Compensatory and Orienting Eye Movements Induced By Off-Vertical Axis Rotation (OVAR) in Monkeys

Kushiro, Keisuke; Dai, Mingjia; Kunin, Mikhail; Yakushin, Sergei B.; Cohen, Bernard; Raphan, Theodore

doi:10.1152/jn.00197.222

Cited by 41 publications

(48 citation statements)

References 83 publications

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“…In addition, translations on the horizontal plane evoke a second type, though at a much lower sensitivity in normal animals, of eye movements that exhibits low-pass dynamics and is not sensitive to behavioral context (Angelaki and Hess 1996;Telford et al 1998). Existing evidence suggests that the evoked torsional/vertical eye movements to IA/NO translations are part of orienting ocular responses most prominent during changes of head orientation with respect to gravity, i.e., tilts (Kushiro et al 2002;Merfeld et al 2001). Since epithelial hair cells on otolith maculae are equally excited by inertial-or gravitation-driven shearing forces, the diminished orienting ocular responses to head translations on the horizontal plane and compensatory LVOR to tilts suggest that the animals' ability to distinguish translation versus tilt is an active neural process.…”

Section: Compensatory Lvor Versus Orienting Ocular Responsesmentioning

confidence: 99%

Frequency-Dependent Spatiotemporal Tuning Properties of Non–Eye Movement Related Vestibular Neurons to Three-Dimensional Translations in Squirrel Monkeys

Chen-Huang

Peterson

2010

Journal of Neurophysiology

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Chen-Huang C, Peterson BW. Frequency-dependent spatiotemporal tuning properties of non-eye movement related vestibular neurons to threedimensional translations in squirrel monkeys. J Neurophysiol 103: 3219-3237, 2010. First published April 7, 2010 doi:10.1152/jn.00904.2009. Responses of vestibular-only translation sensitive (VOTS) neurons in vestibular nuclei of two squirrel monkeys were studied at multiple frequencies to three-dimensional translations and rotations. A novel frequency-dependent spatiotemporal analysis examined in each neuron whether complex models, with unrestricted response dynamics in three-dimensional (3D) space, provided significantly better fits than restricted models following simple, cosine rule. Subsequently, the statistically selected optimal model was used to predict the maximum translation direction, expressed as a unitary vector, Vt max , and its associated sensitivity and phase across frequencies. Simple models were sufficient to quantify the 3D translational responses of 66% of neurons. Most VOTS neurons, complex or simple, exhibited flat-gain or low-pass response dynamics. The Vt max of simple neurons was fixed, whereas that of complex neurons changed with frequency. The spatial distribution of Vt max in simple neurons, which fell within 30°o f either the horizontal plane or/and the sagittal plane, was closely aligned with Vt max of vestibular afferents. In contrast, the frequencydependent Vt max of most complex neurons migrated from the dorsoventral axis at higher frequency toward the horizontal plane, especially the interaural axis, at lower frequency. When the maximum rotation direction was estimated from responses of the same VOTS neurons to 1.2 Hz yaw, pitch, and roll rotations, complex neurons were more likely to respond to rotations activating vertical canals. Responses to 0.15-0.3 Hz linear accelerations produced by inertial or gravitational forces were indistinguishable in most complex neurons but significantly different in most simple neurons. These observations suggest that simple and complex VOTS neurons constitute distinctive vestibular pathways where complex neurons, exhibiting a novel spatiotemporal filtering mechanism in processing otolith-related signals, are well suited to drive tilt-related responses, whereas simple neurons probably mediate pure translation related responses.

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Section: Compensatory Lvor Versus Orienting Ocular Responsesmentioning

confidence: 99%

Frequency-Dependent Spatiotemporal Tuning Properties of Non–Eye Movement Related Vestibular Neurons to Three-Dimensional Translations in Squirrel Monkeys

Chen-Huang

Peterson

2010

Journal of Neurophysiology

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“…Many previous studies have tried to describe vestibular information processing in terms of more or less sophisticated cascades of linear and nonlinear filters. Although this kind of approach can perfectly describe a large class of experimental phenomena (Kushiro et al 2002;Raphan and Cohen 2002;Raphan and Sturm 1991), it cannot account for the considerable challenge that the brain is faced with by the noisy character of afferent information (Roddey et al 2000;Sadeghi et al 2007). The insight into the nature of vestibular signal processing that one can hope to reach by this kind of modeling is therefore rather limited.…”

