Local and Non-local Deficits in Amblyopia: Acuity and Spatial Interactions
Overview
Authors
Affiliations
Amblyopic vision is thought to be limited by abnormal long-range spatial interactions, but their exact mode of action and relationship to the main amblyopic deficit in visual acuity is largely unknown. We studied this relationship in a group (N=59) of anisometropic (N=21) and strabismic (or combined, N=38) subjects, using (1) a single and multi-pattern (crowded) computerized static Tumbling-E test with scaled spacing of two pattern widths (TeVA), in addition to an optotype (ETDRS chart) acuity test (VA) and (2) contrast detection of Gabor patches with lateral flankers (lateral masking) along the horizontal and vertical axes as well as in collinear and parallel configurations. By correlating the different measures of visual acuity and contrast suppression, we found that (1) the VA of the strabismic subjects could be decomposed into two uncorrelated components measured in TeVA: acuity for isolated patterns and acuity reduction due to flanking patterns. The latter comprised over 60% of the VA magnitude, on the average and accounted for over 50% of its variance. In contrast, a slight reduction in acuity was found in the anisometropic subjects, and the acuity for a single pattern could account for 70% of the VA variance. (2) The lateral suppression (contrast threshold elevation) in a parallel configuration along the horizontal axis was correlated with the VA (R2=0.7), as well as with the crowding effect (TeVA elevation, R2=0.5) for the strabismic group. Some correlation with the VA was also found for the collinear configuration in the anisometropic group, but less suppression and no correlation were found for all the vertical configurations in all the groups. The results indicate the existence of a specific non-local component of the strabismic deficit, in addition to the local acuity deficit in all amblyopia types. This deficit might reflect long-range lateral inhibition, or alternatively, an inaccurate and scattered top-down attentional selection mechanism.
Waugh S, Fronius M Invest Ophthalmol Vis Sci. 2024; 65(10):33.
PMID: 39177974 PMC: 11346165. DOI: 10.1167/iovs.65.10.33.
Crowding under scotopic and photopic vision in albino and normal-sighted participants.
Moshkovitz A, Lev M, Polat U Sci Rep. 2024; 14(1):8234.
PMID: 38589506 PMC: 11001935. DOI: 10.1038/s41598-024-58369-0.
Abnormal basic visual processing functions in binocular fusion disorders.
Benhaim-Sitbon L, Lev M, Polat U Sci Rep. 2023; 13(1):19301.
PMID: 37935803 PMC: 10630403. DOI: 10.1038/s41598-023-46291-w.
Eisen-Enosh A, Farah N, Polat U, Mandel Y Sci Rep. 2023; 13(1):7643.
PMID: 37169784 PMC: 10175483. DOI: 10.1038/s41598-023-34421-3.
Extended perceptive field revealed in humans with binocular fusion disorders.
Benhaim-Sitbon L, Lev M, Polat U Sci Rep. 2023; 13(1):6584.
PMID: 37085571 PMC: 10121568. DOI: 10.1038/s41598-023-33429-z.