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1 CM), thereby promoting premature skin aging (photoaging).
2 a major determinant of premature skin aging (photoaging).
3 olar UV irradiation-induced premature aging (photoaging).
4 the pathophysiology of premature skin aging (photoaging).
5 and may contribute to premature skin aging (photoaging).
6 ich may provide potential prevention against photoaging.
7 E(2)) on HA-rich extracellular matrix during photoaging.
8 and anti-inflammatory effects of E(2) during photoaging.
9 ytes and fibroblast-based in vitro models of photoaging.
10 c target for the prevention and treatment of photoaging.
11 skin patterning is a sign of both aging and photoaging.
12 skin wrinkle formation in a murine model of photoaging.
13 possibility of using ERbeta as a target for photoaging.
14 tion associated with chronological aging and photoaging.
15 nm) (UVA) may cause photocarcinogenesis and photoaging.
16 raviolet (UV) light to human skin results in photoaging.
17 olecular mechanism in the pathophysiology of photoaging.
18 ies are directed at improving the results of photoaging.
19 ts in an old and wrinkled appearance, called photoaging.
20 let AI light (340 to 400 nm) associated with photoaging.
21 y and/or antioxidant activities, may prevent photoaging.
22 s-links might be useful markers of aging and photoaging.
23 s toxic intermediates in the pathogenesis of photoaging.
24 f compounds that protect against UVA-induced photoaging.
25 degrade skin collagen and may contribute to photoaging.
26 enzymes, as mediators of collagen damage in photoaging.
27 protection against skin cancer, sunburn, and photoaging, a genome-wide perspective of gene expression
28 alterations represent acute events, whereas photoaging and carcinogenesis are long-term consequences
29 trix proteins play a functional role in skin photoaging and carcinogenesis by sensitization of photo-
30 Radiation-induced skin damage ranges from photoaging and cutaneous carcinogenesis caused by UV exp
32 ene expression program associated with human photoaging and intrinsic skin aging (collectively termed
33 ved to underlie changes associated with both photoaging and natural aging, we determined whether natu
34 ers of oxidative stress underlying cutaneous photoaging and photocarcinogenesis, but the molecular id
40 a suggest a previously unreported pathway of photoaging and support the concept that photoaging is at
41 skin due to ultraviolet light from the sun (photoaging) and damage occurring as a consequence of the
43 rix may serve as markers for skin aging, for photoaging, and for immediate assessment of exposure to
44 e appropriate for mild, moderate, and severe photoaging, and in educating patients on the risks and b
49 erienced in daily life, potentially promotes photoaging by affecting breakdown, rather than synthesis
51 n from sunlight causes premature skin aging (photoaging), characterized in part by wrinkles, altered
54 UVA1 induction of MMP12 mediates some of its photoaging effects, particularly by contributing to elas
55 levance of using fibrillin-1 as a marker for photoaging, facial skin was biopsied at baseline and aft
56 determined whether natural skin aging, like photoaging, gives rise to increased matrix metalloprotei
58 This Commentary reports on the effects of photoaging in an experimental model of ultraviolet radia
63 mechanisms by which ultraviolet light causes photoaging involve activation of growth factor and cytok
64 y of photoaging and support the concept that photoaging is at least in part a process of damage-accel
74 umeric scales that include manifestations of photoaging other than rhytids, such as lentigines, hyper
76 s may contribute to the clinical features of photoaging, such as wrinkle formation and loss of elasti
77 te multiple pathways underlying the cause of photoaging suggests ERbeta to be a novel therapeutic tar
82 und to increase with aging and decrease with photoaging we investigated the characteristics of this d
83 mmunologic injury may play a role in chronic photoaging, we asked whether RA alters the acute photoim
84 arm of 16 subjects with a clinical range of photoaging were examined for fibrillin-1 and fibrillin-2
86 idation in vivo in mouse skin, a hallmark of photoaging, when analyzed biochemically, by immunoblotti
88 ultraviolet A radiation (UVA) contributes to photoaging, which results in the accumulation of massive
89 ngs can also be associated with a subtype of photoaging, which we term telangiectatic photoaging (TP)
90 his study did not demonstrate improvement in photoaging with a standard course of topical fluorouraci
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