Vertical nystagmus: clinical facts and hypotheses

doi:10.1093/brain/awh532

Brain Advance Access originally published online on May 4, 2005
Brain 2005 128(6):1237-1246; doi:10.1093/brain/awh532

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Review Article

Vertical nystagmus: clinical facts and hypotheses

C. Pierrot-Deseilligny¹ and D. Milea²

¹ INSERM 679 and Service de Neurologie 1 and ² Service d'Ophtalmologie, Hôpital de la Salpêtrière (AP-HP), Paris, France

Correspondence to: Professeur C. Pierrot-Deseilligny, Service de Neurologie 1, Hôpital de la Salpêtrière, 47 Bd de l'Hôpital, 75651 Paris cedex 13, France E-mail: cp.deseilligny{at}psl.ap-hop-paris.fr

The pathophysiology of spontaneous upbeat (UBN) and downbeat(DBN) nystagmus is reviewed in the light of several instructiveclinical findings and experimental data. UBN due to pontinelesions could result from damage to the ventral tegmental tract(VTT), originating in the superior vestibular nucleus (SVN),coursing through the ventral pons and transmitting excitatoryupward vestibular signals to the third nerve nucleus. A VTTlesion probably leads to relative hypoactivity of the driveto the motoneurons of the elevator muscles with, consequently,an imbalance between the downward and upward systems, resultingin a downward slow phase. The results observed in internuclearophthalmoplegia suggest that the medial longitudinal fasciculus(MLF) is involved in the transmission of both upward and downwardvestibular signals. Since no clinical cases of DBN due to focalbrainstem damage have been reported, it may be assumed thatthe transmission of downward vestibular signals depends onlyupon the MLF, whereas that of upward vestibular signals involvesboth the MLF and the VTT. The main focal lesions resulting inDBN affect the cerebellar flocculus and/or paraflocculus. Apparently,this structure tonically inhibits the SVN and its excitatoryefferent tract (i.e. the VTT) but not the downward vestibularsystem. Therefore, a floccular lesion could result in a disinhibitionof the SVN–VTT pathway with, consequently, relative hyperactivityof the drive to the motoneurons of the elevator muscles, resultingin an upward slow phase. UBN also results from lesions affectingthe caudal medulla. An area in this region could form part ofa feedback loop involved in upward gaze-holding, originatingin a collateral branch of the VTT and comprising the caudalmedulla, the flocculus and the SVN, successively. Therefore,it is suggested that the main types of spontaneous verticalnystagmus due to focal central lesions result from a primarydysfunction of the SVN–VTT pathway, which becomes hypoactiveafter pontine or caudal medullary lesions, thereby elicitingUBN, and hyperactive after floccular lesions, thereby elicitingDBN. Lastly, since gravity influences UBN and DBN and may facilitatethe downward vestibular system and restrain the upward vestibularsystem, it is hypothesized that the excitatory SVN–VTTpathway, along with its specific floccular inhibition, has developedto counteract the gravity pull. This anatomical hyperdevelopmentis apparently associated with a physiological upward velocitybias, since the gain of all upward slow eye movements is greaterthan that of downward slow eye movements in normal human subjectsand in monkeys.

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