Vestibular Precision: Physiology & Pathophysiology

Dizziness Clinical Trial

Official title:

Vestibular Precision: Physiology & Pathophysiology

Clinical Trial Details — Status: Enrolling by invitation

Administrative data

• NCT number: NCT04890132
• Other study ID #: 2019A015798
• Status: Enrolling by invitation
• Phase: N/A
• Start date: July 1, 2020
• Est. completion date: June 30, 2025

Study information

• Verified date: March 2023
• Source: Massachusetts Eye and Ear Infirmary
• Contact: n/a
• Is FDA regulated: No
• Study type: Interventional

Clinical Trial Summary

This project will investigate the role of noise in the vestibular system, and in particular its effects on the variability (precision) of vestibular-mediated behaviors. The investigators will study vestibular precision in normal subjects and patients with peripheral vestibular damage, and will investigate its potential plasticity. The goals are to develop a better understanding of the role noise plays in the vestibular system in normal and pathologic populations, and to determine if the brain can learn to improve signal recognition within its inherently noisy neural environment, which would result in improved behavioral precision.

Description:

The goal of this study is to investigate vestibular precision by quantifying the variability in behavioral responses that result from the neural noise inherent to the peripheral and central vestibular systems. Because neural noise contaminates the signals that are transduced by the ear and processed by the brain, vestibular-mediated behavioral responses vary even when identical stimuli are provided. In this study, the investigators focus on vestibular precision in human subjects and investigate its sources, its effects on behavior, and its degradation when the periphery is damaged and its potential plasticity. Specifically, the investigators will investigate: (1) Vestibular precision in normal subjects - physiology: A) The investigators will measure the angular and linear vestibulo-ocular reflex (VOR) using novel motion combinations that reinforce or cancel eye movement responses, which will allow us to determine the distribution and magnitude of noise produced in the sensory (canal, otolith) pathways and in the oculomotor pathway. The investigators hypothesize that normal subjects will demonstrate a bimodal distribution of noise with either sensory or motor predominance, and that subjects with more sensory noise will demonstrate other behavioral characteristics that reflect this characteristic (e.g., higher perceptual thresholds); and B) The investigators will assay vestibular noise from trial-trial variations in the VOR and will compare VOR dynamics with those predicted by a Bayesian model using the assayed noise. The investigators predict variations in VOR dynamics across subjects, age and stimulus amplitudes will be consistent with Bayesian processing of noise. Potential confounding factors will be carefully controlled, including attention, fatigue, and non-vestibular cues. (2) Vestibular precision after peripheral damage - pathophysiology: A) The investigators will examine the changes in vestibular precision that occur when one vestibular nerve is damaged (by a vestibular schwannoma, VS) and after the damaged nerve is surgically sectioned, and will investigate if precision measurements can provide evidence of pathologic noise produced by the damaged nerve and therefore help predict clinical outcome when the nerve is sectioned. The investigators hypothesize that changes in signal reliability due to the VS will be traceable to both the reduced redundancy caused by loss of afferent fibers and to aberrant noise generated by the damaged vestibular nerve and that changes in precision after neurectomy will correlate the outcome measures that characterize patient disability; and B) The investigators will examine the plasticity of vestibular precision in the oculomotor and perceptual realms with the goal of determining if precision can be improved. Using novel training approaches that provide challenging signal extraction tasks, the investigators hypothesize that participants will improve their vestibular precision on the trained task. As secondary outcome measures, the investigators will determine if training one behavior generalizes to the non-trained behavior and if patient's symptoms are affected by improved precision.

Recruitment information / eligibility

• Status: Enrolling by invitation
• Enrollment: 90
• Est. completion date: June 30, 2025
• Est. primary completion date: June 30, 2025
• Accepts healthy volunteers: Accepts Healthy Volunteers
• Gender: All
• Age group: 8 Years to 80 Years

Eligibility

Inclusion Criteria:

Normal subjects:

• normal vestibular-oculomotor exams
• normal low-frequency standard rotational testing
• normal hearing

Vestibular Schwannoma:

• existence of unilateral vestibular schwannoma (pre & post surgical resection)
• must have sub-occipital surgical approach with complete sectioning of the vestibular nerve
• rotational testing to assess pre-surgical vestibular function
• audiogram
• brain MRI consistent with vestibular schwannoma
• audiography in each ear Exclusion Criteria: Normal subjects
• history of otologic or neurologic disease
• on vestibular suppressant medication (benzodiazepine, antihistamine, anticholinergic) Vestibular Schwannoma
• other otologic disease (other than presbycusis) or any neurologic disease (other than migraine)
• on vestibular suppressant medication (benzodiazepine, antihistamine, anticholinergic)

Related Conditions & MeSH terms

• Dizziness
• Ear Diseases
• Inner Ear Disease
• Labyrinth Diseases
• Labyrinthitis
• Neurilemmoma
• Neurofibromatoses
• Neurofibromatosis 2
• Neuroma, Acoustic
• Vestibular Diseases
• Vestibular Disorder
• Vestibular Schwannoma

Intervention

Behavioral:
• VOR precision training
Subjects are rotated in yaw using a pseudo-random sum of sines motion (0.5 - 2.0 Hz), view a monitor 1 m away, and are instructed to move their avatar through a maze using a joystick. The size of the maze becomes smaller in real-time when they are successful so that the patient is at the limit of their acuity. This task requires patients to optimize dynamic visual acuity to threshold-level images while rotating. We predict that VOR precision will gradually improve during training and that after training VOR precision will be better than the pre-training data. The sham task is as above but the acuity required to see the maze will set at a much larger level so baseline visual precision will be adequate to perform the task easily.

Locations

Country	Name	City	State
United States	Massachusetts Eye and Ear Infirmary	Boston	Massachusetts

Sponsors (1)

Lead Sponsor	Collaborator
Massachusetts Eye and Ear Infirmary

Country where clinical trial is conducted

United States, 

Outcome

Type	Measure	Description	Time frame	Safety issue
Primary	Change in perceptual thresholds	Measurements of motion perception thresholds (yaw for rotational tasks, roll tilt for tilt task) before and after training.	baseline and post-training (1 hour)
Primary	Change in rapid measure of gait	This measure is scored before and after VOR precision training in UVD (unilateral vestibular dysfunction) patients. Gait is scored by performance on a task derived from the FGA (walking 40 feet while turning the head from side to side). It is scored on a 0 to 10 visual scale and provides a rapid assessment of vestibular function pre and post adaptation.	baseline and post-training (1 hour)
Primary	Change in measure of inducible dizziness	Looking at the change between before and after VOR precision training in UVD (unilateral vestibular dysfunction) patients. Inducible dizziness is the symptom severity provoked by a task derived from the FGA (walking 40 feet while turning the head from side to side). It is scored on a 0 to 10 visual scale and provides a rapid assessment of vestibular function pre and post adaptation.	baseline and post-training (1 hour)