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Published on in Vol 10, No 1 (2022): Jan-Mar

Preprints (earlier versions) of this paper are available at https://preprints.jmir.org/preprint/31020, first published .
Immersive Virtual Reality and Vestibular Rehabilitation in Multiple Sclerosis: Case Report

Immersive Virtual Reality and Vestibular Rehabilitation in Multiple Sclerosis: Case Report

Immersive Virtual Reality and Vestibular Rehabilitation in Multiple Sclerosis: Case Report

Authors of this article:

Cristina García-Muñoz1 Author Orcid Image ;   María-Dolores Cortés-Vega1 Author Orcid Image ;   Juan-Carlos Hernández-Rodríguez2 Author Orcid Image ;   Lourdes M Fernández-Seguín1 Author Orcid Image ;   Isabel Escobio-Prieto1 Author Orcid Image ;   María Jesús Casuso-Holgado1 Author Orcid Image
Article Authors Cited by (6) Tweetations (6) Metrics

    Case Report

    1Department of Physiotherapy, Faculty of Nursing, Physiotherapy and Podiatry, University of Seville, Seville, Spain

    2Department of Dermatology, Hospital Universitario Virgen del Rocío, Seville, Spain

    *all authors contributed equally

    Corresponding Author:

    María-Dolores Cortés-Vega, PhD

    Department of Physiotherapy

    Faculty of Nursing, Physiotherapy and Podiatry

    University of Seville

    C/ Avicena S/N

    Seville, 41009

    Spain

    Phone: 34 954486528

    Fax:34 954486527

    Email: mdcortes@us.es


    Background: Dizziness and imbalance are common and disabling symptoms in patients with multiple sclerosis (MS) and are caused by a central, peripheral, or mixed vestibulopathy. Central vestibular disorder is the most frequently reported vestibular problem in the MS population due to demyelination. Vestibular rehabilitation ameliorates these symptoms and their repercussions and improves quality of life. Immersive virtual reality (VRi) is an emerging tool in this field; however, no previous research has been performed studying its effects in MS.

    Objective: The aim of this study was to apply a VRi vestibular training protocol to a patient with MS and assess the effects induced by the experimental intervention.

    Methods: This case study included a 54-year-old woman with relapsing-remitting MS. We developed a standardized VRi exercise protocol for vestibular rehabilitation based on the gold-standard Cawthorne-Cooksey vestibular training protocol. The 20-session intervention was made up of 10 initial sessions and 10 advanced sessions. Each 50-minute session was performed two to three times per week for 7 weeks. Four evaluations were carried out over the study period: at baseline (T0), between initial and advances phases (T1), postintervention (T2), and 1 month after the experimental procedure (T3). The research outcomes were dizziness, balance, gait, impact of fatigue, quality of life, repercussions in muscular tone, and usability of the head-mounted display device.

    Results: After implementing the VRi vestibular protocol, improvements were seen in the following patient parameters: Dizziness Handicap Inventory score (62 points at T0; 4 points at T2); Berg Balance Scale score (47 points at T0; 54 points at T2); instrumented Timed Up and Go time (8.35 seconds at T0; 5.57 seconds at T2); muscular tone of the erector spinae, rectus femoris, and soleus; Modified Fatigue Impact Scale score (61 points at T0; 37 points at T2); and Multiple Sclerosis Quality of Life-54 values (67.16% in the physical health area at T2; 33.56% in the mental health area at T2). The patient rated the usability of the system as 90%, based on the System Usability Scale, and gave the system a grade of A.

    Conclusions: Although further research is needed, this study provided initial evidence that the first VRi vestibular protocol for the MS population can improve dizziness, balance, gait, impact of fatigue, quality of life, and muscular tone through an exergame intervention. This study may help establish a standardized VRi protocol for vestibular rehabilitation.

    JMIR Serious Games 2022;10(1):e31020

    doi:10.2196/31020

    Keywords

    immersive virtual realityvestibular rehabilitationmultiple sclerosisexergames 


    Relapsing-remitting multiple sclerosis (RRMS) is the most frequent phenotype of multiple sclerosis (MS) and is characterized by relapse or attacks [1,2]. Among the symptoms or sequelae of relapse are vertigo, dizziness, and postural balance disorders [3]. Vertigo is defined as a rotative illusion that can affect 20% to 50% of patients with MS along the disease course [4,5]. Dizziness is usually accompanied by balance problems and affects 49% to 59% of patients with MS [6]. Central, peripheral, or mixed vestibular disorders are possible etiologies in patients with MS, which explain the presence of dizziness, vertigo, and postural disorders [5,7,8]. In spite of the peripheral affection of the vestibular system being quite common in MS, central vestibular disorder is the most common due to the demyelination process in MS [8,9]. The scientific literature has reported that the MS population could benefit from the effects on dizziness and postural balance of vestibular rehabilitation, whether the vestibular lesion is central, peripheral, or a combination of the two [10]. Vestibular rehabilitation involves exercises targeted to improve vertigo, dizziness, and imbalance and its repercussions during basic activities of daily living [11]. Vestibular exercises are performed to train the vestibulo-ocular reflex (VOR) and vestibulo-spinal reflex (VSR), promoting the neuroplastic mechanisms of adaptation, habituation, and substitution [12,13]. Adaptation will train the VOR through head and ocular movements. Habituation aims to eliminate dizziness symptoms by exposing the subject to several environments and repetitive exercises. Substitution compensates for vestibular deficits through visual or somatosensory systems [14,15].

    An emerging tool within vestibular rehabilitation and neurorehabilitation is immersive virtual reality (VRi) [16,17], which immerses patients through a head-mounted display (HMD) in a 360° virtual environment and enables interactions for achieving a specific objective [18]. Some of the advantages of VRi in rehabilitation are the direct auditory and visual feedback provided to the patient, multitasking, a wide variety of environments, and the sense of presence and immersion [18-21]. Exergames are a combination of exercises and video games; these are the principal choice of intervention in VRi for improving the physical condition of users [22,23]. Exergames provide task-oriented training, motivation, and distraction during exercise [22,24]. A recent systematic review reported these additional clinical benefits from VRi compared to conventional vestibular rehabilitation [25]. The same study supported the need for designing a standardized VRi vestibular intervention protocol [25-27].

    Regarding the absence of a VRi vestibular exercise program for the MS population and the need to achieve a standardized VRi protocol for vestibular rehabilitation, we chose to design and develop both a program and a protocol. To the best of our knowledge, this is the first VRi vestibular exercise protocol for the MS population. Thus, the primary goal of research was to apply this innovative intervention and evaluate its effects on dizziness and balance in a patient with RRMS. Changes in gait parameters, the impact of fatigue, quality of life, muscular tone repercussion, and usability were assessed as secondary objectives.


