Your search keyword '"nodulus"' showing total 15 results

1. Vestibular Nuclei and Their Cerebellar Connections

Author

Barmack, Neal H., Gruol, Donna L., editor, Koibuchi, Noriyuki, editor, Manto, Mario, editor, Molinari, Marco, editor, Schmahmann, Jeremy D., editor, and Shen, Ying, editor

Published

2023

2. Motility and Ocular Motor Disorders

Author

Gold, Daniel and Gold, Daniel

Published

2021

3. Vestibular Nuclei and Their Cerebellar Connections

Author

Barmack, Neal H., Gruol, Donna L., editor, Koibuchi, Noriyuki, editor, Manto, Mario, editor, Molinari, Marco, editor, Schmahmann, Jeremy D., editor, and Shen, Ying, editor

Published

2016

4. Impaired Tilt Suppression of Post-Rotatory Nystagmus and Cross-Coupled Head-Shaking Nystagmus in Cerebellar Lesions: Image Mapping Study.

Author

Lee, Sun-Uk, Choi, Jeong-Yoon, Kim, Hyo-Jung, Park, Jeong-Jin, Zee, David, and Kim, Ji-Soo

Subjects

*NYSTAGMUS, *CEREBELLUM injuries, *BRAIN mapping, *MOTOR ability, *VESTIBULO-ocular reflex, *DIAGNOSIS

Abstract

We sought to determine the cerebellar structures responsible for tilt suppression of post-rotatory nystagmus. We investigated ocular motor findings and MRI lesions in 73 patients with isolated cerebellar lesions who underwent recording of the vestibulo-ocular reflex (VOR) using rotatory chair tests. Tilt suppression of post-rotatory nystagmus was diminished in 27 patients (27/73, 37.0 %). The gains of the VOR and the TCs of per- and post-rotatory nystagmus did not differ between the patients with diminished and with normal tilt suppression. The patients with impaired tilt suppression showed perverted ('cross-coupled') head-shaking nystagmus (pHSN) and central positional nystagmus (CPN) more frequently than those with normal responses. Tilt suppression was impaired in five (71.4 %) of the seven patients with isolated nodulus and uvular infarction. Probabilistic lesion-mapping analysis showed that the nodulus and uvula are responsible for tilt suppression. Impaired tilt suppression may be ascribed to disruption of cerebellar contribution to the vestibular velocity-storage mechanism, which integrates information from the semicircular canals and otolith organs to help derive the brain's estimate of the head orientation relative to the pull of gravity. [ABSTRACT FROM AUTHOR]

Published

2017

5. Positional upbeat nystagmus on uprighting due to uvulo‐nodular infarction presenting as persistent vertigo and ataxia.

Author

Yamaguchi, Nanaka, Shimada, Ryuichi, Kajimoto, Yasuyuki, Sugimoto, Izumi, and Sakurai, Yasuhisa

Subjects

*BENIGN paroxysmal positional vertigo, *NYSTAGMUS, *VERTIGO, *INFARCTION, *SUPINE position, *ATAXIA

Abstract

We report a patient with severe and prolonged vertigo and ataxia caused by infarction of the bilateral cerebellar nodulus and uvula. Vertigo and nausea persisted for 2 weeks, causing the patient to remain bedridden. The patient showed upbeat nystagmus (UBN) on upward gaze and upon uprighting from the supine position and did not exhibit apogeotropic nystagmus characteristic of central paroxysmal positional nystagmus. Isolated positional UBN may be specific to an uvulo‐nodular lesion, and persistent and marked vertigo suggests extensive damage to the bilateral nodulus and uvula. [ABSTRACT FROM AUTHOR]

