Neuroanatomy

  49. Striatal Afferents Cortex There are three principal sources of afferents to the striatum (green): Corticostriates(glutamatergic, excitatory) Thalamostriates(glutamatergic, excitatory) Nigrostriates (dopaminergic) CM/Pf Intralaminar complex, thalamus Substantia nigra From Haines, Fundamental Neuroscience

  50. The principal efferents of the striatum (red) are: Striatopallidals- “striosomes” to internal segment of the globus pallidus (GPi) & “matrix” to external segment (GPe) Striatonigrals“striosomes” to pars compacta (SNc) & “matrix” to pars reticulata (SNr) of substantia nigra All of the efferents of the caudate and putamen are GABA-ergic (inhibitory). Striatal Efferents From Haines, Fundamental Neuroscience

More Related