Ocular Motor & Vestibular Features of the MLF Syndrome (Figures 1, 2, and 3)

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Identifier MLFsyndrome_LARP_vHIT_Figures_1-2-3
Title Ocular Motor & Vestibular Features of the MLF Syndrome (Figures 1, 2, and 3)
Creator Tony Brune, DO; Daniel R. Gold, DO
Affiliation (TB) Department of Neurology, The Johns Hopkins School of Medicine, Baltimore, Maryland; (DRG) Departments of Neurology, Ophthalmology, Neurosurgery, Otolaryngology - Head & Neck Surgery, Emergency Medicine, and Medicine, The Johns Hopkins School of Medicine, Baltimore, Maryland
Subject INO; Jerk Nystagmus; Torsional Nystagmus; Gaze-Evoked Nystagmus
Description This 61-year-old woman with HTN and DM presented for evaluation of acute onset diagonal diplopia. Adduction OS was about 60% of normal while medialization OS improved with convergence. In right gaze, dissociated abducting nystagmus was present OD, and there was a clear adduction lag when asking her to look from left to right. These findings are characteristic of a left internuclear ophthalmoplegia (INO), caused by a lesion in the left medial longitudinal fasciculus (MLF). While INO is the most commonly and most easily recognized feature of an MLF lesion, it is often accompanied by other less commonly recognized features. She was seen 1 week following the onset, and while the MRI report did not mention acute MLF injury (images were not available for review), given her vascular risk factors, a small stroke involving the basilar artery perforators was assumed (MRA head normal). ; •; Ocular tilt reaction (OTR - skew deviation, ocular counterroll, head tilt) - With alternate cover and cover-uncover testing, there was an expected exodeviation that was maximal in right gaze due to an adduction deficit OS. However, there was also a left hypertropia that was comitant in all directions of gaze, consistent with a skew deviation. When diagnostic confusion between a skew deviation and 4th nerve palsy for instance, upright-supine testing should be performed - if there is a significant reduction in the amplitude of the hypertropia when going from upright to supine (easiest to measure using Maddox rod testing), then utricle-ocular motor pathway asymmetry (i.e., the mechanism for the OTR and skew) is suggested since these pathways are gravity-dependent. Dilated fundoscopic examination demonstrated another feature of the OTR, ocular counterroll, or extorsion of the (lower) right eye and intorsion of the (higher) left eye. In contrast, the hypertropic eye in a 4th nerve palsy should be excyclodeviated. There was also a mild rightward head tilt; therefore, a complete OTR was seen. The perceptual consequence of the OTR is a shift involving the subjective visual vertical (SVV). The SVV, as measured at the bedside with the bucket test, is tilted in the same direction as the OTR. When the lesion is caudal to the decussation (pontomedullary region) of the utricle-ocular motor pathways as in a right lateral medullary (Wallenberg) syndrome, the OTR and SVV will be ipsiversive - e.g., right head tilt, counterroll of both eyes towards right ear, right hypotropia and SVV tilted to the right. When the lesion is rostral to the decussation of these fibers as in a left MLF syndrome, the OTR and SVV will be contraversive as in this patient - e.g., right head tilt, counterroll of both eyes towards right ear, left hypertropia and SVV tilted to the right. ; •; Nystagmus - In addition to dissociated abducting nystagmus, MLF lesions usual cause other patterns of vertical and torsional nystagmus. ; o; Gaze-evoked nystagmus - Upbeat nystagmus (UBN) in upgaze and downbeat nystagmus (DBN) in downgaze is more often seen with bilateral MLF injury, although may be seen with unilateral pathology as well. It is not clear whether this results from descending fibers going from interstitial nucleus of Cajal (INC) to the medullary nucleus of Roller and/or the nearby paramedian tract (PMT) cell groups; involvement of PMT cell groups alone; or involvement of pathways from vestibular nuclei to the INC that have a role in neural integration. The PMT cell groups are thought to receive inputs from the INC that are transmitted to the flocculus. ; o; Spontaneous torsional or vertical-torsional nystagmus - This patient had spontaneous (primarily) torsional nystagmus, with quick phases of the superior poles directed towards the ipsilesional (left) side. When torsional nystagmus is seen in the setting of acute MLF injury, it is almost always ipsilesional. More common than pure torsional nystagmus is a dissociated vertical nystagmus. The most common pattern is upbeat in both eyes, with more prominent UBN in the contralateral eye. DBN that's more prominent in the ipsilateral eye may also been seen. A final pattern is a jerky (or hemi-) seesaw nystagmus where the torsional component is ipsiversive, there's more UBN in the contralateral eye and more DBN in the ipsilateral eye. These various patterns of nystagmus are caused by the disruption of ascending utricular and/or vertical semicircular canal (SCC) pathways. Our patient was seen about 1 week after the onset, so it's possible that vertical nystagmus had been present but already resolved as this subtle vertical-torsional nystagmus is typically short-lived. ; •; Vertical VOR - It has also been demonstrated that central pathways from the contralateral vertical SCC traverse the MLF. The posterior SCC pathway is much more affected by a unilateral MLF injury as compared to the anterior SCC pathway. This is because the fibers originating in the anterior SCC also travel through the brachium conjunctivum and ventral tegmental tract; therefore, anterior SCC function is relatively preserved. For this reason, patients with bilateral MLF injuries commonly complain of oscillopsia with head movements due to bilateral vertical VOR weakness. Objectively, this can be demonstrated by a significant decrement in dynamic visual acuity vertically but not horizontally, or with vertical head impulse testing (HIT) in the planes of anterior and posterior SCCs. Vertical HIT can be technically challenging, which is why video head impulse testing can be helpful in this setting. In our patient there were reduced right posterior SCC VOR gains on vHIT, with overt catch-up saccades in the plane of the right posterior SCC on bedside exam. Additionally, there were abnormal head impulses in the plane of the left anterior SCC, and it's possible that this resulted from additional involvement of the left brachium conjunctivuum if the left MLF was affected more laterally. ; •; Horizontal VOR - During horizontal VOR testing using the HIT, the velocity of the adducting eye (ipsilateral to an MLF lesion) movement can be relatively preserved - i.e., much better than what would be expected based on bedside testing with a significant adduction lag due to an INO. This is proposed to be caused by an extra-MLF pathway, the ascending tract of Dieters, which goes directly from the vestibular nuclei to the oculomotor nucleus. However, when a refixation saccade is necessary - e.g., adducting saccade OS with leftward HIT in the setting of a left INO may look normal due to an extra-MLF pathway - a much slower adducting saccade OS will be generated (abnormal as this is using the MLF pathway). [[[SEE CASE VIDEO - CLICK HERE: https://collections.lib.utah.edu/details?id=1278694 ]]]
Date 2017
Language eng
Format image/jpeg
Type Image
Collection Neuro-Ophthalmology Virtual Education Library: Dan Gold Neuro-Ophthalmology Collection: https://novel.utah.edu/Gold/
Publisher North American Neuro-Ophthalmology Society
Holding Institution Spencer S. Eccles Health Sciences Library, University of Utah, 10 N 1900 E SLC, UT 84112-5890
Rights Management Copyright 2016. For further information regarding the rights to this collection, please visit: https://NOVEL.utah.edu/about/copyright
ARK ark:/87278/s64v0f7w
Setname ehsl_novel_gold
ID 1278695
Reference URL https://collections.lib.utah.edu/ark:/87278/s64v0f7w
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