ライフサイエンスコーパス: binocular vision

1 of 10 prism diopters or less and evidence of binocular vision).

2 convergence insufficiency and 50 had normal binocular vision.

3 s with preoperative diplopia achieved single binocular vision.

4 amework for understanding the development of binocular vision.

5 ufficiency is a common issue in the field of binocular vision.

6 viously established psychophysical models of binocular vision.

7 ed, whereas the human brain relies mainly on binocular vision.

8 wo channels (ears) being much weaker than in binocular vision.

9 nd its existence suggests the possibility of binocular vision.

10 or with vision in one eye blurred to disrupt binocular vision.

11 that can produce visual discomfort and harm binocular vision.

12 g MD and their recovery after restoration of binocular vision.

13 dissect the underlying neural circuitry for binocular vision.

14 is a requirement to evaluate the quality of binocular vision.

15 yes, likely a key step in the development of binocular vision.

16 in individuals with and without disorders of binocular vision.

17 Diagnosis of a disorder of binocular vision.

18 e claims for beneficiaries with disorders of binocular vision.

19 ms in the mouse, we utilised the geometry of binocular vision.

20 s to a change in the developmental timing of binocular vision.

21 l geniculate nucleus (dLGN), are crucial for binocular vision.

22 ntralaterally to establish the circuitry for binocular vision.

23 ask, in human adults long deprived of normal binocular vision.

24 contralateral eye-dominated V1 and deficient binocular vision.

25 by animal species that lack highly developed binocular vision.

26 ncrossed projections, a pattern critical for binocular vision.

27 ensitivity in the amblyopic eye and abnormal binocular vision.

28 on about scale from both distance walked and binocular vision.

29 c fixation, severe initial amblyopia, and no binocular vision.

30 ered a few hours after restoration of normal binocular vision.

31 iod alter the cortical circuits that support binocular vision.

32 ralateral brain visual centers, critical for binocular vision.

33 nocular deprivation: reverse deprivation and binocular vision.

34 uences for visuomotor processing of removing binocular vision.

35 .14 [0.38] logMAR in the EP group; P < .001; binocular vision: -0.14 [0.15] logMAR in the control gro

36 e two eyes on cortical mechanisms underlying binocular vision [1, 2], and experience's impact on this

37 Among the 46 participants with abnormal binocular vision, 36 (78%) reported that they had no obv

38 rategy for stereopsis.SIGNIFICANCE STATEMENT Binocular vision allows us to derive depth information b

39 of experience-dependent brain development is binocular vision, also called stereopsis.

40 these children at age 5 had no demonstrable binocular vision and 28.2% had visual acuity of 0.3 (log

41 developing visual cortex can cause impaired binocular vision and amblyopia.

42 OR) for the association between disorders of binocular vision and any of the 3 injury types was 2.23

43 cting suppression is essential for assessing binocular vision and conducting visual training.

44 to the required movement on these axes under binocular vision and confirmed that the required depth m

45 contralaterally (cRGCs) to the brain permits binocular vision and depth perception.

46 l mechanisms in the thalamus in establishing binocular vision and may have critical implications for

47 set of connections following restoration of binocular vision and provide new insight into how recove

48 foundation for using tree shrews in studying binocular vision and raise an exciting possibility of ho

49 isual system.SIGNIFICANCE STATEMENT Abnormal binocular vision and reduced acuity are hallmarks of amb

50 e been studied extensively in the context of binocular vision and rivalry [1], but it remains unknown

51 viewed four objects from one location, with binocular vision and small head movements then, without

52 ings indicate that the development of normal binocular vision and spatial acuity depend upon experien

53 better results, allowing the development of binocular vision and stereopsis and reducing the inciden

54 , residual deficits in contrast sensitivity, binocular vision, and motion perception might impair vis

55 to a comprehensive examination for detecting binocular vision anomalies before and after cataract sur

56 sts is an outstanding screening protocol for binocular vision anomalies before cataract surgery.