    Ethics Statements

    Ethical approval was provided by the Regional Ethical Review Board in Andalucía, Spain, on March 25, 2020 (ID 2148-N-19). Before recruitment, the participant was provided with written and oral information. Informed consent, which adhered to the principles of the Declaration of Helsinki, was given by the subject in order to be included in the experimental intervention.

    Outcomes and Measurements

    Four evaluations of the following five outcomes were performed to detect changes in the patient: dizziness, postural balance, gait parameters, fatigue impact, and quality of life. These assessments were carried out at baseline (T0), between initial and advanced phases (T1), postintervention (T2), and 1 month after the experimental procedure (T3). After VRi, the vestibular protocol usability of the Oculus Quest HMD (Facebook Technologies) was measured using the System Usability Scale (SUS) and a semistructured interview.

    Patient Information

    The participant was a 54-year-old woman who was diagnosed with RRMS in 2013 by an expert neurologist and met the McDonald diagnostic criterion. The patient’s Mini-Mental State Examination score was 25 out of 30 due to a memory impairment caused by an MS attack. Her Expanded Disability Status Scale score was 3.0 out of 10.0, which indicated that ambulation was preserved without a walking aid. In 2019, she suffered from an MS attack combined with vertigo and nausea, which lasted more than 24 hours and was unassociated with a specific postural position of onset. Furthermore, in a posterior magnetic resonance imaging (MRI) scan, demyelinating lesions were observed on the right lateral margin of the fourth ventricle, where vestibular nuclei are located [28]. This MRI finding could be related to the vertigo episode. Considering the duration and characteristics of the vertigo episode, along with a negative semicircular canal affection dismissed by the Dix-Hallpike maneuver and Miniconi test, a central vestibular disorder was confirmed. At the initial evaluation, the participant reported severe dizziness (62/100 points) as assessed by the Dizziness Handicap Inventory (DHI) [29,30], accompanied by postural problems and a reluctance to move her head while walking or performing abrupt cephalic movements. Balance examination was carried out through the Berg Balance Scale (BBS) [31], where the participant obtained a total of 47 out of 56 points. It is necessary to highlight the existence of a pronounced imbalance in three specific conditions of the scale: Romberg with closed eyes, tandem position, and single-leg support. The patient was unable to reach or maintain the first two conditions, and she was only able to stand for less than 10 seconds during the last one. A combined analysis by inertial sensors—myoMOTION inertial sensors and software (Noraxon)—and the instrumented Timed Up and Go (iTUG) test [32,33] was carried out to determine the baseline gait parameters of the patient with RRMS. The iTUG global time was 8.35 seconds; the iTUG times for the first and second 180° turns were 0.90 seconds and 0.69 seconds, respectively. Additionally, the sit-to-stand transition time was 1.20 seconds, and the stand-to-sit transition time was 1.03 seconds. The mean gait speed was 1.2 km per hour, and the step cadence was 106 steps per minute. The complete analysis of the gait parameter data is shown in the Results section. The patient’s perceived fatigue impact was 61 out of 84 points on the Modified Fatigue Impact Scale (MFIS) [34]. Quality of life before the experimental intervention was measured using the Multiple Sclerosis Quality of Life-54 (MSQoL-54) [35]; the patient obtained a result of 45.62% for physical health and 25.75% for mental health. Bilateral muscular tone assessment in the erector spinae, the rectus femoris, and the soleus was performed using the MyotonPRO digital palpation device (Myoton AS) [36] during standing after vestibular stimulation through the Miniconi test [37]. All baseline data are listed in detail in the Results section.

    Materials and Intervention

    The Oculus Quest is a wireless VRi device with high-quality graphics that is economically affordable, as compared to other options on the market [38,39]. VRi systems work via an input and output flow (Figure 1). Inputs are recorded by a VRi headset and controllers in response to external actions of the participant; these inputs then induce changes in the virtual environment through the software. Outputs are changes in the virtual environment providing the subject with a multisensory stimulation source (ie, visual, acoustic, and vibrotactile information). Minimal requisites to start interacting with the Oculus virtual environment include a space greater than 2 × 2 meters to ensure a safe play area and a Wi-Fi connection. The experimental intervention was carried out at the participant’s home and was supervised by a therapist.

    Figure 1. Inputs and outputs in immersive virtual reality (VRi) systems.
    View this figure

    Selected VRi exergames are freely available in the Oculus App and include the following: First Steps, Beat Saber, and Sports Scramble. The environments in First Steps include the main room of First Steps, Dance with Robot, and Shots in Space. The first one is a room where the subject can interact with virtual objects (cubes, paper planes, etc). In Dance with Robot, the patient must dance while following some orders. Finally, Shots in Space is a shooter game in which the participant shoots random targets that move over a spatial station (Figure 2). Beat Saber is a rhythm game in which blocks are cut in a specific direction with sabers (Figure 3). Sports Scramble is a sports game where the user can play tennis, baseball, and bowling, with funny virtual elements (eg, a cheese ball instead of a bowling ball; Figure 4). The complete VRi vestibular intervention was carried out over 20 sessions, which occurred two to three times per week over 7 weeks. Each session lasted for 50 minutes. The VRi vestibular protocol can be divided into initial and advanced phases of 10 sessions each. All above-mentioned vestibular exercises were designed to enhance the neuroplastic mechanisms of adaptation, habituation, and substitution and to train the user’s VOR and VSR. Also, to design and create vestibular exercises for this new VRi vestibular protocol, we considered the gold-standard vestibular training from Cooksey [40] as well as key points from Han et al [12] and Whitney and Sparto [13]. Each session from both phases consisted of 15 exercises, which were performed from the easiest to the most complex. Therefore, this gradual exposure of the patient to exercises during sessions prevents the development of dizziness and cybersickness. Exercises and the duration of both phases are described in Table 1. The initial phase consisted of three blocks of exercises, two of which were done seated and the last of which was done in the standing position. Exercises in the advanced phase were performed by disturbing the somatosensory system, reducing the support base, using alternating single-leg support, adopting the tandem position, or adding an unstable surface. This was done to enhance the participation of the vestibular system in maintaining postural balance by the substitution mechanism. New vestibular parameters were added in this second phase of the intervention with quicker head and eye movements, sit-to-stand transitions or vice versa, and 360° turns.

