Functional anatomy of normal human rectus muscles
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Cited by (220)
Statics of plant mechanics
2022, Progress in Brain ResearchCitation Excerpt :Both Miller and Simonsz suspected that these discrepancies might be due to Robinson's admittedly artificial constraint on rectus muscle sideslip. Simonsz demonstrated using x-ray imaging (Simonsz et al., 1985b, c) in humans and Miller and Robbins in monkeys (Miller & Robins, 1987), and Miller demonstrated in humans by magnetic resonance imaging (Miller, 1989), that horizontal rectus muscles do not sideslip over the globe in eccentric vertical gaze positions. Such observations confirmed Robinson's inference that something must prohibit sideslip in a manner arbitrarily described by an equation.
Magnetic Resonance Imaging of the Globe-Tendon Interface for Extraocular Muscles: Is There an “Arc of Contact”?
2018, American Journal of OphthalmologyCitation Excerpt :The most immediate impact is to improve the accuracy of mathematical models designed to predict changes in eye movements in response to various perturbations. Beginning with the seminal studies by Miller5 and Demer13,29 almost 30 years ago, the combination of high-resolution orbital imaging and careful orbital histology has profoundly influenced the fundamental principles governing eye movement. The connective tissue pulleys that constrain posterior EOM belly sideslip simplify neurologic control of eye movements by solving the potentially complex mathematics of coordinated 3-axis eye movements with an elegant mechanical solution.30,31
An ocular biomechanic model for dynamic simulation of different eye movements
2018, Journal of BiomechanicsSkin-Attached Arrayed Piezoelectric Sensors for Continuous and Safe Monitoring of Oculomotor Movements
2024, Advanced Healthcare Materials