ライフサイエンスコーパス: saccadic eye movement

1 ogram items, low-level sensory features, and saccadic eye movement.

2 mifield to the other because of a horizontal saccadic eye movement.

3 the ANT is predictively modulated before the saccadic eye movement.

4 osition of gaze, the hand, and the goal of a saccadic eye movement.

5 targets even when they are not the goal of a saccadic eye movement.

6 rontal eye field (FEF) carries such a CD for saccadic eye movements.

7 smus, strabismic monkey display disconjugate saccadic eye movements.

8 and responded with either button presses or saccadic eye movements.

9 examined using data on the neural control of saccadic eye movements.

10 shifts in 'natural' videos designed to mimic saccadic eye movements.

11 ld requires coordination between pursuit and saccadic eye movements.

12 sms underlying the planning and execution of saccadic eye movements.

13 ation of visual stimuli and the direction of saccadic eye movements.

14 g, finger tapping, pronation/supination, and saccadic eye movements.

15 t either remained stationary or moved during saccadic eye movements.

16 ogram (RDK) paradigm and recordings of their saccadic eye movements.

17 responsive neurones discharged in advance of saccadic eye movements.

18 y also respond in advance of visually guided saccadic eye movements.

19 shifts of attention are usually followed by saccadic eye movements.

20 he compensation for target velocity shown by saccadic eye movements.

21 ght be linked to the preparations for making saccadic eye movements.

22 ted to the control of vertical and torsional saccadic eye movements.

23 means for assuring the conjugacy of vertical saccadic eye movements.

24 that are related to the control of vertical saccadic eye movements.

25 nvironment through orienting actions such as saccadic eye movements.

26 time of either ipsilesional limb reaches or saccadic eye movements.

27 sion results from sensory sampling guided by saccadic eye movements.

28 izes, diverse EEG setups, and artifacts like saccadic eye movements.

29 n: preferential routing of sensory input and saccadic eye movements.

30 flects the planning of behaviorally relevant saccadic eye movements.

31 brain forms decisions comes from studies of saccadic eye movements.

32 r on object recognition) to the precision of saccadic eye movements.

33 a V4 of nonhuman primates trained to execute saccadic eye movements.

34 onkeys that is triggered by the execution of saccadic eye movements.

35 more natural conditions, they make frequent saccadic eye movements.

36 esponse field (RF) stimuli are targeted with saccadic eye movements.

37 t of the BG-brainstem projection controlling saccadic eye movements.

38 explore the visual world through the use of saccadic eye movements.

39 ial functions, such as spatial attention and saccadic eye movements.

40 retina and serially sample visual scenes by saccadic eye movements.

41 visuospatial attention may be linked through saccadic eye movements.

42 atable behavioral deficits in the metrics of saccadic eye movements.

43 of visual targets flashed around the time of saccadic eye movements.

44 of structures involved in the programming of saccadic eye movements.

45 nd specifying the amplitude and direction of saccadic eye movements.

46 ons that are directly involved in triggering saccadic eye movements.

47 of spatial attention, even in the absence of saccadic eye movements.

48 s), and electrical stimulation of CDt evokes saccadic eye movements.

49 o not see the visual motion generated by our saccadic eye movements.

50 in the transformation of visual signals into saccadic eye movements.

51 ld as stable, although we constantly perform saccadic eye movements?

52 and increased their discharge rate ahead of saccadic eye movements (11 of 54 tested, 20%).

53 alled oculomotor range that is accessible by saccadic eye movements [5,6].

54 examined the effects of ketamine on leading saccadic eye movements, a specific component of the smoo

55 Saccadic eye movements activated the caudate nucleus sig

56 he findings suggest that a signal related to saccadic eye movements alters V1 spiking to increase the

57 e neurons was predictive of the latency of a saccadic eye movement and not other saccade parameters s

58 The coupling between saccadic eye movements and attention is assumed to be ro

59 ught to mediate spatial orienting, including saccadic eye movements and covert spatial attention.