    Figure 2. Study participant interacting with First Steps virtual environments. Main room of First Steps (top); Dance with Robot (middle); Shots in Space (bottom).
    View this figure
    Figure 3. Study participant interacting with Beat Saber environment.
    View this figure
    Figure 4. Study participant interacting with Sports Scramble virtual environments. Baseball (top); tennis (middle); bowling (bottom).
    View this figure
    Table 1. Exercises performed as part of the immersive virtual reality vestibular intervention.
    Phases and exercise instructionsVirtual environmentsDurationRepetitions
    Initial phase: 50 minutes (45 min of intervention + 5 min of rest)

    		Before rest time: 24 minutes (all First Steps environments and Beat Saber)


    		Take the ping-pong ball and put it in front of your face and move it closer and fartherMain room of First Steps11 minutesa10 slow repetitions, then 10 fast repetitions


    		Move an object in front of your eyes and follow it; shoot targets that appear in the exergameMain room and Shots in Space (First Steps)Main room: 11 minutes; Shots in Space: 7 minutesbMain room: 10 slow repetitions, then 10 fast repetitions; Shots in Space: 1 repetition for each gun


    		Shoot targets that appear randomly inside the virtual environmentShots in Space (First Steps)7 minutes1 repetition for each gun


    		Cut blocks with a saber while your head is fixed; hit a ball in the main room and fixate your gaze on its movement while your head is fixedBeat Saber and main room of First StepsBeat Saber: 3 minutes; main room: 11 minutesBeat Saber: 1 repetition; main room: 10 slow repetitions, then 10 fast repetitions


    		Take a block from the virtual desk, bring it to the floor, and then move it above your head, while staring at itMain room of First Steps11 minutes10 slow repetitions, then 10 fast repetitions


    		Shrink your shoulders while dancing with a robotDance with Robot (First Steps)3 minutes1 repetition


    		Bend forward and move a virtual block between your kneesMain room of First Steps11 minutes10 slow repetitions, then 10 fast repetitions

    		After rest time: 21 minutes (Beat Saber and Sports Scramble)


    		Sit down and stand up, and vice versa, with your eyes openBeat Saber3 minutes1 repetition


    		Stand up and move to the right while standingBowling (Sports Scramble)6 minutesc3 repetitions


    		Stand up and move to the right or the left while taking a bowling ballBowling (Sports Scramble)6 minutes3 repetitions


    		Throw or hit a ball in front of your faceBaseball and tennis (Sports Scramble)Baseball: 8 minutes; tennis: 4 minutesBaseball: 1 repetition; tennis: 1 repetition


    		Throw the ball to hit the bowling pins under knee levelBowling (Sports Scramble)6 minutes3 repetitions
    Advanced phase: 50 minutes (45 min of intervention + 5 min of rest)

    		Before rest time: 24 minutes (main room of First Steps)


    		Take a block from the virtual desk and when you stand up, throw it at a virtual sign situated inside the virtual environmentMain room of First Steps2 minutes10 repetitions


    		Move a virtual block at eye level; take a virtual block and throw it from one hand to the otherMain room of First Steps5 minutes10 repetitions moving the object, then 10 repetitions throwing the object


    		Take a virtual block, turn 360°, and throw the block to a located target in the environmentMain room of First Steps5 minutes10 repetitions to the right, then 10 repetitions to the left


    		In a standing position with a narrow base of support, hit a ball and follow its movements with your headMain room of First Steps2 minutes5 repetitions (eg, 1 repetition lasts until the ball stops)


    		Take the ping-pong ball and put it in front of your face, then move it closer and farther awayMain room of First Steps5 minutes10 slow repetitions, then 10 fast repetitions


    		Take the ping-pong racket and hit blocks to one side and the other, following them with your headMain room of First Steps2 minutes15 repetitions


    		Take a virtual block from the desk, then move it to the floor and bring it above your head while standing on a foam surfaceMain room of First Steps3 minutes10 repetitions

    		After rest time: 21 minutes (Shots in Space in First Steps, Beat Saber, and Sports Scramble)


    		Shoot targets with a single gun while supported on a single leg, then the otherShots in Space (First Steps)2 minutes1 repetition


    		Shoot targets with a double gun while maintaining a tandem positionShots in Space (First Steps)2 minutes1 repetition


    		Shoot targets with a machine gun while standing on a foam surfaceShots in Space (First Steps)2 minutes1 repetition


    		Hit and cut blocks in a specific direction with sabers while standing on a foam surface; the head is fixed while you make ocular movementsBeat Saber3 minutes1 repetition


    		Throw the ball in a baseball stadium while standing on a foam surfaceBaseball (Sports Scramble)4 minutes1 repetition


    		Bowl with your feet togetherBowling (Sports Scramble)2 minutes1 repetition


    		Bowl while standing on a foam surfaceBowling (Sports Scramble)2 minutes1 repetition


    		Walk down a bowling alley while moving your head from side to side and the throw the bowling ballBowling (Sports Scramble)4 minutes2 repetitions

    aWithin this set of exercises, all exercises in the main room of the First Steps environment combined were performed in 11 minutes.

    bWithin this set of exercises, all Shots in Space exercises combined were performed in 7 minutes.

    cWithin this set of exercises, all bowling exercises in Sports Scramble combined were performed in 6 minutes.


    All outcome results at T1, T2, and T3, as compared to T0, are shown in Table 2.

    Regarding baseline dizziness that evolved from a severe condition (DHI score = 62 points) as compared to the absence of it after the combined VRi vestibular protocol, there was a reduction of 58 points on the DHI (T2 DHI score = 4 points). This improvement in dizziness examined by the DHI continued for 1 month after the end of the VRi sessions.

    Between phases of the experimental intervention, no changes were assessed for postural balance, but balance impairments improved postintervention. The participant’s BBS score reached a maximum of 56 points at T3. Pathological conditions of Romberg with closed eyes, unstable single-leg support, and the inability to stay in the tandem position were reverted by achieving stable balance.

    The participant ameliorated their global iTUG time by 2.35 seconds after the intervention, adding 0.43 seconds to this time 1 month after the VRi program. The rest of the iTUG parameters (ie, sit-to-stand transition and vice versa and both 180° turns) showed a remarkable reduction, as observed in Table 2. Stance and swing phase equated to 50% in both feet, while double support time was 291 milliseconds less in T2 compared to baseline. The minor stride time and the higher stride length were recorded in T3 as 862 milliseconds and 63 centimeters, respectively. The speed of gait and step cadences increased by 1.4 km per hour and 45 steps per minute in T3 from T0, respectively.

