Modeling control of eye orientation in three dimensions. I. Role of muscle pulleys in determining saccadic trajectory.

This study evaluates the effects of muscle axis shifts on the performance of a vector velocity-position integrator in the CNS. Earlier models of the oculomotor plant assumed that the muscle axes remained fixed relative to the head as the eye rotated into secondary and tertiary eye positions. Under this assumption, the vector integrator model generates torsional transients as the eye moves from secondary to tertiary positions of fixation. The torsional transient represents an eye movement response to a spatial mismatch between the torque axes that remain fixed in the head and the displacement plane that changes by half the angle of the change in eye orientation. When muscle axis shifts were incorporated into the model, the torque axes were closer to the displacement plane at each eye orientation throughout the trajectory, and torsional transients were reduced dramatically. Their size and dynamics were close to reported data. It was also shown that when the muscle torque axes were rotated by 50% of the eye rotation, there was no torsional transient and Listing's law was perfectly obeyed. When muscle torque axes rotated >50%, torsional transients reversed direction compared with what occurred for muscle axis shifts of <50%. The model indicates that Listing's law is implemented by the oculomotor plant subject to a two-dimensional command signal that is confined to the pitch-yaw plane, having zero torsion. Saccades that bring the eye to orientations outside Listing's plane could easily be corrected by a roll pulse that resets the roll state of the velocity-position integrator to zero. This would be a simple implementation of the corrective controller suggested by Van Opstal and colleagues. The model further indicates that muscle axis shifts together with the torque orientation relationship for tissue surrounding the eye and Newton's laws of motion form a sufficient plant model to explain saccadic trajectories and periods of fixation when driven by a vector command confined to the pitch-yaw plane. This implies that the velocity-position integrator is probably realized as a subtractive feedback vector integrator and not as a quaternion-based integrator that implements kinematic transformations to orient the eye.

[1]  J. M. Miller,et al.  Evidence for fibromuscular pulleys of the recti extraocular muscles. , 1995, Investigative ophthalmology & visual science.

[2]  C. Schnabolk,et al.  Modeling three-dimensional velocity-to-position transformation in oculomotor control. , 1994, Journal of neurophysiology.

[3]  J. W. Humberston Classical mechanics , 1980, Nature.

[4]  V Henn,et al.  The origin of quick phases of nystagmus in the horizonatal plane. , 1972, Bibliotheca ophthalmologica : supplementa ad ophthalmologica.

[5]  David A. Robinson,et al.  MODELS OF OCULOMOTOR NEURAL ORGANIZATION , 1971 .

[6]  J. M. Miller,et al.  Magnetic resonance imaging of the functional anatomy of the superior oblique muscle. , 1995, Investigative ophthalmology & visual science.

[7]  B. Cohen,et al.  Unit activity in the pontine reticular formation associated with eye movements , 1972 .

[8]  D. Robinson Eye movements evoked by collicular stimulation in the alert monkey. , 1972, Vision research.

[9]  A. Levin,et al.  The Viscous Elastic Properties of Muscle , 1927 .

[10]  K Hepp,et al.  Monkey superior colliculus represents rapid eye movements in a two-dimensional motor map. , 1993, Journal of neurophysiology.

[11]  S. Altmann Rotations, Quaternions, and Double Groups , 1986 .

[12]  D Tweed,et al.  Implications of rotational kinematics for the oculomotor system in three dimensions. , 1987, Journal of neurophysiology.

[13]  A L Rosenbaum,et al.  High resolution, dynamic, magnetic resonance imaging in complicated strabismus. , 1996, Journal of pediatric ophthalmology and strabismus.

[14]  J L Demer,et al.  Surgical implications of the rectus extraocular muscle pulleys. , 1996, Journal of pediatric ophthalmology and strabismus.

[15]  G H Kolling,et al.  Intraoperative Length and Tension Curves of Human Eye Muscles: Including Stiffness in Passive Horizontal Eye Movement in Awake Volunteers , 1986 .

[16]  D. Straumann,et al.  Transient torsion during and after saccades , 1995, Vision Research.

[17]  D. Robinson A quantitative analysis of extraocular muscle cooperation and squint. , 1975, Investigative ophthalmology.

[18]  T. Vilis,et al.  Computing three-dimensional eye position quaternions and eye velocity from search coil signals , 1990, Vision Research.

