Factors Affecting the Predictability of Pseudo-random Motion Stimuli in the Pursuit Reflex of Man

Overview

Journal J Physiol

Specialty Physiology

Date 1989 Jan 1

PMID 2778725

Citations 14

Authors

G R Barnes

C J Ruddock

Affiliations

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Abstract

1. Experiments have been performed on human subjects to determine the principal mechanisms underlying the break-down in performance during ocular pursuit of pseudo-random target motion stimuli composed of a mixture of two, four or six sinusoids. As observed in a previous experiment there was a reduction in the ratio of eye velocity to target velocity (eye velocity gain) for lower-frequency components of the stimulus whenever the highest frequency exceeded 0.4 Hz, but the following effects were also observed. 2. Using a combination of four sinusoids in which the three lowest frequencies (0.11, 0.24 and 0.37 Hz) had a constant peak velocity (3 or 6 deg/s) it was shown that an increase in the velocity of the highest frequency (0.78 or 1.56 Hz) caused a progressive decline in gain of the low frequencies and a significant reduction in phase lag for the highest-frequency component. 3. Using a combination of two sinusoids (0.44 and 1.56 Hz), in which the peak velocity was varied over a wide range (4-32 deg/s), it was shown that the reduction in low-frequency gain was dependent on the velocity ratio between the frequency components rather than their absolute velocity. 4. Experiments using a combination of either four or six sinusoids in which the two highest frequencies were very close have revealed a true enhancement in the gain of the highest-frequency component in relation to other frequency components of the stimulus. 5. In the same experiments the phase relationships in the response were shown to vary according to the frequency range of the stimulus in such a way that phase advance was normally present at the lowest frequency even when this ranged up to 0.89 Hz. 6. When the oculomotor system was passively stimulated by allowing the subject to fixate a tachistoscopically illuminated stationary target, pseudo-random target motion induced a response which exhibited characteristics similar to those of active pursuit; that is, enhancement of the gain of the highest frequency and phase advance at the lowest frequency. 7. During passive stimulation the changes in gain of the low frequencies with increasing frequency of the highest-frequency component were not consistent with those of active pursuit. However, increasing the velocity of the highest-frequency component to simulate the retinal velocity error conditions of normal active pursuit caused a significant decrease in low-frequency gain and a subjective effect of high-frequency dominance similar to that observed during active pursuit.(ABSTRACT TRUNCATED AT 400 WORDS)

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References

Robinson D . The mechanics of human smooth pursuit eye movement. J Physiol. 1965; 180(3):569-91. PMC: 1357404. DOI: 10.1113/jphysiol.1965.sp007718. View

Schalen L . Quantification of tracking eye movements in normal subjects. Acta Otolaryngol. 1980; 90(5-6):404-13. DOI: 10.3109/00016488009131742. View

FENDER D . Nonlinearities of the human oculomotor system: gain. Vision Res. 1969; 9(10):1235-46. DOI: 10.1016/0042-6989(69)90111-4. View

FENDER D . Nonlinearities of the human oculomotor system: time delays. Vision Res. 1969; 9(12):1491-503. DOI: 10.1016/0042-6989(69)90065-0. View

Yasui S, Young L . Perceived visual motion as effective stimulus to pursuit eye movement system. Science. 1975; 190(4217):906-8. DOI: 10.1126/science.1188373. View

Barnes G, Benson A, Prior A . Visual-vestibular interaction in the control of eye movement. Aviat Space Environ Med. 1978; 49(4):557-64. View

Lisberger S, Fuchs A . Role of primate flocculus during rapid behavioral modification of vestibuloocular reflex. I. Purkinje cell activity during visually guided horizontal smooth-pursuit eye movements and passive head rotation. J Neurophysiol. 1978; 41(3):733-63. DOI: 10.1152/jn.1978.41.3.733. View

Lisberger S, Fuchs A . Role of primate flocculus during rapid behavioral modification of vestibuloocular reflex. II. Mossy fiber firing patterns during horizontal head rotation and eye movement. J Neurophysiol. 1978; 41(3):764-77. DOI: 10.1152/jn.1978.41.3.764. View

Kase M, Noda H, Suzuki D, Miller D . Target velocity signals of visual tracking in vermal Purkinje cells of the monkey. Science. 1979; 205(4407):717-20. DOI: 10.1126/science.111350. View

10.

Kowler E, Steinman R . The effect of expectations on slow oculomotor control. I. Periodic target steps. Vision Res. 1979; 19(6):619-32. DOI: 10.1016/0042-6989(79)90238-4. View

11.

Kowler E, Steinman R . The effect of expectations on slow oculomotor control. II. Single target displacements. Vision Res. 1979; 19(6):633-46. DOI: 10.1016/0042-6989(79)90239-6. View

12.

Dubois M, COLLEWIJN H . Optokinetic reactions in man elicited by localized retinal motion stimuli. Vision Res. 1979; 19(10):1105-15. DOI: 10.1016/0042-6989(79)90005-1. View

13.

Lisberger S, Evinger C, Johanson G, Fuchs A . Relationship between eye acceleration and retinal image velocity during foveal smooth pursuit in man and monkey. J Neurophysiol. 1981; 46(2):229-49. DOI: 10.1152/jn.1981.46.2.229. View

14.

Waespe W, Buttner U, Henn V . Input-output activity of the primate flocculus during visual-vestibular interaction. Ann N Y Acad Sci. 1981; 374:491-503. DOI: 10.1111/j.1749-6632.1981.tb30894.x. View

15.

Noda H, Warabi T . Eye position signals in the flocculus of the monkey during smooth-pursuit eye movements. J Physiol. 1982; 324:187-202. PMC: 1250699. DOI: 10.1113/jphysiol.1982.sp014106. View

16.

Yasui S, Young L . On the predictive control of foveal eye tracking and slow phases of optokinetic and vestibular nystagmus. J Physiol. 1984; 347:17-33. PMC: 1199431. DOI: 10.1113/jphysiol.1984.sp015050. View

17.

Buttner U, Waespe W . Purkinje cell activity in the primate flocculus during optokinetic stimulation, smooth pursuit eye movements and VOR-suppression. Exp Brain Res. 1984; 55(1):97-104. DOI: 10.1007/BF00240502. View

18.

Robinson D, Gordon J, Gordon S . A model of the smooth pursuit eye movement system. Biol Cybern. 1986; 55(1):43-57. DOI: 10.1007/BF00363977. View

19.

COLLEWIJN H, Tamminga E . Human fixation and pursuit in normal and open-loop conditions: effects of central and peripheral retinal targets. J Physiol. 1986; 379:109-29. PMC: 1182887. DOI: 10.1113/jphysiol.1986.sp016243. View

20.

Noda H . Mossy fibres sending retinal-slip, eye, and head velocity signals to the flocculus of the monkey. J Physiol. 1986; 379:39-60. PMC: 1182884. DOI: 10.1113/jphysiol.1986.sp016240. View