Published

2019

6. Topsy Turvy: Functions of Climbing and Mossy Fibers in the Vestibulo-Cerebellum.

Author

Barmack, Neal H. and Yakhnitsa, Vadim

Subjects

*CEREBELLUM, *CELLS, *FIBERS, *NEURONS, *BRAIN, *NERVES

Abstract

The cerebellum’s role in sensory-motor control and adaptation is undisputed. However, a key hypothesis pertaining to the function of cerebellar circuitry lacks experimental support. It is universally assumed that the discharge of mossy fibers accounts for modulation of Purkinje cell “simple spikes” (SSs). This assumption acts as a prism through which all other functions of cerebellar circuitry are viewed. The vestibulo-cerebellum (nodulus and uvula) receives a large, unilateral, vestibular primary afferent mossy fiber projection. We can test its role in modulating Purkinje cell SSs by recording the modulated activity of both mossy fiber terminals and Purkinje cell SSs evoked by identical natural vestibular stimulation. Sinusoidal rotation about the longitudinal axis (roll) modulates the activity of vestibular primary afferent mossy and climbing fibers as well as Purkinje cell SSs and complex spikes (CSs). Remarkably, vestibular primary afferent mossy fibers discharge 180 degrees out of phase with SSs. This indicates that mossy fibers cannot account for SS modulation unless an inhibitory synapse is interposed between mossy fibers or vestibular climbing fibers and Purkinje cells. The authors review several experiments that address the relative contributions of mossy and climbing fiber afferents to the modulation of SSs. They conclude that climbing fibers, not mossy fibers, are primarily responsible for the modulation of SSs as well as CSs and they propose revised functions for these two afferent systems. [ABSTRACT FROM PUBLISHER]

Published

2011

7. Computation of Egomotion in the Macaque Cerebellar Vermis.

Author

Angelaki, Dora E., Yakusheva, Tatyana A., Green, Andrea M., Dickman, J. David, and Blazquez, Pablo M.

Subjects

*UVULA, *NEURONS, *CEREBELLAR cortex, *OTOLITHS, *PURKINJE cells

Abstract

The nodulus and uvula (lobules X and IX of the vermis) receive mossy fibers from both vestibular afferents and vestibular nuclei neurons and are thought to play a role in spatial orientation. Their properties relate to a sensory ambiguity of the vestibular periphery: otolith afferents respond identically to translational (inertial) accelerations and changes in orientation relative to gravity. Based on theoretical and behavioral evidence, this sensory ambiguity is resolved using rotational cues from the semicircular canals. Recordings from the cerebellar cortex have identified a neural correlate of the brain's ability to resolve this ambiguity in the simple spike activities of nodulus/uvula Purkinje cells. This computation, which likely involves the cerebellar circuitry and its reciprocal connections with the vestibular nuclei, results from a remarkable convergence of spatially- and temporally-aligned otolith-driven and semicircular canal-driven signals. Such convergence requires a spatio-temporal transformation of head-centered canal-driven signals into an estimate of head reorientation relative to gravity. This signal must then be subtracted from the otolith-driven estimate of net acceleration to compute inertial motion. At present, Purkinje cells in the nodulus/uvula appear to encode the output of this computation. However, how the required spatio-temporal matching takes place within the cerebellar circuitry and what role complex spikes play in spatial orientation and disorientation remains unknown. In addition, the role of visual cues in driving and/or modifying simple and complex spike activity, a process potentially critical for long-term adaptation, constitutes another important direction for future studies. [ABSTRACT FROM AUTHOR]

Published

2010

8. Distribution of granule cells projecting to focal Purkinje cells in mouse uvula-nodulus

Author

Barmack, N.H. and Yakhnitsa, V.

Subjects

*PURKINJE cells, *CELLULAR mechanics, *UVULA, *SEMICIRCULAR canals, *LABORATORY mice, *CEREBELLUM physiology

