Vestibular Disorder Clinical Trial
Official title:
Electrical Stimulation of the Peripheral Vestibular System in Order to Develop a Vestibular Implant
This study has three main goals (1) to explore the effects of electrical stimulations of the peripheral vestibular system(2) to assess the potential of this technique to rehabilitate basic vestibular functions in patients with severe bilateral vestibulopathy, and (3) to take advantage of the unprecedented experimental paradigm provided by the vestibular implant to increase our fundamental knowledge on the contribution of peripheral vestibular function to posture, gait and higher order sensory functions, mechanisms that remain poorly understood.
| Status | Recruiting |
| Enrollment | 52 |
| Est. completion date | December 31, 2023 |
| Est. primary completion date | December 31, 2023 |
| Accepts healthy volunteers | Accepts Healthy Volunteers |
| Gender | All |
| Age group | 18 Years and older |
| Eligibility | Inclusion Criteria: - Patients implanted with a vestibular implant showing neither auditory function nor vestibular one. - Control group of patients implanted with a cochlear implant and presenting a normal vestibular function. - Control group of patients with bilateral vestibular loss. - Control group of patients with unilateral vestibular loss and finally - Control group of healthy subjects with normal auditory and vestibular functions. All sujbects included in the study will be older than 18 years old. Exclusion Criteria: - Children - Patients suffering from blindness, - Patients suffering from major ophtalmologic damage - Patients suffering from neurologic disorder. |
| Country | Name | City | State |
|---|---|---|---|
| Switzerland | Geneva University Hospitals | Geneva |
| Lead Sponsor | Collaborator |
|---|---|
| Nils Guinand | Maastricht University Medical Center, Massachusetts Eye and Ear Infirmary, University of Geneva, Switzerland |
Switzerland,
Boutabla A, Cavuscens S, Ranieri M, Crétallaz C, Kingma H, van de Berg R, Guinand N, Pérez Fornos A. Simultaneous activation of multiple vestibular pathways upon electrical stimulation of semicircular canal afferents. J Neurol. 2020 Dec;267(Suppl 1):273-284. doi: 10.1007/s00415-020-10120-1. Epub 2020 Aug 10. — View Citation
Crétallaz C, Boutabla A, Cavuscens S, Ranieri M, Nguyen TAK, Kingma H, Van De Berg R, Guinand N, Pérez Fornos A. Influence of systematic variations of the stimulation profile on responses evoked with a vestibular implant prototype in humans. J Neural Eng. 2020 Jun 12;17(3):036027. doi: 10.1088/1741-2552/ab8342. — View Citation
Fornos AP, van de Berg R, Armand S, Cavuscens S, Ranieri M, Crétallaz C, Kingma H, Guyot JP, Guinand N. Cervical myogenic potentials and controlled postural responses elicited by a prototype vestibular implant. J Neurol. 2019 Sep;266(Suppl 1):33-41. doi: 10.1007/s00415-019-09491-x. Epub 2019 Aug 8. — View Citation
Guinand N, Van de Berg R, Cavuscens S, Ranieri M, Schneider E, Lucieer F, Kingma H, Guyot JP, Pérez Fornos A. The Video Head Impulse Test to Assess the Efficacy of Vestibular Implants in Humans. Front Neurol. 2017 Nov 14;8:600. doi: 10.3389/fneur.2017.00600. eCollection 2017. — View Citation
Guinand N, Van de Berg R, Cavuscens S, Stokroos R, Ranieri M, Pelizzone M, Kingma H, Guyot JP, Pérez Fornos A. Restoring Visual Acuity in Dynamic Conditions with a Vestibular Implant. Front Neurosci. 2016 Dec 22;10:577. doi: 10.3389/fnins.2016.00577. eCollection 2016. — View Citation
Guinand N, van de Berg R, Cavuscens S, Stokroos RJ, Ranieri M, Pelizzone M, Kingma H, Guyot JP, Perez-Fornos A. Vestibular Implants: 8 Years of Experience with Electrical Stimulation of the Vestibular Nerve in 11 Patients with Bilateral Vestibular Loss. ORL J Otorhinolaryngol Relat Spec. 2015;77(4):227-240. Epub 2015 Sep 15. — View Citation
Nguyen TAK, Cavuscens S, Ranieri M, Schwarz K, Guinand N, van de Berg R, van den Boogert T, Lucieer F, van Hoof M, Guyot JP, Kingma H, Micera S, Perez Fornos A. Characterization of Cochlear, Vestibular and Cochlear-Vestibular Electrically Evoked Compound Action Potentials in Patients with a Vestibulo-Cochlear Implant. Front Neurosci. 2017 Nov 21;11:645. doi: 10.3389/fnins.2017.00645. eCollection 2017. — View Citation
Pelizzone M, Fornos AP, Guinand N, van de Berg R, Kos I, Stokroos R, Kingma H, Guyot JP. First functional rehabilitation via vestibular implants. Cochlear Implants Int. 2014 May;15 Suppl 1:S62-4. doi: 10.1179/1467010014Z.000000000165. — View Citation
Perez Fornos A, Cavuscens S, Ranieri M, van de Berg R, Stokroos R, Kingma H, Guyot JP, Guinand N. The vestibular implant: A probe in orbit around the human balance system. J Vestib Res. 2017;27(1):51-61. doi: 10.3233/VES-170604. — View Citation
Perez Fornos A, Guinand N, van de Berg R, Stokroos R, Micera S, Kingma H, Pelizzone M, Guyot JP. Artificial balance: restoration of the vestibulo-ocular reflex in humans with a prototype vestibular neuroprosthesis. Front Neurol. 2014 Apr 29;5:66. doi: 10.3389/fneur.2014.00066. eCollection 2014. — View Citation
van de Berg R, Guinand N, Nguyen TA, Ranieri M, Cavuscens S, Guyot JP, Stokroos R, Kingma H, Perez-Fornos A. The vestibular implant: frequency-dependency of the electrically evoked vestibulo-ocular reflex in humans. Front Syst Neurosci. 2015 Jan 20;8:255. doi: 10.3389/fnsys.2014.00255. eCollection 2014. — View Citation
