论文信息 - Cerebrocerebellar Circuits for the Perceptual Cancellation of Eye-movement-induced Retinal Image Motion

Cerebrocerebellar Circuits for the Perceptual Cancellation of Eye-movement-induced Retinal Image Motion

Despite smooth pursuit eye movements, we are unaware of resultant retinal image motion. This example of perceptual invariance is achieved by comparing retinal image slip with an internal reference signal predicting the sensory consequences of the eye movement. This prediction can be manipulated experimentally, allowing one to vary the amount of self-induced image motion for which the reference signal compensates and, accordingly, the resulting percept of motion. Here we were able to map regions in CRUS I within the lateral cerebellar hemispheres that exhibited a significant correlation between functional magnetic resonance imaging signal amplitudes and the amount of motion predicted by the reference signal. The fact that these cerebellar regions were found to be functionally coupled with the left parieto-insular cortex and the supplementary eye fields points to these cortical areas as the sites of interaction between predicted and experienced sensory events, ultimately giving rise to the perception of a stable world despite self-induced retinal motion.

[1] M. Liu,et al. Single-neuron activity in the dorsomedial frontal cortex during smooth-pursuit eye movements to predictable target motion , 1997, Visual Neuroscience.

[2] Annette M. Schmid,et al. An fMRI study of anticipation and learning of smooth pursuit eye movements in humans , 2001, Neuroreport.

[3] T. Brandt,et al. Reciprocal inhibitory visual-vestibular interaction. Visual motion stimulation deactivates the parieto-insular vestibular cortex. , 1998, Brain : a journal of neurology.

[4] S. Kawaguchi,et al. Mossy fibre and climbing fibre responses produced in the cerebellar cortex by stimulation of the cerebral cortex in monkeys , 1977, Experimental Brain Research.

[5] J. Haxby,et al. Functional anatomy of pursuit eye movements in humans as revealed by fMRI. , 1999, Journal of neurophysiology.

[6] P. Thier,et al. Responses of Visual‐Tracking Neurons from Cortical Area MST‐I to Visual, Eye and Head Motion , 1992, The European journal of neuroscience.

[7] J Schlag,et al. Primate supplementary eye field: I. Comparative aspects of mesencephalic and pontine connections , 1990, The Journal of comparative neurology.

[8] O. Grüsser,et al. Is there a vestibular cortex? , 1998, Trends in Neurosciences.

[9] Peter Thier,et al. Cortical Substrates of Perceptual Stability during Eye Movements , 2001, NeuroImage.

[10] L. Stark,et al. Ocular proprioception and efference copy in registering visual direction , 1991, Vision Research.

[11] Peter Thier,et al. An Electrophysiological Correlate of Visual Motion Awareness in Man , 1998, Journal of Cognitive Neuroscience.

[12] Tarek A. Yousry,et al. fMRI signal increases and decreases in cortical areas during small-field optokinetic stimulation and central fixation , 2002, Experimental Brain Research.

[13] Karl J. Friston,et al. Detecting Activations in PET and fMRI: Levels of Inference and Power , 1996, NeuroImage.

[14] Curtis C Bell,et al. Memory-based expectations in electrosensory systems , 2001, Current Opinion in Neurobiology.

[15] M. Glickstein,et al. Visual pontocerebellar projections in the macaque , 1994, The Journal of comparative neurology.

[16] F. Bremmer,et al. An fMRI study of optokinetic nystagmus and smooth-pursuit eye movements in humans , 2005, Experimental Brain Research.

[17] M. Schlag-Rey,et al. Evidence for a supplementary eye field. , 1987, Journal of neurophysiology.

[18] D. Heeger,et al. Neuronal Basis of the Motion Aftereffect Reconsidered , 2001, Neuron.

[19] Alan C. Evans,et al. Three-Dimensional MRI Atlas of the Human Cerebellum in Proportional Stereotaxic Space , 1999, NeuroImage.

[20] Peter Thier,et al. Optimizing Visual Motion Perception during Eye Movements , 2001, Neuron.

[21] O. Grüsser,et al. Cortico‐cortical connections and cytoarchitectonics of the primate vestibular cortex: A study in squirrel monkeys (Saimiri sciureus) , 1992, The Journal of comparative neurology.

[22] D. Wolpert,et al. Central cancellation of self-produced tickle sensation , 1998, Nature Neuroscience.

[23] A. Newen,et al. Beyond the comparator model: A multifactorial two-step account of agency , 2008, Consciousness and Cognition.

[24] J. Pardo,et al. Elucidating Dynamic Brain Interactions with Across-Subjects Correlational Analyses of Positron Emission Tomographic Data: The Functional Connectivity of the Amygdala and Orbitofrontal Cortex during Olfactory Tasks , 1998, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[25] Richard S. J. Frackowiak,et al. Identification of the central vestibular projections in man: a positron emission tomography activation study , 2004, Experimental Brain Research.

