Summary
Twenty-nine pigmented offspring of an innately esotropic female cat exhibited varying deficits in the number of binocular cells recorded in area 17 of the visual cortex as compared to 12 normal cats. Misalignment of the two eyes in these cats was found in the awake as well as in the paralysed state. Pupillography combined with measurements of visual disparity yielded abnormal esotropia of up to 8.4° under paralysis, which corresponds to an abnormal convergence of the freely moving eyes of up to 14° (average 7.4°). In the majority of animals cortical binocularity was found reduced by the two eyes controlling independent sets of separate units (U-shaped ocular dominance distribution) whereas in 7 cats the reduction was due to a partial loss of one eye's influence. The proportion of monocular units correlated with the degree of crossover of the visual axes (r = 0.73). Anatomical investigation of the retinofugal projections revealed normal appearance in three previously recorded cats in which more than 50% of cortical units had been monocularly driven. The small angles of esotropia and the “normal” appearance of eye position judged by the pupillary positions in the orbit of these cats, might suggest that we found an animal model for microstrabismus.
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Hoffmann, K.P., Schoppmann, A. Shortage of binocular cells in area 17 of visual cortex in cats with congenital strabismus. Exp Brain Res 55, 470–482 (1984). https://doi.org/10.1007/BF00235278
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DOI: https://doi.org/10.1007/BF00235278