    Regarding fatigue impact of the subject, a score of 38 was considered when determining the difference between fatigued and nonfatigued [41]. The MFIS score reached 35 points in T1 and 37 points in T2, which reflected a nonfatigued perception of the patient, but this improvement was not maintained 1 month after the intervention ended (MFIS score = 47 points).

    The study participant experienced a gain in physical health of 21.54%, as measured by the MSQoL-54, when baseline and postintervention data were assessed. Then, 1 month later, her physical quality of life reached 69.44%, and her mental health reached 42.79%.

    Table 2. Results and changes in study outcomes at the four measurement points.
    Outcome (measurement)Measurement point

    		Baseline (T0)Between initial and advanced phases (T1)Postintervention (T2)1 month after the experimental procedure (T3)
    Dizziness (Dizziness Handicap Inventorya), points

    		Global622646

    		Physical201846

    		Emotional14200

    		Functional28600
    Postural control (Berg Balance Scaleb), points

    		Global47475456
    Spaciotemporal parameters of gait (instrumented Timed Up and Go test)

    		Total time, seconds8.357.006.005.57

    		Sedestation to bipedestation time, seconds1.200.970.950.77

    		First turn, seconds0.900.910.790.78

    		Second turn, seconds0.690.610.580.50

    		Bipedestation to sedestation time, seconds1.030.640.580.50

    		Stance phase, left foot, %70.871.768.851.1

    		Stance phase, right foot, %70.966.365.549.6

    		Swing phase, left foot, %29.228.331.248.9

    		Swing phase, right foot, %29.133.734.550.4

    		Double support time, ms63132934079

    		Stride length, cm40465063

    		Velocity, km/h1.21.61.92.6

    		Stride time, ms12051031941862

    		Step cadence, steps/min106129298151
    Impact of fatigue (Modified Fatigue Impact Scalec), points

    		Global61353747

    		Physical effort218715

    		Cognoscitive effort36242930

    		Psychosocial effort4312
    Quality of life (Multiple Sclerosis Quality of Life-54), %

    		Physical health area45.6253.1467.1669.44

    		Mental health area25.7536.1533.5642.79
    Muscular tone (MyotonPROd), Hz

    		Right erector spinae13.012.713.112.3

    		Left erector spinae12.912.311.711.6

    		Right rectus femoris13.912.413.512.4

    		Left rectus femoris13.711.814.412.5

    		Right soleus26.323.721.921.7

    		Left soleus24.021.420.619.4
    Usability (System Usability Scale), %N/AeN/A90fN/A

    aDizziness Handicap Inventory scores range from 0 to 100 for the global scale; the physical subscale ranges from 0 to 28; the emotional and functional subscales range from 0 to 36.

    bBerg Balance Scale scores range from 0 to 56: 41-56 (low fall risk); 21-40 (medium fall risk); 0-20 (high fall risk).

    cModified Fatigue Impact Scale scores range from 0 to 84; the physical effort subscale ranges from 0 to 36; the cognoscitive effort subscale ranges from 0 to 40; the psychosocial effort subscale ranges from 0 to 8.

    dThe MyotonPRO takes three consecutive measurements and reports the final value as the mean; however, the SD is not reported.

    eN/A: not applicable; the System Usability Scale was only administered at T2.

    fA 90% value on the System Usability Scale represents a grade of A.

    A reduced trend for muscular tone was found in the MyotonPRO data for the three examined muscles. In some cases, there were disparities, primarily in the left erector spinae and bilateral rectus femoris at T2. However, all mean results for the erector spinae, the rectus femoris, and the soleus were lower at T3 compared to T0. The tone of the erector spinae was 19.2% lower for the right side and 21.2% lower for the left side when compared to baseline. Also, 1 month after the experimental intervention, decreases in tone compared to the baseline data were recorded in the rectus femoris (T3 right: –11.4%; left: –9.2%) and in the soleus (T3 right: –19.2%; left: –21.2%).

    Postintervention (T2) usability of the Oculus Quest device and perceived satisfaction with the experimental intervention was assessed using the SUS and a semistructured interview. A SUS score of 90% for usability and a grade of A were marked by the participant with RRMS for the Oculus Quest headset. During the interview process, the following impressions were reported by the patient:

    I enjoyed the intervention through the virtual device so much. I would continue with it.
    These kinds of physiotherapy sessions are more motivating than usual ones in which I get bored really soon because exercises are repetitive.
    I have improved my postural balance a lot; now I can take a shower with my eyes closed without falling or I can put my pants on without sitting down.

    Principal Findings

    The VRi vestibular training protocol was successfully performed by a participant with RRMS, improving their basal conditions of dizziness, postural balance, gait, fatigue, quality of life, and muscular tone repercussion after the intervention.

    HMDs have been described as proper tools with which to apply vestibular rehabilitation by previous studies [16,39,40]. One of the reasons why VRi devices have become a suitable option is because of their accurate tracking systems that record movements by gyroscopes, magnetometers, and accelerometers in six degrees of freedom [42]. Likewise, the control of movement, visual information, and changes in the virtual environment are broken down into cephalic movements, just as the information is provided by the vestibular system [42,43]. Furthermore, thanks to the characteristics of these devices, the neuroplastic mechanisms by which the vestibular system recovers can be trained. Among them, habituation stands out due to the large number of environments to which the subject is exposed and because of the possibility of performing repetitive exercises in a motivational way [12,13].

    Improvements in dizziness conditions measured by the DHI have been reported before by Micarreli et al [44] and Viziano et al [45] in peripheral vestibular impairments after combined VRi and vestibular rehabilitation. In these studies, the HMD intervention was implemented using a smartphone; however, commercial HMDs, such as the Oculus Quest, present higher usability and graphic quality compared to these devices [46,47]. Both groups of researchers implemented home-based virtual reality (VR) vestibular programs combined with conventional vestibular therapy in their experimental groups to ensure adherence to treatment. The adherence and security related to these home-based exercise VR programs should be studied deeply [48]. Even though the selected VR devices were wireless and portable, the home-based intervention was discarded. Despite the intervention being performed at the subject’s home due to their physiological characteristics (ie, imbalance and dizziness) and progression of exercises (unstable surface, tandem, etc), the therapist needed to be next to the patient to prevent falls. Also, due to her memory problems, adherence to treatment was not guaranteed, which also required monitoring, as described by Micarreli et al [44] and Viziano et al [45].

