Head-Eye Coordination at a Microscopic Scale

Humans explore static visual scenes by alternating rapid eye movements (saccades) with periods of slow and incessant eye drifts [1-3]. These drifts are commonly believed to be the consequence of physiological limits in maintaining steady gaze, resulting in Brownian-like trajectories [4-7], which are almost independent in the two eyes [8-10]. However, because of the technical difficulty of recording minute eye movements, most knowledge on ocular drift comes from artificial laboratory conditions, in which the head of the observer is strictly immobilized. Little is known about eye drift during natural head-free fixation, when microscopic head movements are also continually present [11-13]. We have recently observed that the power spectrum of the visual input to the retina during ocular drift is largely unaffected by fixational head movements [14]. Here we elucidate the mechanism responsible for this invariance. We show that, contrary to common assumption, ocular drift does not move the eyes randomly, but compensates for microscopic head movements, thereby yielding highly correlated movements in the two eyes. This compensatory behavior is extremely fast, persists with one eye patched, and results in image motion trajectories that are only partially correlated on the two retinas. These findings challenge established views of how humans acquire visual information. They show that ocular drift is precisely controlled, as long speculated [15], and imply the existence of neural mechanisms that integrate minute multimodal signals.

[1]  Masahiro Takei,et al.  Human resource development and visualization , 2009, J. Vis..

[2]  Kathleen E Cullen,et al.  The neural encoding of self-motion , 2011, Current Opinion in Neurobiology.

[3]  Zhong Wang,et al.  A reinterpretation of the purpose of the translational vestibulo-ocular reflex in human subjects. , 2008, Progress in brain research.

[4]  Michele Rucci,et al.  Fixational eye movements, natural image statistics, and fine spatial vision , 2008, Network.

[5]  R M Steinman,et al.  Vision in the presence of known natural retinal image motion. , 1985, Journal of the Optical Society of America. A, Optics and image science.

[6]  J. Victor,et al.  The unsteady eye: an information-processing stage, not a bug , 2015, Trends in Neurosciences.

[7]  Current Biology , 2012, Current Biology.

[8]  M. Rucci,et al.  Precision of sustained fixation in trained and untrained observers. , 2012, Journal of vision.

[9]  W. M. King,et al.  Getting ahead of oneself: Anticipation and the vestibulo-ocular reflex , 2013, Neuroscience.

[10]  A. A. Skavenski,et al.  Miniature eye movement. , 1973, Science.

[11]  Michele Rucci,et al.  Motion parallax from microscopic head movements during visual fixation , 2012, Vision Research.

[12]  Eileen Kowler,et al.  New directions for oculomotor research , 1990, Vision Research.

[13]  J. Demer,et al.  Human gaze stabilization during natural activities: translation, rotation, magnification, and target distance effects. , 1997, Journal of neurophysiology.

[14]  Christopher R Fetsch,et al.  Neural correlates of reliability-based cue weighting during multisensory integration , 2011, Nature Neuroscience.

[15]  W. King,et al.  Anticipatory eye movements stabilize gaze during self‐generated head movements , 2011, Annals of the New York Academy of Sciences.

[16]  S. McKee,et al.  Visual acuity in the presence of retinal-image motion. , 1975, Journal of the Optical Society of America.

[17]  K. Fukushima,et al.  The Vestibular System: A Sixth Sense , 2012 .

[18]  John Pappalardo,et al.  Appendix II , 2020, Medical History.

[19]  Eileen Kowler Eye movements: The past 25years , 2011, Vision Research.

[20]  D E Angelaki,et al.  Short-latency primate vestibuloocular responses during translation. , 1999, Journal of neurophysiology.

[21]  Michele Rucci,et al.  The Visual Input to the Retina during Natural Head-Free Fixation , 2014, The Journal of Neuroscience.

[22]  Arien Mack,et al.  Is perceived motion a stimulus for smooth pursuit , 1982, Vision Research.

[23]  Ralf Engbert,et al.  An integrated model of fixational eye movements and microsaccades , 2011, Proceedings of the National Academy of Sciences.

[24]  Jerome Carriot,et al.  Multimodal Integration of Self-Motion Cues in the Vestibular System: Active versus Passive Translations , 2013, The Journal of Neuroscience.

[25]  Martina Poletti,et al.  Miniature eye movements enhance fine spatial detail , 2007, Nature.

[26]  T. Cornsweet Determination of the stimuli for involuntary drifts and saccadic eye movements. , 1956, Journal of the Optical Society of America.

[27]  Sidney M. Rubens,et al.  Cube‐Surface Coil for Producing a Uniform Magnetic Field , 1945 .

[28]  H Collewijn,et al.  Gain and delay of human vestibulo-ocular reflexes to oscillation and steps of the head by a reactive torque helmet. I. Normal subjects. , 1997, Acta oto-laryngologica.

[29]  Robert M. Steinman,et al.  Moveo ergo video: natural retinal image motion and its effects on vision , 1995 .

[30]  Eileen Kowler,et al.  Slow control with eccentric targets: Evidence against a position-corrective model , 1993, Vision Research.

[31]  Martina Poletti,et al.  Stability of the Visual World during Eye Drift , 2010, The Journal of Neuroscience.

[32]  T. Haslwanter Mathematics of three-dimensional eye rotations , 1995, Vision Research.

[33]  JoHiN KRAUSKOPFt Analysis of eye movements during monocular and binocular fixation. , 2004 .

[34]  H. Helmholtz Helmholtz's Treatise on Physiological Optics , 1963 .

[35]  Martina Poletti,et al.  Microscopic Eye Movements Compensate for Nonhomogeneous Vision within the Fovea , 2013, Current Biology.

[36]  R. W. Ditchburn,et al.  Involuntary eye movements during fixation , 1953, The Journal of physiology.

[37]  H. Collewijn,et al.  Early components of the human vestibulo-ocular response to head rotation: latency and gain. , 2000, Journal of neurophysiology.

[38]  Michele Rucci,et al.  Decorrelation of neural activity during fixational instability: Possible implications for the refinement of V1 receptive fields , 2004, Visual Neuroscience.

[39]  C. J. Keemink,et al.  Contrast sensitivity for oscillating sine wave gratings during ocular fixation and pursuit , 1988, Vision Research.

[40]  Haim Sompolinsky,et al.  Bayesian model of dynamic image stabilization in the visual system , 2010, Proceedings of the National Academy of Sciences.

[41]  J. Victor,et al.  Temporal Encoding of Spatial Information during Active Visual Fixation , 2012, Current Biology.

[42]  A. A. Skavenski,et al.  Quality of retinal image stabilization during small natural and artificial body rotations in man , 1979, Vision Research.

[43]  H. Bülthoff,et al.  Merging the senses into a robust percept , 2004, Trends in Cognitive Sciences.

[44]  J NACHMIAS,et al.  Two-dimensional motion of the retinal image during monocular fixation. , 1959, Journal of the Optical Society of America.