* Note: There are 11 references in all — Click here to view all references
| Type | Measure | Description | Time frame | Safety issue |
|---|---|---|---|---|
| Primary | Change in Vestibular Ocular Reflex (VOR) amplitude | The canal function of the vestibular system is evaluated based on the VOR measurement.The participant is sited and wearing goggles with movement sensors allowing to measure head movement and a camera to record eyes movements (lightweight infrared eye tracker with built in 6 degree of freedom inertial measurement unit i.e eyeseecam). A trained examiner generates randomized head pulses toward the left or the right while the participant has to stare at a target in front of him. The ratio between head and eyes velocity (amplitude or "gain") is then calculated. | Immediately after the vestibular electrodes are activated | |
| Primary | Change in Vestibular Ocular Reflex (VOR) threshold | The canal function of the vestibular system is evaluated based on the VOR measurement.The participant is sited and wearing goggles with movement sensors allowing to measure head movement and a camera to record eyes movements (lightweight infrared eye tracker with built in 6 degree of freedom inertial measurement unit i.e eyeseecam). An electrical stimulation is generated using the vestibular implant and the velocity threshold for VOR is then quantified. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in pure tone audiometry measurements | Pure tone audiometry presents pure (one-frequency) tones to each ear and determines the threshold of hearing for the participant. This test is performed in a sounfproof cabin with the patient sited. | Immediately after the cochlear and/or vestibular electrodes are activated | |
| Primary | Changes in speech audiometry measurements | The participant is sited in a soundproof cabin while wearing headphones. The participant hears a recording of a list of common words spoken at different volumes and is asked to repeat those words. | Immediately after the cochlear and/or vestibular electrodes are activated | |
| Primary | Changes in logatomes test results | Logatomes are nonsense syllables used for analyzing the confusion of phonemes.The participant is sited in a soundproof cabin while wearing headphones. The participant hears a recording of a list of logatomes with a structure of consonant-vowel-consonant (c-v-c) and vowel-consonant-vowel (v-c-v) and is asked to repeat those logatomes. | Immediately after the cochlear and/or vestibular electrodes are activated | |
| Primary | Changes in the Temporal Binding Window (TBW) | Different combinaisons of auditory, visual and vestibular stimuli are used to determine the respective TBW. The participants are sited in a chair and presented with two different stimuli. They are then asked which stimulus comes first. In patients implanted with a VI, the investigators specifically stimulate the vestibular system and pair this stimulation to a visual or auditory one. The time interval between the two stimuli is progressively decreased until they are percieved as simultaneous. It is thus possible to calculate the TBW. | Immediately after the cochlear and/or vestibular electrodes are activated | |
| Primary | Changes in the Auditory and Vestibular evoked potentials (AEPs-VEPs) | The participant is sited with eyes open. Electrophysiological responses are recorded during the presentation of brief and controlled stimulus. In subjects with a vestibular implant the evoked potentials are recorded following an electrical vestibular stimulation. An electrical cochlear stimulation is used for subjects with a cochlear implant. In healthy controls a brief sound or bone vibration is used. | Immediately after the cochlear and/or vestibular electrodes are activated | |
| Primary | Changes in the cortical and subcortical activity | Electroencephalography (EEG) is a brain exploratory method the investigators will use to estimate the latency of evoked cortical and subcortical potentials following a visual, auditory and vestibular stimulation. The electrical signals are recorded using electrodes placed on the participant scalp. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in the Vestibular Evoked Myogenic Potentials (VEMPs) | For cervical-VEMP recording, a very brief electrical stimulation of the vestibular system is applied. The participant lies on an examination table and is asked to lift his head and turn it toward the stimulation opposite side in order to contract the sternocleidomastoid muscle (SCM) whose myogenic activity is recorded using surface electrodes. The stimulus is the same for ocular-VEMP recording. The sited participant is asked to keep his gaze up and the ocular muscles myogenic activity is recorded. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in motion perception | The participant is sited in a chair anchored to a six degrees of freedom motion platform. Stimuli are different types of movements. The participant is asked to mention if he perceives a movement and if so to eventually give its direction. The statistical analyses of these answers allow to determine a perception threshold for each type of movement. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in gait dynamics while walking at different speeds | Participant is asked to walk six meters straightforward at: normal, slow, and fast auto-selected speeds as well as the fastest speed possible. Changes in three-dimensional kinematics during the different tasks will be assessed using a 12-camera optoelectronic motion capture system. Participants will be equipped with 35 reflective markers placed on specific anatomical landmarks according to the full-body. The test is performed twice per participant within a 1-week interval, to allow reliability (test-retest) analyses. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in gait dynamics performing the Timed "Up & Go" | Partipants are sited on a chair. At the "Go" of the examinor they are asked to stand up, walk for three meters, make a u-turn, come back and sit back on the chair. Changes in three-dimensional kinematics during the different tasks will be assessed using a 12-camera optoelectronic motion capture system. Participants will be equipped with 35 reflective markers placed on specific anatomical landmarks according to the full-body. The test is performed twice per participant within a 1-week interval, to allow reliability (test-retest) analyses. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in Functional Gait Assessment (FGA) performances | The FGA is used to assess postural stability during walking and assesses an individual's ability to perform multiple motor tasks while walking. The FGA comprises ten tasks during which changes in three-dimensional kinematics will be assessed using a 12-camera optoelectronic motion capture system. Participants will be equipped with 35 reflective markers placed on specific anatomical landmarks according to the full-body.The test is performed twice per subject within a 1-week interval, to allow reliability (test-retest) analyses. | Immediately after the vestibular electrodes are activated | |
| Primary | Postural changes (sway threshold and/or amplitudes) | The investgators will use a modified SMART EquiTest to implement a custom protocol developed to identify potential biomarkers of vestibular deficiency using pseudorandom stimulus waveforms to perturb balance. The device delivers continuous surface or visual surround rotations that evoke antero-posterior body sway in participants. The test starts with a 4 min warm-up in order to familiarize the participant with the environment. Then participants undergo 4-min test in 3 conditions: (1) surface-tilt stimuli with eyes closed, (2) surface-tilt with eyes open and visual surround fixed, and (3) visual surround tilt with fixed surface with all using 2° peak-to-peak stimulus amplitudes. Participants are also be equipped with a 3-DOF Head Tracker (part of the EquiTest system) continuously recording head movements in the Yaw, Pitch, and Roll planes. Postural assessments areperformed twice per participants within a 1-week interval, to allow reliability (test-retest) analyses. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in the dynamic visual acuity | During the experiments, participants have to read aloud sequences of Sloan optotypes of decreasing size displayed in a random order one at a time on a computer screen . The sequence starts with a five letters presentation at 1 logMAR (logarithm of the Minimum Angle of Resolution). If the letter recognition rate is above chance (>10%), the letter size is decreased by a step of 0.1 logMAR and five new letters are presented one at a time. The experiments is carried out on a treadmill either in statoc or in dynamic (fastest walking speed as possible) condition. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in angular error during a navigation task | Participants will perform a path integration or 'complete the triangle' virtual reality task in which the subject moves in a virtual environment toward two visual targets following each other and then has to come-back to his starting point. The angular error can then be calculated. | Immediately after the vestibular electrodes are activated | |
| Primary | Changes in orthostatic hypotension test results (Shellong test) | The subject lies on an examination table and is at rest since at least 10mn. Blood pressure and cardiac frequency are measured in lying position. At time zero the subject stands up and his blood pressure and cardiac frequency are then measured at different time points (1mn, 3mn, 5mn and 10mn after time zero). The test will be systematically performed by trained medical staff. All relevant clinical signs of the participant which could appear during the test will be documented. | Before and immediately after the vestibular electrodes are activated | |
| Primary | Changes in pupil size (pupillometry) | Using an eye tracker (EyeLink) to provide a reliable and objective measurement of pupillary size, symmetry, and reactivity through measurement of the pupil light reflex, the investigators will measure changes in pupil size before and right after the activation of the vestibular implant. | Before and immediately after the vestibular electrodes are activated |
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