Novel gaze stability training improves dynamic visual acuity for 6 months

Abstract

Objectives

Peripheral vestibular hypofunction (PVH) affects a significant portion of the population and impairs visual acuity during head motion (dynamic visual acuity, DVA). This study compared the effectiveness of a novel gaze stability training called Incremental VOR Adaptation (IVA) versus traditional vestibular physical therapy (VPT) for improving DVA.

Methods

The Incremental Velocity Error as a New Treatment in Vestibular Rehabilitation (INVENT) trial is a randomized, controlled, cross-over study involving 24 participants with chronic unilateral or bilateral PVH. Participants underwent either IVA or VPT for 3 weeks, followed by a washout period and then the alternate intervention (IVA-VPT or VPT-IVA). DVA was measured at baseline, after each intervention, at the completion of the washout period, and at 6-month follow-up.

Results

There was a significant main effect of treatment Group, F (1,19) = 7.75, p = 0.012, with (IVA-VPT) consistently demonstrating lower DVA scores than VPT-IVA. A significant main effect of Side was also observed, F (1,19) = 13.35, p = 0.0017, indicating lower DVA scores for contralesional compared to ipsilesional head rotation. We found no effect of Time (F (4,76) = 1.44, p = 0.23), suggesting that scores remained stable from baseline through the 6-months follow-up. There were no significant interactions, including Group × Side (F (1,19) = 0.11, p = 0.74), Group × Time (F (4,76) = 1.33, p = 0.27), or Group × Side × Time (F (4,76) = 0.59, p = 0.67).

Conclusion

DVA scores were consistently better at all time points after participants completed IVA. Using an intent to treat analysis, with no baseline demographic differences between groups, our data support that exposure to the first gaze stability training type exerts a stable influence on DVA that persisted to 6-month follow-up. Clinically, this implies that once DVA improvements are established through either IVA or VPT, they tend to remain stable over 6 months.

Level of Evidence

Level 2.

Keywords

dynamic visual acuity incremental VOR adaptation gaze stability vestibular hypofunction

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References

Grill

Heuberger

Strobl

, et al. Prevalence, determinants, and consequences of vestibular hypofunction. Results from the KORA-FF4 survey. Front Neurol 2018; 9: 1076.

Hall

Herdman

Whitney

, et al. Vestibular rehabilitation for peripheral vestibular hypofunction: an updated clinical practice Guideline from the academy of neurologic physical therapy of the American physical therapy association. J Neurol Phys Ther 2022; 46(2): 118–177.

Macdougall

McGarvie

Halmagyi

, et al. The video head impulse test (vHIT) detects vertical semicircular canal dysfunction. PLoS One 2013; 8(4): e61488.

Mahfuz

Millar

Schubert

. Repeated video head impulse testing in patients is a stable measure of the passive vestibulo-ocular reflex. J Otolaryngol 2021; 16(3): 128–137.

Strupp

Bisdorff

Furman

, et al. Acute unilateral vestibulopathy/vestibular neuritis: diagnostic criteria. J Vestib Res 2022; 32(5): 389–406.

Strupp

Kim

Murofushi

, et al. Bilateral vestibulopathy: diagnostic criteria consensus document of the classification committee of the Bárány society. J Vestib Res 2017; 27(4): 177–189.

Beaumont

Rine

, et al. Normative scores for the NIH toolbox dynamic visual acuity test from 3 to 85 years. Front Neurol 2014; 5: 223.

Herdman

Schubert

Das

, et al. Recovery of dynamic visual acuity in unilateral vestibular hypofunction. Arch Otolaryngol Neck Surg 2003; 129(8): 819–824.

Millar

Gimmon

Roberts

, et al. Improvement after vestibular rehabilitation not explained by improved passive VOR gain. Front Neurol 2020; 11: 79.

10.

Herdman

Hall

Schubert

, et al. Recovery of dynamic visual acuity in bilateral vestibular hypofunction. Arch Otolaryngol Neck Surg 2007; 133(4): 383–389.

11.

Schubert

Migliaccio

Della Santina

. Dynamic visual acuity during passive head thrusts in canal planes. J Assoc Res Otolaryngol 2006; 7(4): 329–338.

12.

Herdman

Clendaniel

Steele

. Vestibular rehabilitation. 4th ed. F. A. Davis Company, 2014.

13.

Rinaudo

Schubert

Figtree

WVC

, et al. Human vestibulo-ocular reflex adaptation reduces when training demand variability increases. J Assoc Res Otolaryngol 2021; 22(2): 193–206.

14.

Rinaudo

Schubert

Cremer

, et al. Once-daily incremental vestibular-ocular reflex adaptation training in patients with chronic peripheral vestibular hypofunction: a 1-Week randomized controlled study. J Neurol Phys Ther 2021; 45(2): 87–100.

15.

Rinaudo

Schubert

Cremer

, et al. Comparison of incremental vestibulo-ocular reflex adaptation training versus x1 training in patients with chronic peripheral vestibular hypofunction: a two-year randomized controlled trial. J Neurol Phys Ther 2021; 45(4): 246–258.

16.

Ervin

Schubert

Migliaccio

, et al. Incremental velocity error as a new treatment in vestibular rehabilitation (INVENT VPT) trial: study protocol for a randomized controlled crossover trial. Trials 2021; 22(1): 908.

17.

Dandona

. Revision of visual impairment definitions in the international statistical classification of diseases. BMC Med 2006; 4: 7.

18.

Searle

Speed

Milliken

. Population marginal means in the linear model: an alternative to least squares means. Am Statistician 1980; 34(4): 216–221.

19.

Weber

Todd

, et al. Head impulse test in unilateral vestibular loss: vestibulo-ocular reflex and catch-up saccades. Neurology 2008; 70(6): 454–463.

20.

Wettstein

Weber

Bockisch

, et al. Compensatory saccades in head impulse testing influence the dynamic visual acuity of patients with unilateral peripheral vestibulopathy1. J Vestib Res 2016; 26(4): 395–402.

21.

Sjögren

Fransson

Karlberg

, et al. Functional head impulse testing might be useful for assessing vestibular compensation after unilateral vestibular loss. Front Neurol 2018; 9: 979.

22.

Hermann

Pelisson

Dumas

, et al.

Are covert saccade functionally relevant in vestibular hypofunction?

Cerebellum 2018; 17(3): 300–307.

23.

Tramontano

Haijoub

Lacour

, et al. Updated views on vestibular physical therapy for patients with vestibular disorders. Healthcare 2025; 13(5): 492.

24.

Gimmon

Migliaccio

Kim

, et al. VOR adaptation training and retention in a patient with profound bilateral vestibular hypofunction. Laryngoscope 2019; 129(11): 2568–2573.

25.

Rinaudo

Schubert

Cremer

, et al. Improved oculomotor physiology and behavior after unilateral incremental adaptation training in a person with chronic vestibular hypofunction: a case report. Phys Ther 2019; 99(10): 1326–1333.

26.

Kalderon

Kaplan

Wolfovitz

, et al. Barriers and facilitators of vestibular rehabilitation: patients and physiotherapists’ perspectives. J Neurol Phys Ther 2024; 48(3):140–150.

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