ライフサイエンスコーパス: pursuit eye movement

1 ode in the neural circuit controlling smooth pursuit eye movement.

2 o estimates of target motion to drive smooth pursuit eye movement.

3 a precisely timed change in the direction of pursuit eye movement.

4 ntrol of visually guided saccades and smooth-pursuit eye movements.

5 ange of dynamics normally seen during smooth pursuit eye movements.

6 sociated with a profound asymmetry in smooth pursuit eye movements.

7 for the perception of motion and control of pursuit eye movements.

8 ls coordinate their activity to drive smooth pursuit eye movements.

9 When an object moves, we view it with smooth pursuit eye movements.

10 t to rotational visual cues generated during pursuit eye movements.

11 e visual inputs for behaviors such as smooth pursuit eye movements.

12 ial variations in neural activity and smooth pursuit eye movements.

13 T) are correlated with variability in smooth pursuit eye movements.

14 re larger while the animal was making smooth pursuit eye movements.

15 ionship between motion perception and smooth pursuit eye movements.

16 diate stage in the neural circuit for smooth-pursuit eye movements.

17 dependence as seen in visually guided smooth-pursuit eye movements.

18 motor timing by studying learning in smooth pursuit eye movements.

19 ale comparable with the initiation of smooth pursuit eye movements.

20 i and the right fusiform gyrus during smooth pursuit eye movements.

21 equelae in the direction and speed of smooth pursuit eye movements.

22 m, downstream, or at the site of learning in pursuit eye movements.

23 ral cortex is part of the circuit for smooth pursuit eye movements.

24 al derivative of eye position, during smooth-pursuit eye movements.

25 acement component to the same degree as were pursuit eye movements.

26 ations, and their relatives had worse smooth-pursuit eye movements.

27 tasks requiring fast (exploratory) and slow (pursuit) eye movements.

28 y small idiosyncratic anisotropies in smooth pursuit eye movements, a motor action requiring accurate

29 o rhesus monkeys (Macaca mulatta) performing pursuit eye movements across displays of varying transla

30 n and recall of direction learning in smooth pursuit eye movements across multiple timescales.

31 sual transient.SIGNIFICANCE STATEMENT Smooth pursuit eye movements allow us to track moving objects.

32 result implies that extraretinal signals for pursuit eye movements also contribute to the alleviation

33 mpared with 0.6 +/- 0.07 for visually guided pursuit eye movements and 0.18 +/- 0.09 for the RVOR.

34 und to occur both under conditions of smooth pursuit eye movements and constant fixation, and to be c

35 aque monkeys to initiate saccade-free smooth pursuit eye movements and injected a transient, instanta

36 ther patients and control subjects in smooth pursuit eye movements and on the antisaccade task.

37 hrenia and has a potential to disrupt smooth pursuit eye movements and other visual functions that de

38 e visual cortex and are used to drive smooth pursuit eye movements and perceptual judgments of speed.

39 al and sub-cortical systems mediating smooth pursuit eye movements and sensorimotor gating.

40 e temporal specificity of learning in smooth pursuit eye movements and the well-defined anatomical st

41 perform visually guided saccades and smooth pursuit eye movements and to suppress visually guided sa

42 (small anticipatory) saccades during smooth pursuit eye movements, and cancellation of reflexive sac

43 ts of orienting saccades and tracking smooth pursuit eye movements, and found strong physiological ev

44 dies have shown that abnormalities of smooth pursuit eye movement are increased in the adult relative

45 Smooth pursuit eye movements are abnormal in patients with schi

46 Deficits in smooth pursuit eye movements are an established phenotype for s

47 Smooth pursuit eye movements are considered a well-established

48 Smooth pursuit eye movements are continuous, slow rotations of

49 Smooth pursuit eye movements are generated by a motor system he

50 nslation speed and extraretinal signals from pursuit eye movements are used by MSTd neurons to comput

51 ng of target speed and direction, as well as pursuit eye movements, are significantly impaired at 0.0

52 -to-noise ratio for the initiation of smooth-pursuit eye movements as a function of time and computed

53 revealed the same asymmetry in the monkeys' pursuit eye movements as in humans with early-onset esot

54 us monkeys represent the direction of smooth pursuit eye movements based on both visual cues (dynamic

55 During smooth pursuit eye movements, both tracking position and veloci

56 ty in the frontal eye fields controls smooth pursuit eye movements, but the relationship between sing

57 Learning was induced in smooth pursuit eye movements by repeated presentation of target

58 eurons in monkey frontal cortex that control pursuit eye movements by representing extra-personal spa

59 Learning was induced in the initiation of pursuit eye movements by targets that moved initially at

60 Changing the size of a target for smooth pursuit eye movements changes the relationship between t

61 The present paper asks how primate smooth pursuit eye movements choose targets, by analysis of a n

62 No other indicator, including involuntary pursuit eye movements, covaried with AQ.

63 us of this and other ketamine-induced smooth-pursuit eye-movement deficits involves NMDA receptor fun

64 se neural responses: the initial velocity of pursuit eye movements deviates in a direction perpendicu

65 By means of infrared oculography, smooth pursuit eye movements during a 17 degrees /second visual

66 We measured the pursuit eye movements evoked by stimuli containing two c

67 vide behavioral evidence using monkey smooth pursuit eye movements for four principles of cerebellar

68 ngle rule of ocular kinematics during smooth-pursuit eye movements from eccentric positions.

