The vestibulo-ocular reflex (VOR) induces a compensatory movement in the eye when the head is rotated, to maintain stable vision when we move. It originates in the peripheral vestibular system, which detects head movements. It is particularly effective for rapid head movements, as tested in the Head Impulse Test (HIT). In acute unilateral vestibular deficit (AUVD), the VOR deficit is compensated for by a substitution saccade, more commonly known as catch up saccade, that contribute to refocus the gaze and maintain vision during head rotations. Recent technological advances have made it possible to make high-quality recordings during HIT (video Head Impulse Test, vHIT), leading to the identification of substitution saccades of variable latency. Our team has shown that saccades of shorter latency lead to better visual function (Hermann et al., 2017) and that the cerebellum is involved in the development of these saccades (Hermann et al., 2023), suggesting a learning effect rather than the de novo appearance of particular saccades. The main hypothesis of this study is that the mechanisms underlying short-latency substitution saccades, which seems to guarantee good functional recovery, depend on learning occurring from the first days after an acute unilateral vestibular deficit. We also hypothesise that early physiotherapeutic rehabilitation of the VOR under Head Impulse Test conditions would promote this learning process and the development of early catch-up saccades. One of the causes of AVD is the resection of cochleovestibular schwannomas. This procedure involves a neurotomy, i.e. complete vestibular deafferentation, which is precisely known due to the scheduled nature of the surgery. The exact moment of onset of vestibular damage is therefore known, unlike other vestibular pathologies. Hospitalisation is necessary in the immediate aftermath of surgery, with the presence of physiotherapists on the wards. In addition, there is no spontaneous recovery of the vestibular deficit. These patients therefore represent the ideal acute unilateral vestibular deficit model for testing our hypothesis. Two studies using vHIT in the aftermath of vestibular schwannoma resection surgery (Pogson et al. 2022; Mantokoudis et al. 2014) also allow us to confirm the safety and feasibility of our protocol in this patient population.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
DOUBLE
Enrollment
26
These are gaze stabilisation exercises under vHIT control, between post-operative days 1 to 6. The patient sits facing a wall 2 metres away. The investigator places the vHIT device on the participant's head and ensures that it fits properly. This is followed by an initial calibration phase (the patient must follow a laser dot with his eyes). Then comes stimulation phase: the investigator, standing behind the patient, places his hands on the sides of the patient's lower jaw, which he is asked to clench. The investigator asks the subject to stare at a visual target on the wall in front of the patient. The investigator then performs a series of low-amplitude, high-speed head movements in the plane of the lateral canals and on the side of the vestibular deficit. The patient is encouraged to resume fixation of the visual target as quickly as possible. For each treatment session, patients should perform a minimum of 10 impulses and a maximum of 30 impulses on the deafferented side. Each
These are visually guided saccade exercises under vHIT device control but without head movements (saccade module), between post-operative days 1 to 6. For this sham treatment, the modalities are identical to the experimental treatment session, up to the calibration phase described above. For the stimulation phase, the investigator, standing behind the patient, places his hands on the sides of the patient's lower jaw, which he is asked to clench. The investigator asks the subject to stare at a visual target on the wall in front of the patient. The target then jumps horizontally to trigger visually guided saccades or slides horizontally to trigger an eye-tracking movement. The investigator stabilises the patient's head to prevent any head movement. The patient is encouraged to resume or maintain fixation of the visual target as quickly as possible. A minimum of 5 horizontal saccade sequences and 5 horizontal eye-tracking sequences will be performed. Each training session lasts approxi
Pierre Wertheimer Hospital - Neurological Hospital
Bron, France
RECRUITINGFirst Substitution Saccade Latency after treatment
Mean latencies (in milliseconds) of the first substitution saccade assessed by vHIT examination, in both groups. Eye movements are recorded during the vHIT examination, carried out by one of the expert practitioners (physiotherapist or doctor) investigating the study. Data from the vHIT are extracted, enabling offline analysis of oculomotor parameters, including the latency of the first substitution saccade in milliseconds. These analyses are carried out off-line by the principal investigator, who was trained and experienced in this type of analysis, using software that allowed standardised and automated analysis, blinded to the group.
Time frame: Day 7
First Substitution Saccade Latency during the First Week
Mean latencies (in milliseconds) of the first substitution saccade assessed by vHIT examination, in the experimental group. This secondary outcome measure is analysed using the same method described for Main Outcome
Time frame: Everyday from post-surgery Day 1 to Day 6
First Saccade Latency after treatment (follow-up)
Mean latencies (in milliseconds) of the first substitution saccade assessed by vHIT examination, for both groups This secondary outcome measure is analysed using the same method described for Main Outcome
Time frame: At post-surgery Day 45 and 3rd month
First saccades amplitude after treatment
Mean amplitudes (degrees) of the first substitution saccade assessed by vHIT examination, in both groups. Eye movements are recorded during the vHIT examination, carried out by one of the expert practitioners (physiotherapist or doctor) investigating the study. Data from the vHIT are extracted, enabling offline analysis of oculomotor parameters, including the amplitude of the first substitution saccade in milliseconds. These analyses are carried out off-line by the principal investigator, who was trained and experienced in this type of analysis, using software that allowed standardised and automated analysis, blinded to the group.
Time frame: Post surgery Day 7, Day 45 and 3rd month
First saccades amplitude during first week
Mean amplitudes (degrees) of the first substitution saccade assessed by vHIT examination, in the experimental group This secondary outcome measure is analysed using the same method described for Main Outcome.
Time frame: Everyday from post-surgery Day 1 to Day 6
Balance and gait assessment
Score of the modified Dynamic Gait index (m-DGI), in both groups.
Time frame: At Day -1 (pre-surgery), and post-surgery Day 7, Day 45 and 3rd Month
Quality of Life Assessment
Score of the self administered Dizziness handicap Inventory (DHI), in both groups.
Time frame: At Day -1 (pre-surgery), and post-surgery Day 7, Day 45 and 3rd Month
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