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Superior Oblique Myokymia Presumed Due to Large Posterior Fossa Arteriovenous Malformation

Published online by Cambridge University Press:  05 August 2020

Laura Donaldson
Affiliation:
Department of Surgery, Division of Ophthalmology, Hamilton Regional Eye Institute, McMaster University, Hamilton, Ontario, Canada
Brian van Adel
Affiliation:
Division of Neurology, Neurosurgery, and Diagnostic Imaging, Hamilton General Hospital, McMaster University, Hamilton, Ontario, Canada
Amadeo R. Rodriguez*
Affiliation:
Department of Surgery, Division of Ophthalmology, Hamilton Regional Eye Institute, McMaster University, Hamilton, Ontario, Canada Department of Medicine, Division of Neurology, McMaster University, Hamilton, Ontario, Canada
*
Correspondence to: Amadeo Rodriguez, Hamilton Regional Eye Institute, 2757 King St E, Hamilton, ON L8G 4X3, Canada. Email: arodrig@mcmaster.ca
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Extract

A 26-year-old female presented with a complaint of intermittent oscillopsia and binocular vertical diplopia for the past 5 years. Over the past several months, she had noticed intermittent pulsatile tinnitus. She was otherwise healthy with no previous history of trauma and had no other visual or neurologic complaints. In Neuro-ophthalmology clinic, she was found to have 20/15 vision in both eyes with full ocular motility. There was a small exophoria in primary position and small esophoria in downgaze. Her slit lamp and fundus examinations were normal. During the assessment, the left eye was noted to undergo high-frequency, small amplitude incyclotorsional oscillations for a few seconds at a time (Video 1 in the supplementary material), which she was able to provoke by looking down. The diagnosis of superior oblique myokymia was made, and an MRI/MRA of the brain was requested.

Type
Neuroimaging Highlights
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press on behalf of The Canadian Journal of Neurological Sciences Inc.

A 26-year-old female presented with a complaint of intermittent oscillopsia and binocular vertical diplopia for the past 5 years. Over the past several months, she had noticed intermittent pulsatile tinnitus. She was otherwise healthy with no previous history of trauma and had no other visual or neurologic complaints. In Neuro-ophthalmology clinic, she was found to have 20/15 vision in both eyes with full ocular motility. There was a small exophoria in primary position and small esophoria in downgaze. Her slit lamp and fundus examinations were normal. During the assessment, the left eye was noted to undergo high-frequency, small amplitude incyclotorsional oscillations for a few seconds at a time (Video 1 in the supplementary material), which she was able to provoke by looking down. The diagnosis of superior oblique myokymia was made, and an MRI/MRA of the brain was requested.

MRI of the brain revealed a large cerebellar arteriovenous malformation (AVM) (Figure 1A, 1B). The nidus was located within the left cerebellar hemisphere, with feeding vessels appearing to arise mainly from the left vertebrobasilar system. Multiple interconnected vascular loops were present within the cerebellar hemispheres. Dilated, tortuous draining veins were present in the interpeduncular, ambient and prepontine cisterns, including vessels wrapping around the cerebral peduncles in the expected course of the trochlear nerve.

Figure 1: (A) Sagittal T2 and (B) axial fast imaging employing steady-state acquisition magnetic resonance images showing multiple, abnormal dilated vessels in the cerebellum and brainstem. Tortuous vessels are present surrounding the midbrain in the interpeduncular (black arrow) and ambient cistern (white arrow) along the course of the trochlear nerve. (C, D), (G, H): Digital subtraction angiography of the cerebral vessels. (C, D) A-P (C) and lateral (D) pre-embolization views showing filling from the left vertebral artery. A large cerebellar arteriovenous malformation (AVM) with a compact nidus in the left cerebellar hemisphere (white arrow) is present with complex venous drainage to the transverse sinuses (black arrow) and deep cerebral veins (white arrowhead). (E, F) Pre- (E) and post- (F) embolization MRI axial T2 sequences at the level of the pons and cerebellum. MRI 12 months post embolization shows a reduction in the size of the AVM nidus (white arrow) and less prominent draining veins. (G, H) Post-embolization (Onyx) anteroposterior (G) and lateral (H) angiograms of the AVM after selective injection of the left vertebral artery demonstrate a reduction in the overall size of the AVM nidus (white arrows) and the degree of AV shunting.