Abstract

Abstract: Mossy and climbing fibers convey a broad array of signals from vestibular end organs to Purkinje cells in the vestibulo-cerebellum. We have shown previously that Purkinje cell simple spikes (SSs) and climbing fiber–evoked complex spikes (CSs) in the mouse uvula-nodulus are arrayed in 400 μm wide sagittal climbing fiber zones corresponding to the rotational axes of the vertical semicircular canals. It is often assumed that mossy fibers modulate a higher frequency of SSs through the intermediary action of granule cells whose parallel fibers course through the Purkinje cell dendritic tree. This assumption is complicated by the diffuse topography of vestibular primary afferent mossy fiber projections to the uvula-nodulus and the dispersion of mossy fiber signals along folial axes by parallel fibers. Here we measure this parallel fiber dispersion. We made microinjections of neurobiotin into the molecular layers of different folia within the mouse vestibulo-cerebellum and measured the distribution of granule cells retrogradely labeled by the injected neurobiotin. Sixty-two percent of labeled granule cells were located outside a 400 μm sagittal zone flanking the injection site. The dispersion of labeled granule cells was ∼2.5 mm along folial axes that were 2.7–2.9 mm wide. Our data suggest that topographic specificity of SSs could not be attributed to the topography of vestibular primary afferent mossy fiber–granule cell projections. Rather the response specificity of SSs must be attributed to other mechanisms related to climbing fiber–evoked Purkinje cell and interneuronal activity. [Copyright &y& Elsevier]

Published

2008

9. Functions of Interneurons in Mouse Cerebellum.

Author

Barmack, Neal H. and Yakhnitsa, Vadim

Subjects

*INTERNEURONS, *CEREBELLUM, *PURKINJE cells, *GOLGI apparatus, *OLIVARY nucleus

Abstract

The output signal of Purkinje cells is conveyed by the modulated discharge of simple spikes (SSs) often ascribed to mossy fiber-granule cell-parallel fiber inputs to Purkinje cell dendrites. Although generally accepted, this view lacks experimental support. We can address this view by controlling afferent signals that reach the cerebellum over climbing and mossy fiber pathways. Vestibular primary afferents constitute the largest mossy fiber projection to the uvula-nodulus. The discharge of vestibular primary afferent mossy fibers increases during ipsilateral roll tilt. The discharge of SSs decreases during ipsilateral roll tilt. Climbing fiber discharge [complex spikes (CSs)] increases during ipsilateral roll tilt. These observations suggest that the modulation of SSs during vestibular stimulation cannot be attributed directly to vestibular mossy fiber afferents. Rather we suggest that interneurons driven by vestibular climbing fibers may determine SS modulation. We recorded from cerebellar interneurons (granule, unipolar brush, Golgi, stellate, basket, and Lugaro cells) and Purkinje cells in the uvula-nodulus of anesthetized mice during vestibular stimulation. We identified all neuronal types by juxtacellular labeling with neurobiotin. Granule, unipolar brush, stellate, and basket cells discharge in phase with ipsilateral roll tilt and in phase with CSs. Golgi cells discharge out of phase with ipsilateral roll tilt and out of phase with CSs. The phases of stellate and basket cell discharge suggests that their activity could account for the antiphasic behavior of CSs and SSs. Because Golgi cells discharge in phase with SSs, Golgi cell activity cannot account for SS modulation. The sagittal array of Golgi cell axon terminals suggests that they contribute to the organization of discrete parasagittal vestibular zones. [ABSTRACT FROM AUTHOR]

Published

2008

10. Role of Cerebellar Nodulus and Uvula on the Vestibular Quick Phase Spatial Constancy.

Author

Pettorossi, V. E., Grassi, S., Errico, P., and Barmack, N. H.

Subjects

*VESTIBULAR apparatus, *CEREBELLUM, *UVULA

Abstract

We investigated the orientation of quick phases (QPs) of vestibularly-induced eye movements in rabbits in response to ''off-vertical'' sinusoidal vestibular stimulation. We also examined the possible role of the cerebellar nodulus and ventral uvula in controlling QP spatial orientation and modification. During ''off-vertical'' vestibular stimulation QPs remained aligned with the earth's horizontal plane, while the slow phases (SPs) were aligned with the plane of vestibular stimulation. This suggests that QPs are coded in gravito-inertial coordinates and SPs in head coordinates. When rabbits were oscillated in the light (20° peak-to-peak; 0.2 Hz) about an ''off-vertical'' axis for 2 h, the QPs changed their trajectory, abandoning the earth's horizontal plane to approach the plane of the stimulus. By contrast, in the absence of conjunctive optokinetic stimulation, QPs remained fixed in the earth's horizontal plane even after 2 h of ''off-vertical'' stimulation. The conjunctive combination of optokinetic and vestibular stimulation caused QPs to change their plane of rotation. After lesion of the nodulus-uvula the ability of rabbits to reorient QPs during conjoint vestibular-optokinetic stimulation was maintained. We conclude that the space orientation and adaptation of QPs do not require cerebellar control. [ABSTRACT FROM AUTHOR]

