AIM: To evaluate the effects of virtual reality(VR) training on different parameters of vision.METHODS: Sixty individuals ranged 18-60 years old with asthenopia were randomly divided into short-term(n=40) and long-ter...AIM: To evaluate the effects of virtual reality(VR) training on different parameters of vision.METHODS: Sixty individuals ranged 18-60 years old with asthenopia were randomly divided into short-term(n=40) and long-term(n=20) treatment groups. They were given a specially designed VR training device only once for 15 min or 3-4 times a day for 15 min each time for 1 mo. The visual acuity, spherical equivalent, accommodative range, accommodative facility, pupil size, and visual fatigue were evaluated before(control) and after VR training. RESULTS: The visual acuity, accommodative range, and accommodative facility increased in subjects of the shortterm treatment group, whereas their pupil size contracted significantly. No significant changes in spherical equivalent and visual fatigue were observed. The changes in distant vision and corrected visual acuity were positively correlated with those in pupil size, but not with spherical equivalent. The accommodative range and accommodative facility improved significantly in subjects of the long-term treatment group. No significant changes in visual acuity, spherical equivalent, pupil size, and visual fatigue were noted. CONCLUSION: VR training can improve the accommodative range and accommodative facility of human eyes. Although short-term VR training can transiently improve vision, which probably due to bright light adaptation, there is no evidence that it can improve myopia.展开更多
基金Supported by the National Natural Science Foundation of China (No.81800868)the Health and Family Planning Commission of Zhejiang Province,China (No.2018KY057)the Natural Science Foundation of Zhejiang Province (No.LY19H120007)。
文摘AIM: To evaluate the effects of virtual reality(VR) training on different parameters of vision.METHODS: Sixty individuals ranged 18-60 years old with asthenopia were randomly divided into short-term(n=40) and long-term(n=20) treatment groups. They were given a specially designed VR training device only once for 15 min or 3-4 times a day for 15 min each time for 1 mo. The visual acuity, spherical equivalent, accommodative range, accommodative facility, pupil size, and visual fatigue were evaluated before(control) and after VR training. RESULTS: The visual acuity, accommodative range, and accommodative facility increased in subjects of the shortterm treatment group, whereas their pupil size contracted significantly. No significant changes in spherical equivalent and visual fatigue were observed. The changes in distant vision and corrected visual acuity were positively correlated with those in pupil size, but not with spherical equivalent. The accommodative range and accommodative facility improved significantly in subjects of the long-term treatment group. No significant changes in visual acuity, spherical equivalent, pupil size, and visual fatigue were noted. CONCLUSION: VR training can improve the accommodative range and accommodative facility of human eyes. Although short-term VR training can transiently improve vision, which probably due to bright light adaptation, there is no evidence that it can improve myopia.
