In primates normal visual perception depends upon positioning the eyes so that objects of interest activate the foveae of both eyes. This is achieved through an impressively precise calibration of eye muscle growth and neural commands, a process that depends upon early binocular visual experience. For at least 3% of children born in the United States this developmental process is unsuccessful, which leads to a chronic misalignment of the eyes referred to as strabismus. In addition to the motor impairments, the loss of binocular visual experience often leads to substantial impairments of visual function, such as amblyopia. Numerous oculomotor abnormalities have also been reported, including asymmetrical smooth pursuit gain, a lack of disparity vergence, and disconjugate saccades. Existing treatments are successful in some individuals but in others misalignment persists or reappears in the years following treatment. Recent studies have suggested that this problem may be attributable, in part, to different neurodevelopmental trajectories in normal and strabismic individuals. At present, however, very little is known about the specific abnormalities of oculomotor circuitry that may underlie the disorder. For example, virtually nothing is known about the neurophysiology of saccadic circuitry in strabismus. The long-term goal of the proposed experiments, therefore, is to identify the specific neurophysiological abnormalities that lead to disordered saccades and that maintain the eyes in a misaligned state. Our hypothesis is that disordered brainstem saccadic commands influence the static eye misalignment. To test this idea, we have developed an animal model of infantile strabismus in macaques. Previously published behavioral data have shown that these animals have visual and eye movement abnormalities that closely match those found in human children. We will use a combination of single unit recording and microstimulation of brainstem oculomotor structures while monkeys perform saccade tasks. These studies would significantly advance our understanding of the neurological abnormalities that currently impede the development of improved treatments for infantile strabismus.
Strabismus is a common disorder of eye alignment that can lead to significant abnormalities of visual function, including amblyopia and impaired stereoscopic depth perception. Our studies are designed to identify abnormalities of neural circuitry in strabismus with the goal of improving diagnosis and treatment.
Pallus, Adam C; Walton, Mark M G; Mustari, Michael J (2018) Activity of near response cells during disconjugate saccades in strabismic monkeys. J Neurophysiol : |
Pallus, Adam C; Walton, Mark M G; Mustari, Michael J (2018) Response of supraoculomotor area neurons during combined saccade-vergence movements. J Neurophysiol 119:585-596 |
Walton, Mark M G; Mustari, Michael J (2017) Comparison of three models of saccade disconjugacy in strabismus. J Neurophysiol 118:3175-3193 |
Walton, Mark M G; Pallus, Adam; Fleuriet, Jérome et al. (2017) Neural mechanisms of oculomotor abnormalities in the infantile strabismus syndrome. J Neurophysiol 118:280-299 |
Fleuriet, Jérome; Walton, Mark M G; Ono, Seiji et al. (2016) Electrical Microstimulation of the Superior Colliculus in Strabismic Monkeys. Invest Ophthalmol Vis Sci 57:3168-80 |
Willoughby, Christy L; Fleuriet, Jérome; Walton, Mark M et al. (2015) Adaptability of the Immature Ocular Motor Control System: Unilateral IGF-1 Medial Rectus Treatment. Invest Ophthalmol Vis Sci 56:3484-96 |
Walton, Mark M G; Mustari, Michael J; Willoughby, Christy L et al. (2015) Abnormal activity of neurons in abducens nucleus of strabismic monkeys. Invest Ophthalmol Vis Sci 56:10-9 |
Willoughby, Christy L; Fleuriet, Jérome; Walton, Mark M et al. (2015) Adaptation of slow myofibers: the effect of sustained BDNF treatment of extraocular muscles in infant nonhuman primates. Invest Ophthalmol Vis Sci 56:3467-83 |
Walton, Mark M G; Mustari, Michael J (2015) Abnormal tuning of saccade-related cells in pontine reticular formation of strabismic monkeys. J Neurophysiol 114:857-68 |