60 times, we measured visual sensitivity before saccadic eye movements and during fixation at locations

61 olation by performing combined recordings of saccadic eye movements and fast event-related fMRI durin

62 ive fields of macaque area V4 neurons during saccadic eye movements and find that receptive fields ar

63 Saccadic eye movements and fixations are the behavioral

64 in the oculomotor vermis of marmosets during saccadic eye movements and found that following the pres

65 We consider saccadic eye movements and hypothesize that duration of

66 ng target are slower and longer lasting than saccadic eye movements and it has been suggested that in

67 nts, beyond its traditional roles in guiding saccadic eye movements and localizing attention.

68 This study predicts that saccadic eye movements and normal head movements after v

69 on and size of saccades, the consequences of saccadic eye movements and their resulting EMREOs for he

70 The close relationship between saccadic eye movements and vision complicates the identi

71 implicated as a salience map for control of saccadic eye movements and visual attention.

72 inaccurately represent eye position during a saccadic eye movement, and to be too slow to support a r

73 ional modulations that occur while preparing saccadic eye movements, and highlight their differences

74 ause of the rapid and reproducible nature of saccadic eye movements, and the key role that they play

75 Vertical saccadic eye movements are accompanied by concurrent eye

76 Saccadic eye movements are among the most frequent perce

77 ual-oculomotor phenomenon: A period in which saccadic eye movements are dominated by external stimuli

78 here sensorimotor transformations leading to saccadic eye movements are implemented in the brain, les

79 Sequences of saccadic eye movements are instrumental in navigating ou

80 When voluntary saccadic eye movements are made to a silently ticking cl

81 stem and the brainstem circuits that control saccadic eye movements are particularly well understood,

82 Saccadic eye movements are the result of neural decision

83 hanism are compatible with the rate at which saccadic eye movements are typically observed in natural

84 Using the saccadic eye movement as a probe, we provide results tha

85 ntribution to the planning and triggering of saccadic eye movements as well as to the control of visu

86 cenes require that a target for an impending saccadic eye movement be selected from a larger number o

87 cenes require that a target for an impending saccadic eye movement be selected from a number of possi

88 he oculomotor system can correct itself when saccadic eye movements become inaccurate.

89 The frequency of these saccadic eye movements belies the complexity underlying

90 isual scenes or the blurs caused by rapid or saccadic eye movements between successive fixations.

91 Saccadic eye movements "bring" eccentric targets to the

92 e related to opposite directions of vertical saccadic eye movements but that project to the same moto

93 We explore the visual world through saccadic eye movements, but saccades also present a chal

94 ence of a causal link between the control of saccadic eye movements by frontal cortex and covert visu

95 elp gate the transition between fixation and saccadic eye movements by monosynaptically suppressing a

96 nt contributions to our understanding of how saccadic eye movements can be rapidly inhibited, changed

97 rience seems continuous and detailed despite saccadic eye movements changing retinal input several ti

98 perficial SC, suggesting a novel pathway for saccadic eye movement choice.

99 tial attention, these biases reflect nascent saccadic eye movement commands.

100 When saccadic eye movements consistently fail to land on the

101 may indicate right-hemispheric dominance for saccadic eye movement control.

102 visual world despite our frequent quick, or saccadic, eye movements: corollary discharge about each

103 hat SC buildup neuronal activity signals the saccadic eye movement decision.

104 ify the temporal impulse response underlying saccadic eye movement decisions.

105 lts suggest that reward-dependent changes in saccadic eye movements depend partly on dopaminergic mod

106 Saccadic eye movements direct the high-resolution foveae

107 To examine the speed and accuracy of saccadic eye movements during a novel eye tracking thres

108 gets, and measured how this illusion affects saccadic eye movements during FEF microstimulation.