57 vision testing protocol for the diagnosis of binocular vision anomalies.

58 to the prediction of pre- and post-surgical binocular vision anomalies.

59 for improving stereo vision in patients with binocular vision anomalies.

60 Disorders of binocular vision are increasingly prevalent among fee-fo

61 Refractive error and binocular vision assessment, integrating accommodative p

62 toperative outcomes indicate improvements in binocular vision at far, intermediate, and near distance

63 of myopia onset influences accommodative and binocular vision behavior in adulthood, emphasizing the

64 in the visual cortex that reduce acuity and binocular vision by causing neurons to lose responsivene

65 This genetic hierarchy controls binocular vision by regulating the magnitude and source

66 de that some human adults deprived of normal binocular vision can recover stereopsis at least partial

67 near visual symptoms in children with normal binocular vision compared with symptoms caused by prefer

68 (BiS), or improvement in visual acuity using binocular vision compared with the better eye alone, is

69 This study examines whether brief periods of binocular vision could preserve stereopsis in monkeys re

70 e six monkeys wore prisms but had 2 hours of binocular vision daily, one for 4, one for 6, and two fo

71 Binocular vision depends on retinal ganglion cell (RGC)

72 use depth discrimination.(5)(,)(9) Mice with binocular vision descended to a near (shallow) surface m

73 irmed that the required depth movement under binocular vision determined depth error independent of t

74 The results demonstrate that early binocular vision development in monkeys is not constrain

75 To resolve this fundamental issue in binocular vision development, we measured the responsive

76 line with findings on a critical period for binocular vision development.

77 sodes of abnormal vision will cause abnormal binocular vision development.

78 Disrupting binocular vision during a developmental critical period

79 Together, these results reveal that balanced binocular vision during development is essential for dri

80 sually guided behaviors in mice that require binocular vision (e.g., predation), our measures will pr

81 Optometric Extension Program (OEP) expected binocular vision findings have longstanding use in optom

82 ibe the functional and behavioral aspects of binocular vision, focusing on the mouse, and discuss rec

83 ia and as an outcome measure for recovery of binocular vision following therapy.

84 ctions, and in revealing the independence of binocular vision from eye movements.

85 hes (item 3) more frequently than the normal binocular vision group did.

86 Medicare beneficiaries with a disorder of binocular vision have significantly higher odds of susta

87 te hemisphere, a pattern critical for proper binocular vision, have not been identified.

88 a common ocular misalignment that can impair binocular vision if untreated.

89 on stereoacuity in individuals with no known binocular vision impairments.

90 omotor-Test-System (VR-OTS) was used testing binocular vision in 9 gaze directions via stereoscopic s

91 Binocular vision in amblyopes is often disrupted by inte

92 eopening of plasticity in the adult restores binocular vision in amblyopic mice.

93 of the neural deficits caused by mismatched binocular vision in early childhood has predominantly fo

94 nsitivity) showed only slight differences in binocular vision in favour of the expedited-surgery grou

95 l, which plays roles in contrast sensing and binocular vision in mice.

96 projections likely preceded the emergence of binocular vision in tetrapods.

97 thfinding, development events fundamental to binocular vision in the adult animal.

98 ies that the brain may independently process binocular vision information on each axis.

99 In mammals with binocular vision, integration of the left and right visu

100 Binocular vision is created by fusing the separate input

101 ical and psychophysical studies confirm that binocular vision is crucial for the accurate planning an

102 Effective binocular vision is dependent on both motor and perceptu

103 Development or restoration of binocular vision is one of the key goals of strabismus m

104 y of rivalry provides the mechanism by which binocular vision is optimized for viewing natural images

105 uidance at the midline and for analyzing how binocular vision is patterned.

106 One of the fundamental challenges of binocular vision is that objects project to different po

107 Binocular vision is traditionally treated as two process

108 enomena, which indicate that a wider view of binocular vision is warranted.