Published

2001

11. Properties of utricular and saccular nerve-activated vestibulocerebellar neurons in cats.

Author

Ono, S., Kushiro, K., Zakir, M., Meng, H., Sato, H., and Uchino, Y.

Subjects

BLADDERWORTS, SACCULINIDAE, VESTIBULO-ocular reflex, ACOUSTIC nerve, NEURONS, SPINAL cord, RATS

Abstract

Properties of otolith inputs to vestibulocerebellar neurons were investigated in 14 adult cats. In the vestibular nuclei, we recorded single-unit activities that responded orthodromically after stimulation of the utricular and/or saccular nerves and antidromically after stimulation of the cerebellum (uvula-nodulus and anterior vermis). Descending axonal projections to the spinal cord were also examined by antidromic stimulation of the caudal end of the C1 segment. Forty-seven otolith-activated neurons that projected to the uvula-nodulus were recorded. Thirteen (28%) of the 47 neurons received convergent inputs from the utriculus and sacculus. The remaining 34 (72%) vestibular neurons were non-convergent neurons: 18 (38%) received utricular input alone, and 16 (34%) received saccular input alone. Most (35/47) vestibulocerebellar neurons were located in the descending vestibular nucleus and only one of these projected to the spinal cord. Seven of the 47 vestibulocerebellar neurons were located in the lateral vestibular nucleus and most of these neurons projected to the spinal cord. The remaining neurons were located in group X (two neurons) and the superior vestibular nucleus (three neurons). In a different series of experiments, 37 otolith-activated vestibular neurons were tested to determine whether they projected to the uvula-nodulus and/or the anterior vermis. Nineteen of the 37 neurons projected to the anterior vermis, 13/37 projected to the uvula-nodulus, and 5/37 projected to both. The utricular and/or saccular nerve-activated vestibulocerebellar neurons projected to not only the uvula-nodulus, but also to the anterior vermis. In summary, the results of this study showed that vestibular neurons receiving inputs from the utriculus and/or sacculus projected to the cerebellar cortex. This indirect otolith-cerebellar pathway terminated both in the anterior lobe and in the uvula/nodulus. [ABSTRACT FROM AUTHOR]

Published

2000

12. Connections of Purkinje cell axons of lobule X with vestibulocerebellar neurons projecting to lobule X or IX in the rat.

Author

Guoxiang Xiong and Matsushita, Matsuo

Subjects

PURKINJE cells, EPICOCCUM, NEURONS, NERVES, AXONS, VIBRIO infections

Abstract

Connections of Purkinje cell axons of lobule X (nodulus) with vestibulocerebellar neurons projecting to lobule X or IX (uvula) were revealed in the rat. Purkinje cell axons were anterogradely labeled with biotinylated dextran (BD) injected into sublobule Xa while vestibular neurons were retrogradely labeled with cholera toxin subunit B (CTB) injected into sublobule Xa or IXc. Labeled terminals of Purkinje cell axons of lobule X were numerous in the superior vestibular nucleus (SV), medial parts of the parvocellular (MVpc) and the caudal part (MVc) of the medial vestibular nucleus (MV), and group y. These subdivisions of the vestibular nuclei contained many neurons projecting to lobule X or IX. Lobule-X-projecting and lobule-IX-projecting neurons were in contact with terminals of Purkinje cell axons of lobule X in the MVpc and MVc. They were distributed dorsally to medially in medial parts of the MVpc and MVc. The present study suggests that Purkinje cells in lobule X regulate the output of a population of lobule-X-projecting or lobule-IX-projecting neurons of the MVpc and MVc. [ABSTRACT FROM AUTHOR]

