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1 ally heterogeneous group of disorders of the crystalline lens.
2 each increased the rate of thickening of the crystalline lens.
3 orrect internal refractive properties of the crystalline lens.
4 it, thus replicating the original shape of a crystalline lens.
5 s changes in the spherical aberration of the crystalline lens.
6 t of the unique cellular architecture of the crystalline lens.
7 ium and decreased to 17 +/- 8 mm Hg near the crystalline lens.
8 mary wound closure, and 4) disruption of the crystalline lens.
9 n treating clinically significant subluxated crystalline lenses.
10 axed, freshly extracted intact, clear, human crystalline lenses aged 3, 17, 45, 54, 54, 56, and 56 ye
11 nd genetically heterogeneous disorder of the crystalline lens and a leading cause of visual impairmen
12  The optical device mimics the design of the crystalline lens and ciliary muscle of the human eye.
13 completely new technology for removal of the crystalline lens and compares it to currently available
14 attributed to the age-related changes of the crystalline lens and CRC.
15                                 Removing the crystalline lens and implanting an intraocular lens in a
16                               Imaging of the crystalline lens and intraocular lens is becoming increa
17                                              Crystalline lens and IOLs were visualized and quantified
18 ar distance between the anterior pole of the crystalline lens and the horizontal line joining the 2 s
19 such as thinner, steeper corneae and thinner crystalline lenses and, functionally, a degrading influe
20  by nuclear magnetic resonance spectroscopy; crystalline lens apoptosis was evaluated by TUNEL and ca
21 nts were compared with pathologic changes of crystalline lenses associated with retinal detachment.
22             This light must pass through the crystalline lens before absorption by the MPs can occur.
23 r bone; in another, total replacement of the crystalline lens by adipose tissue; and in a third, an a
24 ng-term corneal endothelium cell density and crystalline lens clarity remain a concern.
25 front science demonstrates that the youthful crystalline lens compensates for aberrations in the corn
26 mmodation data, and videophakometry measured crystalline lens curvatures.
27 illuminance due to varying opaqueness of the crystalline lens do not seem to have a measurable influe
28 ' visual demands and expectations, degree of crystalline lens dysfunction, and other ocular character
29 physical and biomechanical properties of the crystalline lens (e.g., viscoelasticity) have long been
30                                      Thinner crystalline lenses found at longer vitreous chamber dept
31 patients with retinal detachment, dislocated crystalline lens from complicated cataract surgery, endo
32 s with refractive error and the shape of the crystalline lens (Gullstrand lens power) were significan
33                                      Exposed crystalline lenses had significantly increased caspase-3
34                                  Because the crystalline lens has a major mechanistic role, lens extr
35    Concurrent thinning and flattening of the crystalline lens imply that the lens is mechanically str
36           Additionally, removal of the clear crystalline lens in phakic eyes was not necessary in the
37 xial length, thinning, and flattening of the crystalline lens, increases in lens equivalent refractiv
38  knowledge, for the management of subluxated crystalline lenses involving preplacement of an iris-sut
39                       The dislocation of the crystalline lens is a common finding in patients with Ma
40 /left symmetry in the horizontal tilt of the crystalline lens is disrupted on IOL implantation.
41 l deformations on fresh bovine sclera, iris, crystalline lens, kidney fat, orbital pulley tissue, and
42                               The cornea and crystalline lens lost substantial amounts of dioptric po
43 gmented AGEs contributed to yellowing of the crystalline lens nucleus.
44 ies with a lens material that behaves like a crystalline lens of a 25 year old could precisely return
45                             Opacities in the crystalline lens of eye appear with high frequency in th
46 of protecting the cornea, aqueous humor, and crystalline lens of rabbits from UV-induced pathologic c
47 , including the olfactory epithelium and the crystalline lens of the eye.
48 mmodation in the presence of a normal, young crystalline lens or a similar surrogate.
49     Rasgrf1(-/-) mice show a heavier average crystalline lens (P = 0.001).
50 y, the authors measured refractive error and crystalline lens parameters in 994 children in the first
51                          Previous studies of crystalline lens pathologic findings associated with ret
52 ocular components: corneal power, Gullstrand crystalline lens power, and axial length.
53 arental myopia, axial length, corneal power, crystalline lens power, ratio of accommodative convergen
54  patients with surgically treated subluxated crystalline lenses presenting to the Wilmer Eye Institut
55 ons were measured by A-scan ultrasonography, crystalline lens radii of curvature by videophakometry,
56                                  Corneal and crystalline lens radii of curvature were measured in the
57 , anterior chamber depth was 2.9 +/- 0.3 mm, crystalline lens rise 748.18 +/- 393.13 mum, and phakic
58 erior chamber depth, anterior chamber width, crystalline lens rise, and the distance between phakic I
59 ation between higher AC/A ratios and flatter crystalline lens shapes, as well as other reported featu
60 n distances between the ICL and the anterior crystalline lens surface were 557 +/- 224 mum and 528 +/
61                                              Crystalline lens surgery and phakic intraocular lenses a
62 " which the authors define as tension on the crystalline lens that increases the level of effort need
63 eper anterior and vitreous chambers, flatter crystalline lenses that were smaller in volume, and stee
64  anterior chamber depth (-0.22 to +0.18 mm), crystalline lens thickness (-0.21 to +0.27 mm), corneal
65 us depth (AD), anterior chamber depth (ACD), crystalline lens thickness (LT), vitreous depth (VD), an
66 ness, aqueous depth, anterior chamber depth, crystalline lens thickness, white-to-white corneal diame
67                                      Thinner crystalline lenses were associated with more hyperopic r
68  be slightly more vertically tilted than the crystalline lens, with increasing tendency with accommod
69 (n = 92), pseudophakia (n = 131), or natural crystalline lenses without cataract (n = 98).

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