109 Two hours of daily binocular vision largely preserves local and global ster

110 n stereo blindness, whereas daily periods of binocular vision limited the reduction to a twofold loss

111 Participants with binocular vision losses due to developmental disorders (

112 Electrophysiological evidence indicates that binocular vision may be particularly important for the v

113 (up to 60 degrees ), suggesting that extreme binocular vision may facilitate tool use.

114 Most binocular vision models assume that the two eyes sum inc

115 e investigated whether there is a deficit in binocular vision near the vertical meridian in humans an

116 st corrected visual acuity (BCVA) of logMAR, binocular vision, ocular health and management outcomes.

117 and is then re-opened recover rapidly during binocular vision or much more slowly following reverse o

118 firm whether these findings reflect impaired binocular vision or stringent criteria.

119 isual deprivation persists for days, even if binocular vision precedes monocular deprivation.

120 Daily periods of binocular vision preserved stereopsis over 16 weeks of o

121 rgence insufficiency (CI) is the most common binocular vision problem, associated with blurred/double

122 We conclude that binocular vision provides useful information for locatin

123 One article this year discusses binocular vision recovery in bilateral keratoplasty and

124 Mammalian binocular vision relies on the divergence of retinal gan

125 Mammalian binocular vision requires ipsi- and contralateral projec

126 Functional binocular vision requires that inputs arising from the t

127 Binocular vision requires the segregation of retinal gan

128 Binocular vision requires us to match up the different v

129 onkeys treated for 4 weeks, daily periods of binocular vision rescued stereopsis from the 10-fold red

130 In animals with binocular vision, retinal ganglion cell (RGC) axons eith

131 In mammals with binocular vision, retinal ganglion cell (RGC) axons from

132 In animals with binocular vision, retinal ganglion cell (RGC) axons from

133 As a result, under binocular vision, ROT (90), which required the largest d

134 To compare the effectiveness of a brief binocular vision screening protocol to a comprehensive e

135 In seven participants with normal binocular vision, sensory eye dominance was assessed usi

136 and the need for future exploration of near binocular vision status as a potential driver of astheno

137 orn), the initial severity of the amblyopia, binocular vision status, fixation of the amblyopic eye,

138 initial severity of amblyopia, fixation, and binocular vision status; treatment factors: refractive a

139 5 (4.5%) had at least 1 reported disorder of binocular vision (strabismus, 2.3%; diplopia, 2.2%; ambl

140 has examined the influence that disorders of binocular vision (strabismus, amblyopia, diplopia, and n

141 ular global geolocation (MGG) and long-range binocular vision target geolocation (LRBVTG) by obtainin

142 A comprehensive binocular vision test battery as a gold standard were ad

143 has similar effectiveness as a comprehensive binocular vision testing protocol for the diagnosis of b

144 Albinos usually have such poor binocular vision that they perform very poorly on clinic

145 utational model of the development of active binocular vision to fill this gap.

146 type-specific set of ipsi-RGCs that supports binocular vision to guide predation.

147 ceived as a serious game designed to provide binocular vision training to anisometropic amblyopic chi

148 a novel VR-based system designed to provide binocular vision training to children with anisometropic

149 cent study provides compelling evidence that binocular vision uses two separate channels; one channel

150 creased sensory uncertainty due to disrupted binocular vision was a small bias in gaze towards closer

151 f cortical binocularity after restoration of binocular vision was similarly unaffected by HSV-mCREB t

152 ction, glasses prescriptions, deviation, and binocular vision were collected.

153 practice, 100 children aged 9-18 with normal binocular vision were recruited to receive either the or

154 This patient suffered severe symptoms in binocular vision, which can be explained by a spontaneou

155 ular neurons in V1 are the cellular basis of binocular vision, which is required for predation.

156 d eyes suggest that Megalomatia probably has binocular vision, which would have played a significant

157 llected from twenty participants with normal binocular vision while performing vergence eye movements

158 Patients with binocular vision will be sensitive to diplopia in any ga