Published

2000

13. Ocular tilt reaction due to unilateral cerebellar lesion.

Author

Min, Wang-kie, Kim, Jong-yeol, Park, Sung-pa, and Suh, Chung-kyu

Subjects

*EYE movement disorders, *BRAIN injuries, *VESTIBULAR nuclei

Abstract

We report two patients with an ocular tilt reaction (OTR) due to unilateral caudal cerebellar lesion. One patient had a caudal cerebellar hemorrhage, the other a posterior inferior cerebellar artery territory infarct. There was head tilt in both patients which had not been reported previously. These findings support the previous proposal that the mechanism of a tonic contraversive OTR with unilateral cerebellar lesion is an increased tonic resting activity in the ipsilesional vestibular nucleus due to a loss of inhibition from the lesioned nodulus. [ABSTRACT FROM AUTHOR]

Published

1999

14. Stimulation of the nodulus and uvula discharges velocity storage in the vestibulo-ocular reflex.

Author

Solomon, David and Cohen, Bernard

Abstract

The nodulus and sublobule d of the uvula of rhesus and cynomolgus monkeys were electrically stimulated with short trains of pulses to study changes in horizontal slow-phase eye velocity. Nodulus and uvula stimulation produced a rapid decline in horizontal slow phase velocity, one aspect of the spatial reorientation of the axis of eye rotation that occurs when the head is tilted with regard to gravity during per- and post-rotatory nystagmus and optokinetic after-nystagmus (OKAN). Nodulus and uvula stimulation also reproduced the reduction of the horizontal time constant of post-rotatory nystagmus and OKAN that occurs during visual suppression. The brief electric stimuli (4-5 s) induced little slow-phase velocity and had no effect on the initial jump in eye velocity at the onset or the end of angular rotation. Effects of stimulation were unilateral, suggesting specificity of the output pathways. Activation of more caudal sites in the uvula produced nystagmus with a rapid rise in eye velocity, but the effects did not outlast the stimulus and did not affect VOR or OKAN time constants. Thus, stimulation of caudal parts of the uvula did not affect eye velocity produced by velocity storage. We postulate that the nodulus and sublobule d of the uvula control the time constant of the yaw axis (horizontal) component of slow-phase eye velocity produced by velocity storage. [ABSTRACT FROM AUTHOR]

Published

1994

15. Secondary vestibulocerebellar projections to the flocculus and uvulo-nodular lobule of the rabbit: a study using HRP and double fluorescent tracer techniques.

Author

Epema, A., Gerrits, N., and Voogd, J.

Abstract

The distribution of vestibular neurons projecting to the flocculus and the nodulus and uvula of the caudal vermis (Larsell's lobules X and IX) was investigated with retrograde axonal transport of horseradish peroxidase and the fluorescent tracers Fast Blue, Nuclear Yellow and Diamidino Yellow. The presence of collateral axons innervating the flocculus on one hand and the nodulus and uvula on the other was studied with simultaneous injection of the different fluorescent tracers. The distribution of vestibular neurons projecting to either flocculus or caudal vermis is rather similar and has a bilateral symmetry. The projection from the magnocellular medial vestibular nucleus is very sparse, while that from the lateral vestibular nucleus is absent. The majority of labeled neurons was found in the medial, superior, and descending vestibular nuclei, in that order. Double labeled neurons were distributed in a similar way as the single labeled ones. Labeled neurons project to the nodulus and uvula, the flocculus, and to both parts of the cerebellum simultaneously in a ratio of 12:4:1. Five different populations of vestibulocerebellar neurons can be distinguished on the basis of their projection to the: (1) ipsilateral flocculus, (2) contralateral flocculus, (3) ipsilateral flocculus and nodulus/uvula, (4) contralateral flocculus and nodulus/uvula, and (5) nodulus/uvula. [ABSTRACT FROM AUTHOR]

Published

1990