109 erience the visual world through a series of saccadic eye movements, each one shifting our gaze to br

110 easily be dissociated from the generation of saccadic eye movements, especially when sophisticated be

111 The amplitude and direction of saccadic eye movements evoked electrically from the dors

112 Saccadic eye movements facilitate rapid and efficient ex

113 Participants were asked to make saccadic eye movements for different monetary rewards, w

114 This study examines the consequences of saccadic eye movements for the internal representation o

115 ing and processing speed for visually guided saccadic eye movement generation after FEF lesions and a

116 The primary endpoint was horizontal saccadic eye movement (HSEM) velocity, based on its corr

117 emonstrated that during the preparation of a saccadic eye movement, human observers anticipate defini

118 With every saccadic eye movement, humans bring new information into

119 related but kinematically distinct types of saccadic eye movement in larval zebrafish as a model to

120 participants to make two visually triggered saccadic eye movements in brief succession.

121 n has been used to argue that the DMFC codes saccadic eye movements in head-centered coordinates.

122 ings confirm the claim that the DMFC encodes saccadic eye movements in head-centered coordinates.

123 upled between the eyes, similar to conjugate saccadic eye movements in humans.

124 and execution of visually guided manual and saccadic eye movements in macaque monkeys.

125 f this study was to examine the conjugacy of saccadic eye movements in monkeys with sensory strabismu

126 ve assessment of cortical networks governing saccadic eye movements in multiple sclerosis.

127 s (MD) conveys oculomotor CD associated with saccadic eye movements in nonhuman primates.

128 Monkeys learned to select one of four saccadic eye movements in response to a foveal instructi

129 help ensure the coordination of pursuit and saccadic eye movements in selecting a single target.

130 Saccadic eye movements in the vertical plane are control

131 ort the direction of the cue by performing a saccadic eye movement into the same direction following

132 ave shown that binocular coordination during saccadic eye movement is affected in humans with large s

133 A key structure for directing saccadic eye movements is the superior colliculus (SC).

134 The accuracy of saccadic eye movements is thought to be mediated by an i

135 The purpose of saccadic eye movements is to facilitate vision, by placi

136 holds are elevated before, during, and after saccadic eye movements, is an important mechanism for ma

137 y encoding as well as with the generation of saccadic eye movements, is mediating the unconscious pro

138 mple are movements of the eardrum induced by saccadic eye movements, known as "eye movement-related e

139 In monkeys deciding between alternative saccadic eye movements, lateral intraparietal (LIP) neur

140 For saccadic eye movements, learning also alters space perce

141 l stimuli in the contralateral field and for saccadic eye movements made to those stimuli.

142 However, the amplitude of saccadic eye movements made to visual targets can be sys

143 how the motor systems for smooth pursuit and saccadic eye movements might extract a usable signal of

144 , and those activated during visually guided saccadic eye movements, namely the supplementary eye fie

145 had been trained to generate visually-guided saccadic eye movements of a particular size and directio

146 This study aims to determine whether the saccadic eye movements of people with glaucoma differ fr

147 d that stimulation of the DMFC always evoked saccadic eye movements of the same size and direction be

148 We studied the effects of saccadic eye movements on visual signaling in the primat

149 ferrets reveals that, during visual pursuit, saccadic eye movements optimize optic flow patterns, rat

150 When we make saccadic eye movements or goal-directed arm movements, t

151 art of a network of brain areas that directs saccadic eye movements, overtly shifting both gaze and a

152 Saccadic eye movements play a central role in primate vi

153 ontrols; AUC = 0.73; 95% CI, 0.50-0.89); and saccadic eye movements prosaccade latency (30 studies in

154 Saccadic eye movements provide a valuable model to study

155 Adaptation of saccadic eye movements provides an excellent motor learn

156 Saccadic eye movements rapidly shift the visual scene ac

157 fts, where head movements are accompanied by saccadic eye movements, rather than to head movements wh

158 Specifically, before the initiation of a saccadic eye movement, receptive fields shrink and shift

159 The amplitude and direction of saccadic eye movements remained invariant to such manipu

160 ed manual button press (humans) or a speeded saccadic eye movement response (humans and monkeys).

161 d that S cone stimuli did not cause IOR when saccadic eye movement responses were required.

