Summary
In order to isolate some of the factors responsible for strabismic amblyopia as well as to ascertain the time course of its development, frequent measurements were made of the visual acuity of the two eyes of kittens following imposition of surgically induced strabismus. Following behavioural training on a jumping stand, strabismus was induced in all but one animal by simple section of either the lateral (esotropia) or medial (exotropia) rectus muscle of one eye. The one exception was a kitten on which esotropia was induced by another common but more radical surgical procedure that involved removal of the body of both the lateral rectus and superior oblique muscles of one eye. There was a surprising difference between the immediate consequences for vision of section of the lateral and medial rectus muscles that were reflected by equally large differences in the magnitude of the amblyopia that developed eventually in the two situations. Following section of the lateral rectus muscle, there was an immediate reduction in the visual acuity of the operated eye of as much as 2 octaves after which vision returned to normal levels over 4 to 8 days. The acuity of the two eyes remained comparable for a few days after which the vision of the operated eye began to decline once more, signalling the onset of amblyopia some 10 to 12 days following imposition of strabismus. In contrast to the severity of these effects, the effects observed following section of the medial rectus were both mild and transitory. Furthermore, whereas all kittens that were rendered esotropic early developed amblyopia, none of the kittens that were made exotropic at the same age did so. Together, these results suggest that factors associated with the immediate consequences of the surgical procedure employed to produce a misalignment of the visual axes may contribute to the severity of the effects of surgically induced strabismus.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Baker FH, Grigg P, Von Noorden GK (1974) Effects of visual deprivation and strabismus on the responses of neurons in the visual cortex of the monkey, including studies on the striate and prestriate cortex in the normal animal. Brain Res 66: 185–208
Batini C, Buisseret P, Buisseret-Delmas C (1975) Trigeminal pathway of the extrinsic eye muscle afferents in cat. Brain Res 85: 74–78
Bennett MJ, Smith EL, Harwerth RS, Crawford MLJ (1980) Ocular dominance, eye alignment and visual acuity in kittens reared with an optically induced squint. Brain Res 193: 33–45
Berman N, Murphy H (1982) The critical period for alteration in cortical binocularity resulting from divergent and convergent strabismus. Dev Brain Res 2: 181–202
Buisseret P, Maffei L (1977) Extraocular proprioceptive projections to the visual cortex. Exp Brain Res 28: 421–425
Chino YM, Shansky MS, Hamasaki DI (1980) Development of receptive field properties of retinal ganglion cells in kittens raised with a convergent squint. Exp Brain Res 39: 313–320
Chino YM, Shansky MS, Jankowski WL, Banser FA (1983) Effects of rearing kittens with convergent strabismus on development of receptive field properties in striate cortex neurons. J Neurophysiol 50: 265–286
Cleland BG, Crewther DP, Gillard-Crewther S, Mitchell DE (1982) Normality of spatial resolution of retinal ganglion cells in cats with strabismic amblyopia. J Physiol (Lond) 236: 235–249
Crawford MLJ, Von Noorden GK (1979) The effects of short-term experimental strabismus on the visual system in Macaca mulatta. Invest Ophthamol Vis Sci 18: 496–505
Crawford MLJ, Von Noorden GK (1980) Optically-induced concomitant strabismus in monkeys. Invest Ophthalmol Vis Sci 19: 1105–1109
Crawford MLJ, Von Noorden GK, Meharg LS, Rhodes JW, Harwerth RS, Smith EL, Miller DD (1983) Binocular neurons and binocular function in monkeys and children. Invest Ophthalmol Vis Sci 24: 491–495
Davis DD, Storey HE (1943) Carotid circulation in the domestic cat. Field Mus Nat Hist Zool Ser 28: 5–47
Duke-Elder SS, Wybar K (1973) System of Ophthalmology, Ocular Motility and Strabismus. London, Kimpton Vol VI
Fiorentini A, Berardi N, Maffei L (1982) Role of extraocular proprioception in the orienting behaviour of cats. Exp Brain Res 48: 113–120
Freeman RD, Sclar G, Ohzawa I (1983) An electrophysiological comparison of convergent and divergent strabismus in the cat: Visual evoked potentials. J Neurophysiol 49: 227–237