    Moreover, dizziness is related to imbalance or postural problems, like positive Romberg with closed eyes, unstable single-leg support, or difficulty in the tandem position. Equally, dizziness during cephalic movements while walking is one of the main clinical manifestations in vestibular disorders [49]. Global postural control ameliorated after the VRi intervention was conducted. BBS scores increased by 7 points when comparing measurements at T2 with those at T0, and the maximum score was reached 1 month later by the participant. Once the intervention finished, the patient with RRMS was able to stand in the eyes-closed Romberg position and maintain single-leg support and the tandem position for more than 30 seconds. Ozkul et al [50] confirmed better results in postural balance after an experimental intervention with the Oculus Quest HMD after 16 sessions, as compared to conventional balance training. However, this author did not examine vestibular rehabilitation effects; reported results were similar to those obtained in this case report. In the vestibular framework, Yeh et al [51] and Hsu et al [52] reported better balance performance assessed by posturography in Meniérè disease (ie, peripheral disorder) after a VR vestibular intervention that combined Wii, Kinect, a smartphone HMD, and big screens. Better balance and dizziness were reported by Hsu et al [52] in VR groups compared to groups performing Cawthorne-Cooksey traditional exercises (P<.001).

    To the best of our knowledge, this is the first study to examine gait parameters in a subject with MS to evaluate changes caused by vestibular training. Gait parameter assessment was carried out because of its remarkable role during walking [53]. The higher gait speed and step cadence during the iTUG test seen in this case study could be related to enhancement of the postural balance of the subject, due to a better vestibular function [54]. A reduction in double stance time could also be explained by the greater performance of the vestibular system [55]. Other studies based on vestibular training for peripheral vestibular problems support the gait data we collected during the iTUG test for global time [56,57]. According to Witchel et al [58], a lower sit-to-stand transition time could be related to greater balance performance, as reported in our case study. Additionally, a vestibular intervention has been shown to be effective in the achievement of a shorter time to perform 180° turns as measured by the iTUG test [59]. In this case study, there was a reduction of 0.11 seconds in both turns after the experimental intervention.

    Fatigue is one of the most disabling symptoms among patients with MS and can contribute to postural disorders or a worse performance in the iTUG test [60,61]. In this case, better results in the iTUG test and balance could be related to lower fatigue impact. Vestibular rehabilitation and VR interventions have shown positive effects on fatigue impact in people with MS [50,62]. Dizziness, postural balance impairments, and fatigue are considered the most disturbing symptoms affecting patients’ quality of life [63]. Therefore, after improvement in the above-mentioned symptoms, an increase in quality of life, as measured by the MSQoL-54, was registered in this participant; this was also seen in Ozgen et al [56]. In the Ozgen et al study, after 16 sessions (20 minutes per session) of vestibular balance and ambulation exercises to ameliorate vestibular disturbances in a sample of patients with MS, an improvement in quality of life was recorded within the group, as compared to no intervention (P<.001) [56].

    Regarding muscular tone repercussion after VRi vestibular training, disparities obtained in the left erector spinae and rectus femoris at the end of the intervention might have been related to the demyelination process that is characteristic of patients with MS, which alters VSR [64]. Also, the general reduction of muscular tone found in the aforementioned muscles may be explained by better balance performance and decreasing VSR activity, according to Forbes et al [65,66].

    Lubetzky et al [67] declared acceptable usability (73% in the SUS) for the forerunner of the Oculus Quest, as compared to 90% usability reported by our participant. Furthermore, that author confirmed that the existence of wires reduced immersion and the presence of the users within the VRi environment. This problem is solved with the wireless Oculus Quest HMD. Additionally, thanks to the selected HMD and the design of our vestibular exercises, intrinsic Cawthorne-Cooksey protocol limitations can be addressed. These limitations are overcome by adopting a multimodal approach, providing extrinsic feedback, task-oriented focus, and exposure to different environments [68,69]. Also, considering the VRi vestibular protocol design and the portable and wireless HMD device, one future field of research could be telerehabilitation strategies. This field of study is still poorly investigated regarding vestibular rehabilitation and VR.

    Limitations and Strengths

    The main limitations of this study were derived from the study design; thus, selection bias may have been present, and it is not possible to establish cause-and-effect relationships nor to make general statements regarding the MS population. Another limitation would be the question as to whether this intervention would be favorable in all phenotypes of MS or in central, peripheral, or mixed vestibular disorders. Because of this, the results must be interpreted with caution. To provide additional scientific evidence, a randomized controlled trial will be performed.

    A principal strength of this study is that it provides the first standardized VRi vestibular training protocol for an MS population. Thanks to the design of the exercises and the characteristics of the selected HMD, the limitations of the gold-standard Cawthorne-Cooksey protocol are overcome. This innovative VRi vestibular protocol was designed to allow its implementation at clinic, hospital, and home and as a telerehabilitation strategy. In addition to the expected effects of vestibular rehabilitation, this protocol shows benefits from VRi. Lastly, the selected exergames are freely available, which allows professionals who have HMD devices to implement this VRi vestibular protocol without additional costs.

    Conclusions

    The first standardized VRi vestibular protocol based on a gold-standard protocol was carried out on a subject with RRMS. The protocol showed promising results for dizziness, postural balance, gait, fatigue, and quality of life after the experimental intervention, although the results should be interpreted with caution due to the design of the study. The intervention described in this case study could set a precedent for future VRi vestibular interventions for vestibular disorders, specifically in the MS population. To achieve solid results in relation to this innovative protocol, it is necessary for further research to be conducted, such as a randomized controlled trial. Another future approach that could evaluate the effects of this VRi vestibular intervention would be a telerehabilitation strategy.

    Authors' Contributions

    CGM, MDCV, and MJCH conceptualized and designed the study and the intervention. CGM recruited the study participant. MDCV assessed the clinical outcomes. MJCH analyzed the participant data. CGM wrote the first draft of the manuscript with critical input from MDCV and MJCH. MDCV, MJCH, JCHR, LMFS, and IEP contributed significantly to the revision of the manuscript. All authors read and approved the final version of the manuscript.

    Conflicts of Interest

    None declared.