[19]  D. Robinson,et al.  Mechanical components of human eye movements. , 1969, Journal of applied physiology.

[20]  Joel Miller,et al.  Extraocular muscle sideslip and orbital geometry in monkeys , 1987, Vision Research.

[21]  D. Robinson The mechanics of human saccadic eye movement , 1964, The Journal of physiology.

[22]  Joel Miller Functional anatomy of normal human rectus muscles , 1989, Vision Research.

[23]  F A Miles,et al.  Visually induced adaptive changes in primate saccadic oculomotor control signals. , 1985, Journal of neurophysiology.

[24]  K Nakayama A New Method of Determining the Primary Position of the Eye Using Listing's Law , 1978, American journal of optometry and physiological optics.

[25]  L. Optican,et al.  Cerebellar-dependent adaptive control of primate saccadic system. , 1980, Journal of neurophysiology.

[26]  B. Cohen,et al.  Coding of information about rapid eye movements in the pontine reticular formation of alert monkeys , 1976, Brain Research.

[27]  K Hepp,et al.  Two- rather than three-dimensional representation of saccades in monkey superior colliculus. , 1991, Science.

[28]  L. Shen,et al.  Linear Algebra , 1968 .

[29]  A L Rosenbaum,et al.  Effect of transposition surgery on rectus muscle paths by magnetic resonance imaging. , 1993, Ophthalmology.

[30]  J. M. Miller,et al.  Location and stability of rectus muscle pulleys. Muscle paths as a function of gaze. , 1997, Investigative ophthalmology & visual science.

[31]  C. Collins,et al.  ELEMENTS OF THE PERIPHERAL OCULOMOTOR APPARATUS* , 1969, American journal of optometry and archives of American Academy of Optometry.

[32]  J M Miller,et al.  A model of the mechanics of binocular alignment. , 1984, Computers and biomedical research, an international journal.

[33]  E. Keller Participation of medial pontine reticular formation in eye movement generation in monkey. , 1974, Journal of neurophysiology.

[34]  Felix Klein,et al.  Vorlesungen über das Ikosaeder und die Auflösung der Gleichungen vom fünften Grade , 1884 .

[35]  J. M. Miller,et al.  Innervation of extraocular pulley smooth muscle in monkeys and humans. , 1997, Investigative ophthalmology & visual science.

[36]  J. Demer,et al.  Magnetic resonance imaging of the superior oblique muscle in superior oblique myokymia. , 1994, Journal of pediatric ophthalmology and strabismus.

[37]  K Hepp,et al.  Role of Monkey Nucleus Reticularis Tegmenti Pontis in the Stabilization of Listing’s Plane , 1996, The Journal of Neuroscience.

[38]  D Tweed,et al.  Rotation Axes of Saccades a , 1988, Annals of the New York Academy of Sciences.

[39]  T Vilis,et al.  Brainstem regions related to saccade generation. , 1989, Reviews of oculomotor research.

[40]  Han Collewijn,et al.  PART II. THREE‐DIMENSIONAL CODING IN THE OCULOMOTOR AND VISUAL SYSTEMS The Behavior of Human Gaze in Three Dimensions a , 1988 .

[41]  G H Kolling,et al.  Length-tension curves of human eye muscles during succinylcholine-induced contraction. , 1988, Investigative ophthalmology & visual science.

[42]  T. Vilis,et al.  Geometric relations of eye position and velocity vectors during saccades , 1990, Vision Research.

[43]  A. A. Skavenski,et al.  Role of abducens neurons in vestibuloocular reflex. , 1973, Journal of neurophysiology.

[44]  Klaus Hepp,et al.  Oculomotor control: Listing's law and all that , 1994, Current Opinion in Neurobiology.

[45]  S. Gielen,et al.  A quantitative analysis of generation of saccadic eye movements by burst neurons. , 1981, Journal of neurophysiology.

[46]  D. Tweed,et al.  Testing models of the oculomotor velocity-to-position transformation. , 1994, Journal of neurophysiology.

[47]  A. V. van den Berg,et al.  The behavior of human gaze in three dimensions. , 1988, Annals of the New York Academy of Sciences.

[48]  T Vilis,et al.  Axes of eye rotation and Listing's law during rotations of the head. , 1991, Journal of neurophysiology.