Section: Introductionmentioning

confidence: 99%

“…In both these protocols, the sensory mismatch results in a rapid decrease of the vestibular or visual afterresponse, a phenomenon that has also been called dumping, characterized by a sharp shortening of the postrotatory time constant. A completely different type of protocol consists in rotating a subject at constant velocity about a tilted axis (Angelaki and Hess 1996b;Angelaki et al 2000, Harris 1988Kushiro et al 2002) (Fig. 1D).…”

Section: Introductionmentioning

confidence: 99%

Processing of Angular Motion and Gravity Information Through an Internal Model

Laurens

Straumann

Hess

2010

Journal of Neurophysiology

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The vestibular organs in the base of the skull provide important information about head orientation and motion in space. Previous studies have suggested that both angular velocity information from the semicircular canals and information about head orientation and translation from the otolith organs are centrally processed in an internal model of head motion, using the principles of optimal estimation. This concept has been successfully applied to model behavioral responses to classical vestibular motion paradigms. This study measured the dynamic of the vestibuloocular reflex during postrotatory tilt, tilt during the optokinetic afternystagmus, and off-vertical axis rotation. The influence of otolith signal on the VOR was systematically varied by using a series of tilt angles. We found that the time constants of responses varied almost identically as a function of gravity in these paradigms. We show that Bayesian modeling could predict the experimental results in an accurate and consistent manner. In contrast to other approaches, the Bayesian model also provides a plausible explanation of why these vestibulooculo motor responses occur as a consequence of an internal process of optimal motion estimation.

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“…Angelaki et al 1999;Droulez and Darlot 1989;Glasauer 1993;Angelaki 2004, Holly 2000;Kushiro et al 2002;Merfeld et al 1993;Merfeld and Zupan 2002;Mergner and Glasauer 1999;Ormsby and Young 1977), where the neural mechanisms for the mathematical operations are not under study (except to a certain extent in Green and Angelaki (2004), as discussed in Sect. 1).…”

Section: Discussionmentioning

confidence: 99%

Head tilt–translation combinations distinguished at the level of neurons

2006

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Angular and linear accelerations of the head occur throughout everyday life, whether from external forces such as in a vehicle or from volitional head movements. The relative timing of the angular and linear components of motion differs depending on the movement. The inner ear detects the angular and linear components with its semicircular canals and otolith organs, respectively, and secondary neurons in the vestibular nuclei receive input from these vestibular organs. Many secondary neurons receive both angular and linear input. Linear information alone does not distinguish between translational linear acceleration and angular tilt, with its gravity-induced change in the linear acceleration vector. Instead, motions are thought to be distinguished by use of both angular and linear information. However, for combined motions, composed of angular tilt and linear translation, the infinite range of possible relative timing of the angular and linear components gives an infinite set of motions among which to distinguish the various types of movement. The present research focuses on motions consisting of angular tilt and horizontal translation, both sinusoidal, where the relative timing, i.e. phase, of the tilt and translation can take any value in the range -180 degrees to 180 degrees . The results show how hypothetical neurons receiving convergent input can distinguish tilt from translation, and that each of these neurons has a preferred combined motion, to which the neuron responds maximally. Also shown are the values of angular and linear response amplitudes and phases that can cause a neuron to be tilt-only or translation-only. Such neurons turn out to be sufficient for distinguishing between combined motions, with all of the possible relative angular-linear phases. Combinations of other neurons, as well, are shown to distinguish motions. Relative response phases and in-phase firing-rate modulation are the key to identifying specific motions from within this infinite set of combined motions.

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Compensatory and Orienting Eye Movements Induced By Off-Vertical Axis Rotation (OVAR) in Monkeys

Cited by 41 publications

References 83 publications

Frequency-Dependent Spatiotemporal Tuning Properties of Non–Eye Movement Related Vestibular Neurons to Three-Dimensional Translations in Squirrel Monkeys

Frequency-Dependent Spatiotemporal Tuning Properties of Non–Eye Movement Related Vestibular Neurons to Three-Dimensional Translations in Squirrel Monkeys

Processing of Angular Motion and Gravity Information Through an Internal Model

Head tilt–translation combinations distinguished at the level of neurons

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