    1. Kalincik T. Multiple sclerosis relapses: Epidemiology, outcomes and management. A systematic review. Neuroepidemiology 2015;44(4):199-214 [FREE Full text] [CrossRef] [Medline]
    2. Kantarci OH. Phases and phenotypes of multiple sclerosis. Continuum (Minneap Minn) 2019 Jun;25(3):636-654. [CrossRef] [Medline]
    3. Oh J, Vidal-Jordana A, Montalban X. Multiple sclerosis: Clinical aspects. Curr Opin Neurol 2018 Dec;31(6):752-759. [CrossRef] [Medline]
    4. Chan Y. Differential diagnosis of dizziness. Curr Opin Otolaryngol Head Neck Surg 2009 Jun;17(3):200-203. [CrossRef] [Medline]
    5. Karatas M. Central vertigo and dizziness: Epidemiology, differential diagnosis, and common causes. Neurologist 2008 Nov;14(6):355-364. [CrossRef] [Medline]
    6. Marrie RA, Cutter GR, Tyry T. Substantial burden of dizziness in multiple sclerosis. Mult Scler Relat Disord 2013 Jan;2(1):21-28. [CrossRef] [Medline]
    7. Frohman EM, Zhang H, Dewey RB, Hawker KS, Racke MK, Frohman TC. Vertigo in MS: Utility of positional and particle repositioning maneuvers. Neurology 2000 Nov 28;55(10):1566-1569. [CrossRef] [Medline]
    8. Zeigelboim BS, Arruda WO, Mangabeira-Albernaz PL, Iório MCM, Jurkiewicz AL, Martins-Bassetto J, et al. Vestibular findings in relapsing, remitting multiple sclerosis: A study of thirty patients. Int Tinnitus J 2008;14(2):139-145. [Medline]
    9. Frohman EM, Kramer PD, Dewey RB, Kramer L, Frohman TC. Benign paroxysmal positioning vertigo in multiple sclerosis: Diagnosis, pathophysiology and therapeutic techniques. Mult Scler 2003 Jun;9(3):250-255. [CrossRef] [Medline]
    10. García-Muñoz C, Cortés-Vega M, Heredia-Rizo AM, Martín-Valero R, García-Bernal M, Casuso-Holgado MJ. Effectiveness of vestibular training for balance and dizziness rehabilitation in people with multiple sclerosis: A systematic review and meta-analysis. J Clin Med 2020 Feb 21;9(2):590 [FREE Full text] [CrossRef] [Medline]
    11. Alghadir AH, Iqbal ZA, Whitney SL. An update on vestibular physical therapy. J Chin Med Assoc 2013 Jan;76(1):1-8 [FREE Full text] [CrossRef] [Medline]
    12. Han BI, Song HS, Kim JS. Vestibular rehabilitation therapy: Review of indications, mechanisms, and key exercises. J Clin Neurol 2011 Dec;7(4):184-196 [FREE Full text] [CrossRef] [Medline]
    13. Whitney SL, Sparto PJ. Principles of vestibular physical therapy rehabilitation. NeuroRehabilitation 2011;29(2):157-166 [FREE Full text] [CrossRef] [Medline]
    14. Herdman SJ. Vestibular rehabilitation. Curr Opin Neurol 2013;26(1):96-101 [FREE Full text] [CrossRef]
    15. Boyer FC, Percebois-Macadré L, Regrain E, Lévêque M, Taïar R, Seidermann L, et al. Vestibular rehabilitation therapy. Neurophysiol Clin 2008 Dec;38(6):479-487. [CrossRef] [Medline]
    16. Song J. Virtual reality for vestibular rehabilitation. Clin Exp Otorhinolaryngol 2019 Nov;12(4):329-330 [FREE Full text] [CrossRef] [Medline]
    17. Massetti T, da Silva TD, Crocetta TB, Guarnieri R, de Freitas BL, Bianchi Lopes P, et al. The clinical utility of virtual reality in neurorehabilitation: A systematic review. J Cent Nerv Syst Dis 2018;10:1-18 [FREE Full text] [CrossRef] [Medline]
    18. Snoswell AJ, Snoswell CL. Immersive virtual reality in health care: Systematic review of technology and disease states. JMIR Biomed Eng 2019 Sep 26;4(1):e15025 [FREE Full text] [CrossRef]
    19. Servotte J, Goosse M, Campbell SH, Dardenne N, Pilote B, Simoneau IL, et al. Virtual reality experience: Immersion, sense of presence, and cybersickness. Clin Simul Nurs 2020 Jan;38:35-43. [CrossRef]
    20. Xu W, Liang H, He Q, Li X, Yu K, Chen Y. Results and guidelines from a repeated-measures design experiment comparing standing and seated full-body gesture-based immersive virtual reality exergames: Within-subjects evaluation. JMIR Serious Games 2020 Jul 27;8(3):e17972 [FREE Full text] [CrossRef] [Medline]
    21. Winter C, Kern F, Gall D, Latoschik ME, Pauli P, Käthner I. Immersive virtual reality during gait rehabilitation increases walking speed and motivation: A usability evaluation with healthy participants and patients with multiple sclerosis and stroke. J Neuroeng Rehabil 2021 Apr 22;18(1):68 [FREE Full text] [CrossRef] [Medline]
    22. Szpak A, Michalski SC, Loetscher T. Exergaming with Beat Saber: An investigation of virtual reality aftereffects. J Med Internet Res 2020 Oct 23;22(10):e19840 [FREE Full text] [CrossRef] [Medline]
    23. Li J, Erdt M, Chen L, Cao Y, Lee S, Theng Y. The social effects of exergames on older adults: Systematic review and metric analysis. J Med Internet Res 2018 Jun 28;20(6):e10486 [FREE Full text] [CrossRef] [Medline]
    24. Mat RM, Mat RH, Davis OGM, Husain R, Hasnan N. Exergaming for individuals with neurological disability: A systematic review. Disabil Rehabil 2017 Apr;39(8):727-735. [CrossRef] [Medline]
    25. Xie M, Zhou K, Patro N, Chan T, Levin M, Gupta MK, et al. Virtual reality for vestibular rehabilitation: A systematic review. Otol Neurotol 2021 Mar 26:967-977. [CrossRef] [Medline]
    26. Meldrum D, Burrows L, Cakrt O, Kerkeni H, Lopez C, Tjernstrom F, et al. Vestibular rehabilitation in Europe: A survey of clinical and research practice. J Neurol 2020 Dec;267(Suppl 1):24-35 [FREE Full text] [CrossRef] [Medline]
    27. Bergeron M, Lortie CL, Guitton MJ. Use of virtual reality tools for vestibular disorders rehabilitation: A comprehensive analysis. Adv Med 2015;2015:916735 [FREE Full text] [CrossRef] [Medline]
    28. MacKinnon CD. Sensorimotor anatomy of gait, balance, and falls. Handb Clin Neurol 2018;159:3-26 [FREE Full text] [CrossRef] [Medline]