[26] R. Sperry. Neural basis of the spontaneous optokinetic response produced by visual inversion. , 1950, Journal of comparative and physiological psychology.

[27] C. Galletti,et al. ‘Real-motion’ cells in area V3A of macaque visual cortex , 2004, Experimental Brain Research.

[28] A. Gibson,et al. Corticopontine visual projections in macaque monkeys , 1980, The Journal of comparative neurology.

[29] D. Wolpert,et al. The cerebellum is involved in predicting the sensory consequences of action , 1999, Neuroreport.

[30] P. Brodal,et al. The corticopontine projection in the rhesus monkey. Origin and principles of organization. , 1978, Brain : a journal of neurology.

[31] F. Binkofski,et al. Cortical mechanisms of smooth pursuit eye movements with target blanking. An fMRI study , 2004, The European journal of neuroscience.

[32] S. Zeki,et al. A visuo‐somatomotor pathway through superior parietal cortex in the macaque monkey: cortical connections of areas V6 and V6A , 1998, The European journal of neuroscience.

[33] Patrick Haggard,et al. Supplementary motor area provides an efferent signal for sensory suppression. , 2004, Brain research. Cognitive brain research.

[34] Guldin Wo,et al. Is there a vestibular cortex , 1998 .

[35] C. Sherrington. OBSERVATIONS ON THE SENSUAL RÔLE OF THE PROPRIOCEPTIVE NERVE-SUPPLY OF THE EXTRINSIC OCULAR MUSCLES , 1918 .

[36] M Dieterich,et al. Cerebellar activation during optokinetic stimulation and saccades , 2000, Neurology.

[37] T. L. Harrington,et al. Neural mechanisms of space vision in the parietal association cortex of the monkey , 1985, Vision Research.

[38] K. Sasaki,et al. Electrophysiological studies on the cerebellocerebral projections in monkeys , 1976, Experimental Brain Research.

[39] S. McKee,et al. Statistical properties of forced-choice psychometric functions: Implications of probit analysis , 1985, Perception & psychophysics.

[40] S. Heinen. Single neuron activity in the dorsomedial frontal cortex during smooth pursuit eye movements , 2004, Experimental Brain Research.

[41] E. Holst,et al. Das Reafferenzprinzip , 2004, Naturwissenschaften.

[42] P. Brodal,et al. The pontocerebellar projection in the rhesus monkey: An experimental study with retrograde axonal transport of horseradish peroxidase , 1979, Neuroscience.

[43] C. Galletti,et al. Neuronal mechanisms for detection of motion in the field of view , 2003, Neuropsychologia.

[44] Alexander H. Wertheim,et al. Motion perception during selfmotion: The direct versus inferential controversy revisited , 1994, Behavioral and Brain Sciences.

[45] Werner Lutzenberger,et al. Neuromagnetic activity in medial parietooccipital cortex reflects the perception of visual motion during eye movements , 2004, NeuroImage.

[46] Uwe J. Ilg,et al. Cancellation of self-induced retinal image motion during smooth pursuit eye movements , 2001, Vision Research.

[47] Jody Tanabe,et al. Brain Activation during Smooth-Pursuit Eye Movements , 2002, NeuroImage.

[48] Richard S. Frackowiak,et al. Neural Correlates of Visual-Motion Perception as Object- or Self-motion , 2002, NeuroImage.

[49] C. Blakemore,et al. Functional imaging of brain areas involved in the processing of coherent and incoherent wide field-of-view visual motion , 2000, Experimental Brain Research.

[50] G. Orban,et al. Motion-responsive regions of the human brain , 1999, Experimental Brain Research.

[51] A. Bronstein,et al. Torsional eye movements are facilitated during perception of self-motion , 1999, Experimental Brain Research.

[52] D. Robinson,et al. Eye movements evoked by cerebellar stimulation in the alert monkey. , 1973, Journal of neurophysiology.

[53] P. Thier,et al. Saccadic Dysmetria and Adaptation after Lesions of the Cerebellar Cortex , 1999, The Journal of Neuroscience.

[54] Hiroshi Imamizu,et al. Human cerebellar activity reflecting an acquired internal model of a new tool , 2000, Nature.

[55] Richard A Andersen,et al. Pursuit Compensation during Self-Motion , 2001, Perception.

[56] Masao Ito. Bases and implications of learning in the cerebellum--adaptive control and internal model mechanism. , 2005, Progress in brain research.

[57] M. Missal,et al. Supplementary eye fields stimulation facilitates anticipatory pursuit. , 2004, Journal of neurophysiology.

[58] Peter Thier,et al. False perception of motion in a patient who cannot compensate for eye movements , 1997, Nature.

[59] J. Stein,et al. Neuronal activity in the lateral cerebellum of trained monkeys, related to visual stimuli or to eye movements. , 1990, The Journal of physiology.

[60] Alex Pentland,et al. Microcomputer-based estimation of psychophysical thresholds: The Best PEST , 1982 .