The patient underwent a diagnostic cerebral angiogram (Figure 1C, 1D), which showed a large compact AVM nidus measuring 6 cm in diameter within the left cerebellar hemisphere. Arterial supply was from the left and right posterior inferior cerebellar arteries, left anterior inferior cerebellar artery and left superior cerebellar artery. Multiple ecstatic and dilated veins drained the AVM to both transverse sinuses as well as reflux into the deep venous system via the left basal vein of Rosenthal. Multiple high-flow arteriovenous (AV) shunts were noted predominately within the left cerebellar hemisphere with multiple dilated, and tortuous cerebellar hemispheric draining veins with a pseudophlebitic pattern of the pial veins of the posterior cranial fossa suggestive of long-standing AV shunting and venous hypertension.

For symptomatic treatment, the patient was started on topical timolol 0.5% bid to the left eye, an off-label use. She reported a noticeable decrease in the frequency of her oscillopsia. Later, endovascular embolization of the AVM (Figure 1E–1H) was performed, resulting in significant improvement and allowing her to discontinue timolol post-operatively.

Superior oblique myokymia is a monocular condition that can occur in association with any structural compromise to the trochlear nerve including microvascular compression, Reference Fam, Scott, Forster and Kamel1,Reference Hashimoto, Ohtsuka, Suzuki, Minamida and Houkin2 trauma and brainstem neoplasms, though in many cases no underlying etiology can be identified. The reported success of timolol in treating this condition could relate to a reduction in ephatic transmission or decreased amplitude of vascular pulsations through blood pressure lowering. Reference Strupp, Dieterich, Brandt and Feil3 As in this case, definitive treatment consists of decompression of the affected trochlear nerve.

It has been suggested that neuroimaging may not be required for every case of superior oblique myokymia, but should be considered when there is non-response to topical therapy and certainly before planning for extra-ocular muscle surgery. Reference Zhang, Gilbert and Hunter4 In this case, it was the long-standing nature of her complaint and relatively severe presentation with frequent, bothersome episodes which prompted early referral for MRI.

Conflict of Interest

None.

Statement of authorship

LD wrote the manuscript; BV and ARR made revisions and approved the final version.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/cjn.2020.125.

References

Fam, MD, Scott, C, Forster, A, Kamel, MH. Microvascular decompression for superior oblique myokymia: case report. Br J Neurosurg. 2014;28(4):552–5.10.3109/02688697.2013.869551CrossRefGoogle ScholarPubMed
Hashimoto, M, Ohtsuka, K, Suzuki, Y, Minamida, Y, Houkin, K. Superior oblique myokymia caused by vascular compression. J Neuroophthalmol. 2004;24(3):237–9.10.1097/00041327-200409000-00012CrossRefGoogle ScholarPubMed
Strupp, M, Dieterich, M, Brandt, T, Feil, K. Therapy of vestibular paroxysmia, superior oblique myokymia, and ocular neuromyotonia. Curr Treat Options Neurol. 2016;18(7):34.10.1007/s11940-016-0417-2CrossRefGoogle ScholarPubMed
Zhang, M, Gilbert, A, Hunter, DG. Superior oblique myokymia. Surv Ophthalmol. 2018;63(4):507–17.10.1016/j.survophthal.2017.10.005CrossRefGoogle ScholarPubMed
Figure 0

Figure 1: (A) Sagittal T2 and (B) axial fast imaging employing steady-state acquisition magnetic resonance images showing multiple, abnormal dilated vessels in the cerebellum and brainstem. Tortuous vessels are present surrounding the midbrain in the interpeduncular (black arrow) and ambient cistern (white arrow) along the course of the trochlear nerve. (C, D), (G, H): Digital subtraction angiography of the cerebral vessels. (C, D) A-P (C) and lateral (D) pre-embolization views showing filling from the left vertebral artery. A large cerebellar arteriovenous malformation (AVM) with a compact nidus in the left cerebellar hemisphere (white arrow) is present with complex venous drainage to the transverse sinuses (black arrow) and deep cerebral veins (white arrowhead). (E, F) Pre- (E) and post- (F) embolization MRI axial T2 sequences at the level of the pons and cerebellum. MRI 12 months post embolization shows a reduction in the size of the AVM nidus (white arrow) and less prominent draining veins. (G, H) Post-embolization (Onyx) anteroposterior (G) and lateral (H) angiograms of the AVM after selective injection of the left vertebral artery demonstrate a reduction in the overall size of the AVM nidus (white arrows) and the degree of AV shunting.

Donaldson et al. supplementary material

Donaldson et al. supplementary material

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