    29. Yorke A, Ward I, Vora S, Combs S, Keller-Johnson T. Measurement characteristics and clinical utility of the Dizziness Handicap Inventory among individuals with vestibular disorders. Arch Phys Med Rehabil 2013 Nov;94(11):2313-2314 [FREE Full text] [CrossRef]
    30. Cattaneo D, Jonsdottir J, Repetti S. Reliability of four scales on balance disorders in persons with multiple sclerosis. Disabil Rehabil 2007 Dec 30;29(24):1920-1925. [CrossRef] [Medline]
    31. Berg KO, Maki BE, Williams JI, Holliday PJ, Wood-Dauphinee SL. Clinical and laboratory measures of postural balance in an elderly population. Arch Phys Med Rehabil 1992 Nov;73(11):1073-1080. [Medline]
    32. Sankarpandi SK, Baldwin AJ, Ray J, Mazzà C. Reliability of inertial sensors in the assessment of patients with vestibular disorders: A feasibility study. BMC Ear Nose Throat Disord 2017;17:1 [FREE Full text] [CrossRef] [Medline]
    33. Hershkovitz L, Malcay O, Grinberg Y, Berkowitz S, Kalron A. The contribution of the instrumented Timed-Up-and-Go test to detect falls and fear of falling in people with multiple sclerosis. Mult Scler Relat Disord 2019 Jan;27:226-231. [CrossRef] [Medline]
    34. Fisk JD, Pontefract A, Ritvo PG, Archibald CJ, Murray TJ. The impact of fatigue on patients with multiple sclerosis. Can J Neurol Sci 1994 Feb;21(1):9-14. [Medline]
    35. Vickrey BG, Hays RD, Harooni R, Myers LW, Ellison GW. A health-related quality of life measure for multiple sclerosis. Qual Life Res 1995 Jun;4(3):187-206. [Medline]
    36. Schneider S, Peipsi A, Stokes M, Knicker A, Abeln V. Feasibility of monitoring muscle health in microgravity environments using Myoton technology. Med Biol Eng Comput 2015 Jan;53(1):57-66. [CrossRef] [Medline]
    37. Miniconi P. Réponse posturale du réflexe vestibulospinal lors d’un mouvement dynamique actif dans le plan des six canaux semi-circulaires. Neurophysiol Clin 2016 Nov;46(4-5):269-270. [CrossRef]
    38. Rose T, Nam CS, Chen KB. Immersion of virtual reality for rehabilitation - Review. Appl Ergon 2018 May;69:153-161. [CrossRef] [Medline]
    39. Kim W, Cho S, Ku J, Kim Y, Lee K, Hwang H, et al. Clinical application of virtual reality for upper limb motor rehabilitation in stroke: Review of technologies and clinical evidence. J Clin Med 2020 Oct 21;9(10):3369 [FREE Full text] [CrossRef] [Medline]
    40. Cooksey FS. Rehabilitation in vestibular injuries. Proc R Soc Med 1946 Mar;39(5):273-278 [FREE Full text] [Medline]
    41. Flachenecker P, Kümpfel T, Kallmann B, Gottschalk M, Grauer O, Rieckmann P, et al. Fatigue in multiple sclerosis: A comparison of different rating scales and correlation to clinical parameters. Mult Scler 2002 Dec;8(6):523-526. [CrossRef] [Medline]
    42. LaValle SM, Yershova A, Katsev M, Antonov M. Head tracking for the Oculus Rift. In: Proceedings of the IEEE International Conference on Robotics and Automation. 2014 Presented at: IEEE International Conference on Robotics and Automation; May 31-June 7, 2014; Hong Kong, China p. 187-194. [CrossRef]
    43. Lubetzky AV, Kelly J, Wang Z, Gospodarek M, Fu G, Sutera J, et al. Contextual sensory integration training via head mounted display for individuals with vestibular disorders: A feasibility study. Disabil Rehabil Assist Technol 2020 May 18:1-11. [CrossRef] [Medline]
    44. Micarelli A, Viziano A, Augimeri I, Micarelli D, Alessandrini M. Three-dimensional head-mounted gaming task procedure maximizes effects of vestibular rehabilitation in unilateral vestibular hypofunction: A randomized controlled pilot trial. Int J Rehabil Res 2017 Dec;40(4):325-332. [CrossRef] [Medline]
    45. Viziano A, Micarelli A, Augimeri I, Micarelli D, Alessandrini M. Long-term effects of vestibular rehabilitation and head-mounted gaming task procedure in unilateral vestibular hypofunction: A 12-month follow-up of a randomized controlled trial. Clin Rehabil 2019 Jan;33(1):24-33. [CrossRef] [Medline]
    46. Papachristos NM, Vrellis I, Mikropoulos TA. A comparison between Oculus Rift and a low-cost smartphone VR headset: Immersive user experience and learning. In: Proceedings of the IEEE 17th International Conference on Advanced Learning Technologies. 2017 Presented at: IEEE 17th International Conference on Advanced Learning Technologies; July 3-7, 2017; Timisoara, Romania p. 477-481.
    47. Hupont I, Gracia J, Sanagustin L, Gracia M. How do new visual immersive systems influence gaming QoE? A use case of serious gaming with Oculus Rift. In: Proceedings of the 7th International Workshop on Quality of Multimedia Experience. 2015 Presented at: 7th International Workshop on Quality of Multimedia Experience; May 26-29, 2015; Pilos, Greece p. 1-6. [CrossRef]
    48. Sheehy L, Taillon-Hobson A, Sveistrup H, Bilodeau M, Yang C, Welch V, et al. Home-based virtual reality training after discharge from hospital-based stroke rehabilitation: A parallel randomized feasibility trial. Trials 2019 Jun 07;20(1):333 [FREE Full text] [CrossRef] [Medline]
    49. Sulway S, Whitney SL. Advances in vestibular rehabilitation. Adv Otorhinolaryngol 2019;82:164-169. [CrossRef] [Medline]
    50. Ozkul C, Guclu-Gunduz A, Yazici G, Atalay Guzel N, Irkec C. Effect of immersive virtual reality on balance, mobility, and fatigue in patients with multiple sclerosis: A single-blinded randomized controlled trial. Eur J Integr Med 2020 Apr;35:101092. [CrossRef]
    51. Yeh S, Chen S, Wang P, Su M, Chang C, Tsai P. Interactive 3-dimensional virtual reality rehabilitation for patients with chronic imbalance and vestibular dysfunction. Technol Health Care 2014;22(6):915-921. [CrossRef] [Medline]
    52. Hsu S, Fang T, Yeh S, Su M, Wang P, Wang VY. Three-dimensional, virtual reality vestibular rehabilitation for chronic imbalance problem caused by Ménière's disease: A pilot study. Disabil Rehabil 2017 Aug;39(16):1601-1606. [CrossRef] [Medline]