Freeman RD, Sclar G, Ohzawa I (1983) A quantitative comparison of binocular and monocular cells in the visual cortex of strabismic cats. Invest Ophthalmol Vis Sci ARVO Suppl 24 (3): 140
Freeman RD, Tsumoto T (1983) An electrophysiological comparison of convergent and divergent strabismus in the cat: Electrical and visual activation of single cortical cells. J Neurophysiol 49: 238–253
Giffin F, Mitchell DE (1978) The rate of recovery of vision after early monocular deprivation in kittens. J Physiol (Lond) 274: 511–537
Harwerth RS, Smith EL, Boltz RL, Crawford MLJ, von Noorden GK (1983) Behavioral studies on the effect of abnormal early visual experience in monkeys: spatial modulation sensitivity. Vision Res 23: 1501–1510
Holopigian K, Blake R (1983) Spatial vision in strabismic cats. J Neurophysiol 50: 287–296
Hubel DH, Wiesel TN (1965) Binocular interaction in striate cortex of kittens reared with artificial squint. J Neurophysiol 28: 1041–1059
Ikeda H, Tremain KE (1979) Amblyopia occurs in retinal ganglion cells in cats reared with convergent squint without alternating fixaton. Exp Brain Res 35: 559–582
Ikeda H, Tremain KE, Einon G (1978) Loss of spatial resolution of lateral geniculate nucleus neurones in kittens raised with convergent squint produced at different stages in development. Exp Brain Res 31: 207–220
Ikeda H, Wright MJ (1976) Properties of LGN cells in kittens reared with convergent squint: A neurophysiological demonstration of amblyopia. Exp Brain Res 25: 63–77
Jacobson SG, Ikeda H (1979) Behavioural studies of spatial vision in cats reared with convergent squint: Is amblyopia due to arrest of development? Exp Brain Res 34: 11–26
Kiorpes L, Boothe RG (1980) The time course for the development of strabismic amblyopia in infant monkeys (Macaca nemestrina). Invest Ophthalmol Vis Sci 19: 841–845
Mitchell DE, Giffin F, Timney B (1977) A behavioural technique for the rapid assessment of visual capabilities of kittens. Perception 6: 181–193
Mitchell DE, Giffin F, Wilkinson F, Anderson P, Smith ML (1976) Visual resolution in young kittens. Vision Res 16: 363–366
Mitchell DE, Timney B (1982) Behavioural measurement of normal and abnormal development of vision in kittens. In: Ingle DJ, Goodale MA, Mansfield RJ (eds) Analysis of Visual Behaviour. MIT Press, Cambridge pp 483–523
Mitchell DE, Timney B (1984) Postnatal development of function in the mammalian visual system. In: Darian-Smith I (ed) Handbook of Physiology Section I: The Nervous System, Vol 3, Sensory Processes, Part 1. American Physiological Society, Bethesda, pp 507–555
Mower GD, Burchfiel JL, Duffy FH (1982) Animal models of strabismic amblyopia: Physiological studies of visual cortex and the lateral geniculate nucleus. Dev Brain Res 5: 311–327
Olson CR (1980) Spatial localization in cats reared with strabismus. J Neurophysiol 43: 792–806
Olson CR, Freeman RD (1978) Eye alignment in kittens. J Neurophysiol 41: 848–859
Pettigrew JD, Cooper ML, Blasdel GG (1979) Improved use of tapetal reflection for eye-position monitoring. Invest Ophthalmol Vis Sci 18: 490–495
Tremain K, Ikeda H (1982) Relationship between amblyopia, LGN cell ‘shrinkage’ and cortical ocular dominance in cats. Exp Brain Res 45: 243–252
Van Sluyters RC, Levett F (1980) Experimental strabismus in the kitten. J Neurophysiol 43: 686–699
Von Grunau MW, Singer W (1980) Functional amblyopia in kittens with unilateral exotropia. Exp Brain Res 40: 305–310
Von Noorden GK (1973) Experimental amblyopia in monkeys. Further behavioural observations and clinical correlations. Invest Ophthalmol Vis Sci 12: 721–726
Von Noorden GK, Dowling JE (1970) Experimental amblyopia in monkeys II. Behavioral studies in strabismic amblyopia. Arch Ophthalmol 84: 215–220
Author information
Authors and Affiliations
Additional information
This research was supported by a grant (MA7732) to D.E.M. from the Medical Research Council of Canada. We wish to thank Keith Grasse for his assistance with the measurements of eye alignment under paralysis, and Cindy Trask and Heather Dzioba for their assistance with the behavioural testing
Rights and permissions
About this article
Cite this article
Mitchell, D.E., Ruck, M., Kaye, M.G. et al. Immediate and long-term effects on visual acuity of surgically induced strabismus in kittens. Exp Brain Res 55, 420–430 (1984). https://doi.org/10.1007/BF00235272
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00235272