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Bilateral Internuclear Ophthalmoplegia

941-2. Bilateral Internuclear Ophthalmoplegia. Eye Movements. Bilateral Internuclear Ophthalmoplegia Acquired Pendular Nystagmus Lid Nystagmus Upbeat Nystagmus. Clinical Features.

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Bilateral Internuclear Ophthalmoplegia

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  1. 941-2 Bilateral Internuclear Ophthalmoplegia

  2. Eye Movements Bilateral Internuclear Ophthalmoplegia Acquired Pendular Nystagmus Lid Nystagmus Upbeat Nystagmus

  3. Clinical Features Medial rectus muscle weakness ipsilateral to the side of the lesion with paresis of adduction or adduction lag. Abducting nystagmus of the eye contralateral to the lesion – Dissociated nystagmus

  4. Clinical Features Normal convergence Skew deviation – hypertropia on the side of the lesion Dissociated vertical nystagmus – downbeat with greater torsional component in the contralateral eye

  5. Bilateral INO Additional Signs: Gaze evoked vertical nystagmus Impaired vertical pursuit Decreased vertical vestibular response Small amplitude saccadic intrusions suggesting involvement of the brainstem adjacent to the MLF

  6. Pathogenesis of Certain Signs in Internuclear Ophthalmoplegia Ocular Motor Possible Deficit Pathophysiologic Substrate Ipsilateral hypertropia skew Vertical-gaze evoked nystagmus Vertical vestibular and pursuit movements impaired Otolith imbalance Vertical saccades bring eye to target but vertical eye position signal is inadequate Bilateral interruption MLF axons carrying vertical vestibular and smooth pursuit signals

  7. INO Weakness of adduction is due to impaired conduction in axons from the abducens internuclear neurons which project to the medial rectus motor neurons in the contralateral oculomotor (third nerve) nucleus.

  8. INO Adduction weakness is most evident during saccades and adduction lag is brought out by asking the patient to look all the way to the right and all the way to the left (i.e. make large saccades).

  9. INO The speed of the adducting eye depends on a strong agonist contraction. The adducting saccade may be slow and hypometric.

  10. INO In the abducting eye, abducting saccades are hypometric with centripetal drifts of the eye and slowing. A series of small saccades and drifts have the clinical appearance of abducting nystagmus - dissociated nystagmus.

  11. INO Dissociated nystagmus may be due to: impaired ability to inhibit the affected medial rectus or Dissociated nystagmus reflects the brain’s attempts to compensate for the adduction weakness.

  12. Etiology Multiple sclerosis(commonly bilateral) Brainstem infarction (commonly unilateral), including vasculitis, complication of arteriography and hemorrhage Brainstem and fourth ventricular tumors

  13. Etiology Arnold-Chiari malformation and associated hydrocephalus Infection: bacterial, viral and other forms of meningoencephalitis and AIDS

  14. Etiology Wernicke’s encephalopathy Metabolic disorders: hepatic encephalopathy Drug intoxications: phenothiazines, tricyclic antidepressants, narcotics, propranolol, lithium, barbiturates.

  15. Pendular Horizontal Oscillations Relatively high frequency oscillations that dampen after a blink PHO are partially suppressed following a saccade and on convergence.

  16. Upbeat Nystagmus Primary position upbeat nystagmus is attributable to a lesion(s) in the region of the Nucleus intercalatus Nucleus of Roller

  17. Clinical Features of Acquired Pendular Nystagmus (APV) May have horizontal, vertical and torsional components; their amplitude and phase relationship determines the trajectory of the nystagmus in each eye Phase shift between the eyes is common (horizontally and torsionally; seldom vertically) – may reach 180 degrees, so that the nystagmus becomes convergent-divergent or cyclovergent

  18. Clinical Features of APN Amplitudes often differ, and nystagmus may appear monocular Trajectories may be conjugate, but more often are dissimilar Oscillations sometimes suppress momentarily in the wake of a saccade

  19. Clinical Features of APN In Association with Demyelinating Diseases Frequency 2-8 Hz (typically 34-4Hz) Generally greater amplitude in the eye with poorer vision Internuclear ophthalmoplegia commonly associated May have an associated upbeat component

  20. Clinical Features of APN Syndrome of Oculopalatal Tremor Frequency 1-3 Hz (typically 2 Hz) May be vertical (with bilateral lesions) or disconjugate vertical- torsional Accentuated by eyelid closure Movements of palate and other branchial muscles may be synchronized

  21. APN: Whipple’s Disease Whipple’s Disease Frequency typically about 1 Hz Usually convergence-divergence, occasionally vertical; sometimes with associated oscillatory movements of the jaw, face or limbs (oculomasticatory myorhythmia)

  22. APN: Whipple’s Disease Vertical gaze palsy similar to the clinical picture of progressive supranuclear palsy is usually also present Leigh RJ, Zee DS. The Neurology of Eye Movements 4th Edition. Oxford University Press, New York 2006 with permission

  23. http://www.library.med.utah.edu/NOVEL

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