    53. Akay T, Murray AJ. Relative contribution of proprioceptive and vestibular sensory systems to locomotion: Opportunities for discovery in the age of molecular science. Int J Mol Sci 2021 Feb 02;22(3):1467 [FREE Full text] [CrossRef] [Medline]
    54. Fettrow T, Reimann H, Grenet D, Crenshaw J, Higginson J, Jeka J. Walking cadence affects the recruitment of the medial-lateral balance mechanisms. Front Sports Act Living 2019;1:40 [FREE Full text] [CrossRef] [Medline]
    55. Askim T, Indredavik B, Engen A, Roos K, Aas T, Mørkved S. Physiotherapy after stroke: To what extent is task-oriented practice a part of conventional treatment after hospital discharge? Physiother Theory Pract 2013 Jul;29(5):343-350. [CrossRef] [Medline]
    56. Ozgen G, Karapolat H, Akkoc Y, Yuceyar N. Is customized vestibular rehabilitation effective in patients with multiple sclerosis? A randomized controlled trial. Eur J Phys Rehabil Med 2016 Aug;52(4):466-478 [FREE Full text] [Medline]
    57. Seddighi-Khavidak M, Tahan N, Akbarzadeh-Baghban A. Comparing the effects of vestibular rehabilitation with and without lavender oil scents as an olfactory stimulus on balance, fear of falling down and activities of daily living of people with multiple sclerosis: A randomized clinical trial. Disabil Rehabil 2020 Dec 11:1-7. [CrossRef] [Medline]
    58. Witchel HJ, Oberndorfer C, Needham R, Healy A, Westling CEI, Guppy JH, et al. Thigh-derived inertial sensor metrics to assess the sit-to-stand and stand-to-sit transitions in the Timed Up And Go (TUG) task for quantifying mobility impairment in multiple sclerosis. Front Neurol 2018;9:684 [FREE Full text] [CrossRef] [Medline]
    59. Kim K, Gimmon Y, Millar J, Brewer K, Serrador J, Schubert M. Vestibular physical therapy improves turning not straight walking during the inertial sensor-instrumented Timed Up and Go test. Research Square posted online on July 17, 2020. [CrossRef]
    60. Van Emmerik REA, Remelius JG, Johnson MB, Chung LH, Kent-Braun JA. Postural control in women with multiple sclerosis: Effects of task, vision and symptomatic fatigue. Gait Posture 2010 Oct;32(4):608-614. [CrossRef] [Medline]
    61. Ibrahim AA, Küderle A, Gaßner H, Klucken J, Eskofier BM, Kluge F. Inertial sensor-based gait parameters reflect patient-reported fatigue in multiple sclerosis. J Neuroeng Rehabil 2020 Dec 18;17(1):165 [FREE Full text] [CrossRef] [Medline]
    62. Brichetto G, Piccardo E, Pedullà L, Battaglia MA, Tacchino A. Tailored balance exercises on people with multiple sclerosis: A pilot randomized, controlled study. Mult Scler 2015 Jul;21(8):1055-1063. [CrossRef] [Medline]
    63. Barin L, Salmen A, Disanto G, Babačić H, Calabrese P, Chan A, Swiss Multiple Sclerosis Registry (SMSR). The disease burden of multiple sclerosis from the individual and population perspective: Which symptoms matter most? Mult Scler Relat Disord 2018 Oct;25:112-121. [CrossRef] [Medline]
    64. Di Stadio A, Dipietro L, Ralli M, Greco A, Ricci G, Bernitsas E. The role of vestibular evoked myogenic potentials in multiple sclerosis-related vertigo. A systematic review of the literature. Mult Scler Relat Disord 2019 Feb;28:159-164. [CrossRef] [Medline]
    65. Forbes PA, Siegmund GP, Schouten AC, Blouin J. Task, muscle and frequency dependent vestibular control of posture. Front Integr Neurosci 2014;8:94 [FREE Full text] [CrossRef] [Medline]
    66. Forbes PA, Luu BL, Van der Loos HFM, Croft EA, Inglis JT, Blouin J. Transformation of vestibular signals for the control of standing in humans. J Neurosci 2016 Nov 09;36(45):11510-11520 [FREE Full text] [CrossRef] [Medline]
    67. Lubetzky AV, Kelly J, Wang Z, Taghavidilamani M, Gospodarek M, Fu G, et al. Head mounted display application for contextual sensory integration training: Design, implementation, challenges and patient outcomes. In: Proceedings of the International Conference on Virtual Rehabilitation. 2019 Presented at: International Conference on Virtual Rehabilitation; July 21-24, 2019; Tel Aviv, Israel p. 1-7. [CrossRef]
    68. Ricci NA, Aratani MC, Caovilla HH, Ganança FF. Effects of vestibular rehabilitation on balance control in older people with chronic dizziness: A randomized clinical trial. Am J Phys Med Rehabil 2016 Apr;95(4):256-269. [CrossRef] [Medline]
    69. Angelaki DE, Cullen KE. Vestibular system: The many facets of a multimodal sense. Annu Rev Neurosci 2008;31:125-150. [CrossRef] [Medline]

    BBS: Berg Balance Scale
    DHI: Dizziness Handicap Inventory
    HMD: head-mounted display
    iTUG: instrumented Timed Up and Go
    MFIS: Modified Fatigue Impact Scale
    MRI: magnetic resonance imaging
    MS: multiple sclerosis
    MSQoL-54: Multiple Sclerosis Quality of Life-54
    RRMS: relapsing-remitting multiple sclerosis
    SUS: System Usability Scale
    T0: baseline
    T1: between initial and advanced phases
    T2: postintervention
    T3: 1 month after the experimental procedure
    VOR: vestibulo-ocular reflex
    VR: virtual reality
    VRi: immersive virtual reality
    VSR: vestibulo-spinal reflex

    Edited by N Zary; submitted 07.06.21; peer-reviewed by PC Wang, I Alguacil; comments to author 22.07.21; revised version received 07.09.21; accepted 12.10.21; published 16.02.22

    Copyright

    ©Cristina García-Muñoz, María-Dolores Cortés-Vega, Juan-Carlos Hernández-Rodríguez, Lourdes M Fernández-Seguín, Isabel Escobio-Prieto, María Jesús Casuso-Holgado. Originally published in JMIR Serious Games (https://games.jmir.org), 16.02.2022.

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