69 saccades and increasing responses for smooth pursuit eye movements from posterior/medial to anterior/

70 Smooth pursuit eye movement gain (equal to the ratio of eye-tar

71 maximizes information about visual motion in pursuit eye movements guided by that cortical activity.

72 Abnormal smooth pursuit eye movements have been found in many schizophre

73 Smooth pursuit eye movements have been investigated as a diagno

74 that working memory is related to predictive pursuit eye movements; however, the degradation of worki

75 le sensorimotor measures derived from smooth pursuit eye movements in a large sample of psychosis pro

76 tems alter motor behavior, we studied smooth pursuit eye movements in monkeys trained to associate th

77 rm and contrast for the initiation of smooth pursuit eye movements in monkeys, we show that visual mo

78 Abnormal smooth pursuit eye movements in patients with schizophrenia are

79 Here we use visually guided smooth-pursuit eye movements in primates as a testing ground fo

80 norhabditis elegans to the control of smooth pursuit eye movements in primates, and from the coding o

81 Pursuit eye movements in prosthetic vision, compared to

82 ents with schizophrenia have abnormal smooth pursuit eye movements in response to a step-ramp stimulu

83 ed attention on motion perception and smooth-pursuit eye movements in response to moving dichoptic pl

84 Abnormal smooth pursuit eye movements in schizophrenia and related disor

85 of mind in autism to abnormalities of smooth pursuit eye movements in schizophrenia.

86 n a frontotemporal network subserving smooth pursuit eye movements in schizophrenia.

87 to test the hypothesis that abnormal smooth pursuit eye movements in schizophrenic patients are asso

88 s and methodologies, validated during smooth pursuit eye movements in the cerebellar floccular comple

89 velocity discrimination and impaired smooth pursuit eye movements, inasmuch as the brain regions res

90 has been suggested that initiating a smooth pursuit eye movement involves an obligatory "open-loop"

91 The visual input for pursuit eye movements is represented in the cerebral cor

92 he interaction of two distinct operations in pursuit eye movements, learning and vector-averaging, to

93 Smooth pursuit eye movements maintain the line of sight on smoo

94 One-dimensional smooth pursuit eye movements measured via earEOG exhibited a hi

95 timuli sweep across the retina during smooth pursuit eye movements, non-pursued targets are usually p

96 During smooth pursuit eye movement, observers often misperceive veloci

97 The current study compared pursuit eye movements of 60 high-functioning individuals

98 We have used motor learning in smooth pursuit eye movements of monkeys to determine how and wh

99 s during trial-over-trial learning in smooth pursuit eye movements of monkeys.

100 g percepts remain stable, even though smooth-pursuit eye movements often distort optic flow.

101 get trajectories and emit pre-emptive smooth pursuit eye movements--prior to the emergence of a targe

102 Before a saccade, pursuit eye movements reflect a vector average of motion

103 ow that electrical stimulation of the smooth-pursuit eye movement region in the arcuate sulcus of the

104 ral code for sensory-motor latency in smooth pursuit eye movements reveals general principles of neur

105 target motion with normal, high-gain smooth-pursuit eye movements right up until the target was inte

106 Qualitative smooth pursuit eye movement score was significantly worse in re

107 edure, yielding 42 metrics related to smooth pursuit eye movement (SPEM), saccades, dynamic visual ac

108 Abnormal smooth pursuit eye movements (SPEMs) are some of the most repro

109 nisms dominate physiological corrections for pursuit eye movements, suggesting that extraretinal cues

110 In the smooth pursuit eye movement system, neural integration is requi

111 ntrol is also an integral part of the smooth-pursuit eye movement system.

112 e brain hemodynamic response during a smooth pursuit eye movement task in patients with schizophrenia

113 althy comparison subjects performed a smooth pursuit eye movement task while undergoing 1.5-T fMRI.

114 visual cortex while monkeys perform a smooth pursuit eye movement task with prior expectation of the

115 cebo in double-blind fashion during a smooth-pursuit eye-movement task.

116 In smooth pursuit eye movements, the response to a brief perturbat

117 For example, smooth pursuit eye movements to follow a moving target are slow

118 nstrains the rotational axes of saccades and pursuit eye movements to Listing's plane (LP).

119 n between visual motion estimates and smooth pursuit eye movements to measure stimulus-response corre

120 Smooth-pursuit eye movements transform 100 ms of visual motion

121 ructive signals for motor learning in smooth pursuit eye movements under natural conditions, suggesti

122 arget gap and overlap conditions) and smooth pursuit eye movements using an infrared pupil-tracking s

123 ons, including figure-ground segregation and pursuit eye movements, visual functions that are impaire

124 known to be involved in saccadic and smooth-pursuit eye movements, we propose that a nearby region m

125 Smooth pursuit eye movements were assessed during both the init

126 Pursuit eye movements were driven primarily by the local

127 Also, the schizophrenic patients' smooth-pursuit eye movements were tested in response to a 0.3-H

128 imulus, we assessed the initiation of smooth pursuit eye movements when two targets move in different