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1 mediates a very basic reflex, the pupillary light reflex.
2 circadian photoentrainment and the pupillary light reflex.
3 cones, and ipRGCs that mediate the pupillary light reflex.
4 indicating its involvement in the pupillary light reflex.
5 e-forming nuclei and an attenuated pupillary light reflex.
6 icating that these cells serve the pupillary light reflex.
7 n cues and rewards, or to alterations in the light reflex.
8 ce tomography (OCT), and the chromatic pupil light reflex.
9 sual field, nystagmus testing, and pupillary light reflex.
10 e assessed neuronal integration of the pupil light reflex.
11 input to the islet grafts via the pupillary light reflex.
12 r negative masking but not for the pupillary light reflex.
13 erent for negative masking and the pupillary light reflex.
14 ent for reaching threshold for the pupillary light reflex.
15 ng circadian photo-entrainment and pupillary light reflex.
16 tal eye fields (FEF) modulates the pupillary light reflex.
17 ilateral ESV, while preserving the pupillary light reflex.
18 ation of circadian rhythms and the pupillary light reflex.
19 and blue colors; visual field; and pupillary light reflex.
20 ession of pineal melatonin, or the pupillary light reflex.
21 ncluding circadian rhythms and the pupillary light reflex.
22 tion of sleep-wake states, and the pupillary light reflex.
23 circadian photoentrainment or the pupillary light reflex.
24 rming visual processes such as the pupillary light reflex and circadian entrainment but also contribu
27 nonimage visual functions, such as pupillary light reflex and circadian photoentrainment, which are g
30 ular injection of AAQ restores the pupillary light reflex and locomotory light avoidance behavior in
33 he subject-fixated coaxially sighted corneal light reflex and pupil center is described not by an ang
34 he subject-fixated coaxially sighted corneal light reflex and the fixation point, the subject-fixated
35 ed dog was functionally blind, and pupillary light reflexes and ERG response amplitudes continued to
36 almic ocular examination including pupillary light reflexes and laboratory examinations; computed tom
38 r competent circadian entrainment, pupillary light reflex, and other non-imaging-forming photic respo
42 ies in circadian photoentrainment, the pupil light reflex, and the circadian regulation of the cone p
43 at the retinotectal fibers serving the pupil light reflex are less susceptible to damage from the OPA
44 circadian photoentrainment and the pupillary light reflex, are thought to be mediated by the combinat
46 he subject-fixated coaxially sighted corneal light reflex avoids the shortcomings of current ocular a
47 he subject-fixated coaxially sighted corneal light reflex axis to a refined definition of the visual
48 he subject-fixated coaxially sighted corneal light reflex axis, is independent of pupillary dilation
50 Rs) from intrinsic melanopsin-mediated pupil light reflexes by comparing pupil responses with red and
51 he subject-fixated coaxially sighted corneal light reflex can be a clinically useful reference marker
52 anglion cells (ipRGCs) mediate the pupillary light reflex, circadian entrainment, and may contribute
53 sic neurological examinations (eg, pupillary light reflex) contributed heavily to a linear model pred
56 and rod-cone photoreceptors to the pupillary light reflex in humans, we compared pupillary light resp
57 This spectrum matches that for the pupillary light reflex in mice of the same genotype, and that for
62 grees ) using 3 techniques (best guess [BG], light reflex [LR], and a ruler measuring [RU] technique)
63 rming visual functions such as the pupillary light reflex, masking behavior, and light-induced melato
64 rsistent constriction phase of the pupillary light reflex may represent a surrogate biomarker for the
65 d by reduced direct and consensual pupillary light reflexes, phenotypic presence of retinal degenerat
66 d-, cone-, and melanopsin-mediated pupillary light reflex (PLR) abnormalities in diabetic patients wh
68 cone, and melanopsin to the human pupillary light reflex (PLR) and to determine the optimal conditio
69 pupillography was used to measure pupillary light reflex (PLR) in 44 healthy children (23 girls, 21
70 It is well established that the pupillary light reflex (PLR) in rats is mediated by a direct retin
72 by the PFC.SIGNIFICANCE STATEMENT The pupil light reflex (PLR) is our brain's first and most fundame
73 visual function in rd/rd mice: the pupillary light reflex (PLR) returned almost to normal; the mice s
74 photoreceptors (rd/rd cl) retain a pupillary light reflex (PLR) that does not rely on local iris phot
75 eated measurements of quantitative pupillary light reflex (PLR) using the Neurolight-Algiscan device.
76 ht surfaces results in an enhanced pupillary light reflex (PLR)-the pupillary constriction that occur
81 cal example of a central reflex is the pupil light reflex (PLR): the automatic constriction of the pu
82 To differentiate rod-cone-mediated pupil light reflexes (PLRs) from intrinsic melanopsin-mediated
84 o environmental light, such as the pupillary light reflex, seasonal adaptations in physiology, photic
86 Mice lacking rods and cones retain pupillary light reflexes that are mediated by intrinsically photos
87 wer eyelid height (measured from the corneal light reflex to the lower eyelid margin, or marginal ref
88 he subject-fixated coaxially sighted corneal light reflex to the surgical centration of refractive tr
89 ion of latency were limited by the number of light reflexes used to estimate the average latency and
90 for determination of the onset of the pupil light reflex was devised that consisted of filtering, in
91 In contrast, sensitivity of the pupillary light reflex was more severely reduced in rd1 than in No
94 lateral miosis on the magnitude of the pupil light reflex was studied to ascertain how a clinically s
95 ral pathways subserving the feline pupillary light reflex were examined by defining retinal input to
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