Your search keyword '"nodulus"' showing total 6 results

1. Dedication to Mingjia Dai, Ph.D. for Discovery of the First Successful Treatment of the Mal de Debarquement Syndrome

Author

Bernard Cohen

Subjects

vestibular, vestibulo-cerebellar, motion sickness, velocity storage, nodulus, Neurology. Diseases of the nervous system, RC346-429

Published

2019

2. Hypothesis: The Vestibular and Cerebellar Basis of the Mal de Debarquement Syndrome

Author

Bernard Cohen, Sergei B. Yakushin, and Catherine Cho

Subjects

vestibular-only neurons, nodulus, baclofen, rocking, swaying, bobbing, Neurology. Diseases of the nervous system, RC346-429

Abstract

The Mal de Debarquement syndrome (MdDS) generally follows sea voyages, but it can occur after turbulent flights or spontaneously. The primary features are objective or perceived continuous rocking, swaying, and/or bobbing at 0.2 Hz after sea voyages or 0.3 Hz after flights. The oscillations can continue for months or years and are immensely disturbing. Associated symptoms appear to be secondary to the incessant sensation of movement. We previously suggested that the illness can be attributed to maladaptation of the velocity storage integrator in the vestibular system, but the actual neural mechanisms driving the MdDS are unknown. Here, based on experiments in subhuman primates, we propose a series of postulates through which the MdDS is generated: (1) The MdDS is produced in the velocity storage integrator by activation of vestibular-only (VO) neurons on either side of the brainstem that are oscillating back and forth at 0.2 or 0.3 Hz. (2) The groups of VO neurons are driven by signals that originate in Purkinje cells in the cerebellar nodulus. (3) Prolonged exposure to roll, either on the sea or in the air, conditions the roll-related neurons in the nodulus. (4) The prolonged exposure causes a shift of the pitch orientation vector from its original position aligned with gravity to a position tilted in roll. (5) Successful treatment involves exposure to a full-field optokinetic stimulus rotating around the spatial vertical countering the direction of the vestibular imbalance. This is done while rolling the head at the frequency of the perceived rocking, swaying, or bobbing. We also note experiments that could be used to verify these postulates, as well as considering potential flaws in the logic. Important unanswered questions: (1) Why does the MdDS predominantly affect women? (2) What aspect of roll causes the prolongation of the tilted orientation vector, and why is it so prolonged in some individuals? (3) What produces the increase in symptoms of some patients when returning home after treatment, and how can this be avoided? We also posit that the same mechanisms underlie the less troublesome and shorter duration Mal de Debarquement.

Published

2018

3. Hypothesis: The Vestibular and Cerebellar Basis of the Mal de Debarquement Syndrome.

Author

Cohen, Bernard, Yakushin, Sergei B., and Cho, Catherine

Subjects

BACLOFEN, BALANCE disorders, VESTIBULAR apparatus diseases

Abstract

The Mal de Debarquement syndrome (MdDS) generally follows sea voyages, but it can occur after turbulent fights or spontaneously. The primary features are objective or perceived continuous rocking, swaying, and/or bobbing at 0.2 Hz after sea voyages or 0.3 Hz after fights. The oscillations can continue for months or years and are immensely disturbing. Associated symptoms appear to be secondary to the incessant sensation of movement. We previously suggested that the illness can be attributed to maladaptation of the velocity storage integrator in the vestibular system, but the actual neural mechanisms driving the MdDS are unknown. Here, based on experiments in subhuman primates, we propose a series of postulates through which the MdDS is generated: (1) The MdDS is produced in the velocity storage integrator by activation of vestibular-only (VO) neurons on either side of the brainstem that are oscillating back and forth at 0.2 or 0.3 Hz. (2) The groups of VO neurons are driven by signals that originate in Purkinje cells in the cerebellar nodulus. (3) Prolonged exposure to roll, either on the sea or in the air, conditions the roll-related neurons in the nodulus. (4) The prolonged exposure causes a shift of the pitch orientation vector from its original position aligned with gravity to a position tilted in roll. (5) Successful treatment involves exposure to a full-field optokinetic stimulus rotating around the spatial vertical countering the direction of the vestibular imbalance. This is done while rolling the head at the frequency of the perceived rocking, swaying, or bobbing. We also note experiments that could be used to verify these postulates, as well as considering potential faws in the logic. Important unanswered questions: (1) Why does the MdDS predominantly affect women? (2) What aspect of roll causes the prolongation of the tilted orientation vector, and why is it so prolonged in some individuals? (3) What produces the increase in symptoms of some patients when returning home after treatment, and how can this be avoided? We also posit that the same mechanisms underlie the less troublesome and shorter duration Mal de Debarquement. [ABSTRACT FROM AUTHOR]

Published

2018

4. Dedication to Mingjia Dai, Ph.D. for Discovery of the First Successful Treatment of the Mal de Debarquement Syndrome.

Author

Cohen, Bernard

Subjects

SYNDROMES, VESTIBULO-ocular reflex, DEDICATIONS, MOTION sickness, NEUROLOGICAL disorders, SEMICIRCULAR canals, VESTIBULAR apparatus diseases

Abstract

The successful treatment of the MdDS has been carried on by Dai's colleague, Sergei Yakushin, Ph.D., Associate Professor of Neurology. 15 Dai, M, Raphan, T, Cohen, B, Prolonged reduction of motion sickness sensitivity by visual-vestibular interaction. 18 Dai, M, Cohen, B, Cho, C, Shin, S, Yakushin, SB, Treatment of the Mal de Debarquement Syndrome: a 1-year follow-up. [Extracted from the article]

Published

2019

5. Cerebellum and Ocular Motor Control

Author

Amir eKheradmand and David S. Zee

Subjects

saccade, vestibular, pursuit, Fastigial, Flocculus, Nodulus, Neurology. Diseases of the nervous system, RC346-429

Abstract

An intact cerebellum is a prerequisite for optimal ocular motor performance. The cerebellum fine-tunes each of the subtypes of eye movements so they work together to bring and maintain images of objects of interest on the fovea. Here we review the major aspects of the contribution of the cerebellum to ocular motor control. The approach will be based on structural-functional correlation, combining the effects of lesions and the results from physiologic studies, with the emphasis on the cerebellar regions known to be most closely related to ocular motor function: 1) the flocculus/paraflocculus for high-frequency (brief) vestibular responses, sustained pursuit eye movements and gaze-holding, 2) the nodulus/ventral uvula for low-frequency (sustained) vestibular responses, and 3) the dorsal oculomotor vermis and its target in the posterior portion of the fastigial nucleus (the fastigial oculomotor region) for saccades and pursuit initiation.

Published

2011

6. Cerebellum and ocular motor control.

Author

Kheradmand A and Zee DS

Abstract

An intact cerebellum is a prerequisite for optimal ocular motor performance. The cerebellum fine-tunes each of the subtypes of eye movements so they work together to bring and maintain images of objects of interest on the fovea. Here we review the major aspects of the contribution of the cerebellum to ocular motor control. The approach will be based on structural-functional correlation, combining the effects of lesions and the results from physiologic studies, with the emphasis on the cerebellar regions known to be most closely related to ocular motor function: (1) the flocculus/paraflocculus for high-frequency (brief) vestibular responses, sustained pursuit eye movements, and gaze holding, (2) the nodulus/ventral uvula for low-frequency (sustained) vestibular responses, and (3) the dorsal oculomotor vermis and its target in the posterior portion of the fastigial nucleus (the fastigial oculomotor region) for saccades and pursuit initiation.

Published

2011