162 Saccadic eye movements (saccades) disrupt the continuous

163 Saccadic eye movements (saccades) in primates organize t

164 When interacting with the visual world using saccadic eye movements (saccades), the perceived locatio

165 During visual exploration, saccadic eye movements scan the scene for objects of int

166 or and perceptual changes during learning of saccadic eye movements, showing that learning is actuall

167 control of gaze implies the ability to make saccadic eye movements specified by abstract instruction

168 Our studies show mice make saccadic eye movements spontaneously and in response to

169 Every saccadic eye movement that we make changes the image of

170 es constantly explore their surroundings via saccadic eye movements that bring different parts of an

171 lesions have revealed only mild deficits in saccadic eye movements that recovered rapidly.

172 (TMS) to any part of the human head during a saccadic eye movement, the ongoing eye velocity was redu

173 During saccadic eye movements, the job of the nervous system is

174 s may not be directly involved in triggering saccadic eye movements, they are nonetheless highly sacc

175 to smooth-pursuit response time and to total saccadic eye-movement time were measured.

176 To make a saccadic eye movement to a target we must first attend t

177 Each monkey was trained to make saccadic eye movements to a field of moving dots or to w

178 Monkeys were trained to produce saccadic eye movements to a visual target.

179 he monkeys to occasionally withhold planned, saccadic eye movements to a visual target.

180 umans actively sample their environment with saccadic eye movements to bring relevant information int

181 Animals can make saccadic eye movements to intercept a moving object at t

182 neurons and the degree of visual guidance of saccadic eye movements to objects of different form.

183 tests in which animals were trained to make saccadic eye movements to paired or multiple targets pre

184 ct during the initiation of both pursuit and saccadic eye movements to parafoveal targets.

185 s and other animals with foveate vision make saccadic eye movements to prioritize the visual analysis

186 explore environment by active sensing, using saccadic eye movements to relocate the fovea and sample

187 bjects were obliged to make both pursuit and saccadic eye movements to track the mask covering the ta

188 We understand the world by making saccadic eye movements to various objects.

189 Subjects made saccadic eye movements toward a visual target that was d

190 loration of complex visual scenes depends on saccadic eye movements toward important locations.

191 slowly, and its presence was independent of saccadic eye movements toward the targets.

192 tested this theory under the hypothesis that saccadic eye movements, tracking an unseen reaching move

193 Humans perform saccadic eye movements two to three times per second.

194 A sequence of saccadic eye-movement vectors, moving from one salient f

195 increasing intravenous doses of diazepam on saccadic eye movement velocity and accuracy (the latter

196 rom baseline to months 12 and 24 in vertical saccadic eye movement velocity as determined by the peak

197 ficant between-group differences in vertical saccadic eye movement velocity or in the other neurologi

198 During the preparation of saccadic eye movements, visual attention is confined to

199 Shortly before saccadic eye movements, visual sensitivity at the saccad

200 tes learning of image statistics and directs saccadic eye movements, we propose that the acquisition

201 ty) and numbers, amplitudes, and subtypes of saccadic eye movements were compared.

202 ll amplitude, nasally directed (ipsiversive) saccadic eye movements were evoked by microstimulation i

203 r to the anterior frontal sulcus, from which saccadic eye movements were evoked with electrical stimu

204 ked by SC stimulation as well as spontaneous saccadic eye movements were larger in the dark-reared mi

205 Saccadic eye movements were measured using infra-red ocu

206 ectrical microstimulation to the SC, so that saccadic eye movements were not evoked.

207 Saccadic eye movements were recorded using an infrared s

208 icant increase in the probability of evoking saccadic eye movements when low current electrical stimu

209 to recall the sequence and reproduce it with saccadic eye movements when presented with an array of o

210 We examined whether the preparation of saccadic eye movements, when behaviorally dissociated fr

211 le, expectation of reward increases speed of saccadic eye movements, whereas expectation of effort de

212 y to select the task-relevant stimulus for a saccadic eye movement, while inhibiting saccades to task

213 model can be used to evaluate populations of saccadic eye movements with different ranges of amplitud

214 al for transforming spatial information into saccadic eye movements, yet its functional organization