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1 the response to injury of a human bilayered skin substitute.
2 was observed with meshing of human bilayered skin substitute.
3 nfluence the subsequent functionality of the skin substitute.
4 required for hair development in engineered skin substitutes.
5 ts a massive influence on gene expression in skin substitutes.
6 eneic human cadaver skin grafts or synthetic skin substitutes.
7 an keratinocytes and fibroblasts in cultured skin substitutes.
8 ring healing of wounds treated with cultured skin substitutes.
9 rated adipose-derived mesenchymal cells into skin substitutes and found that adipose-derived mesenchy
12 ry support, the early excision of burns, and skin substitutes are improving survival from massive bur
16 were similar to the insulin-treated cultured skin substitutes at day 14, but by day 28 had deteriorat
17 lues similar to the insulin-treated cultured skin substitutes at day 14, but were significantly lower
18 s a promising alternative method to generate skin substitutes because it can replicate the structural
20 ut because they contain only two cell types, skin substitutes cannot replace all of the functions of
21 s or Langerhans cells present in StrataGraft skin substitute compared to cadaver allograft, the stand
22 howed that the epidermal and dermal cultured skin substitute components express insulin-like growth f
26 pacitance (SEC) of the epidermis in cultured skin substitutes (CSS) in vitro and after grafting to at
29 ised concerns about the costs to Medicare of skin substitutes, documenting pervasive fraudulent billi
30 igmented and prevascularized dermo-epidermal skin substitute (EarSkin) tested in immunocompromised ra
31 like growth factor I exhibited poor cultured skin substitute epidermal morphology throughout the expe
32 enitors can be utilized to vascularize human skin substitutes even in the setting of compromised host
36 xternal hairs and sebaceous glands, chimeric skin substitutes formed pigmented hairs without sebaceou
38 d epidermal compartments, chimeric composite skin substitutes generated using up to 90% GFP-labeled N
40 y agreed with MTT data showing that cultured skin substitutes grown with insulin media had multiple l
41 Generation of skin appendages in engineered skin substitutes has been limited by lack of trichogenic
43 ts for excised, full-thickness burns, but no skin substitutes have the anatomy and physiology of nati
45 results suggest that incubation of cultured skin substitutes in medium containing vitamin C extends
46 The data show that incubation of cultured skin substitutes in medium containing vitamin C results
47 in human skin cultured ex vivo and in human skin substitutes in vitro were substantially diminished
49 owed significantly higher values in cultured skin substitutes incubated with insulin at incubation da
51 by keratinocytes and fibroblasts in cultured skin substitutes is not sufficient to fully replace the
52 d skin substitute, as a prototypic bilayered skin substitute, is a truly dynamic living tissue, capab
56 Chimeric autologous/allogeneic bioengineered skin substitutes offer an innovative regenerative medici
57 ts greater physiologic stability in cultured skin substitutes over time, and that expression of insul
60 Improved anatomy and physiology of cultured skin substitutes that result from nutritional factors in
61 would produce a fully stratified engineered skin substitute tissue and serve to deliver autologous k
62 for the formation of bioengineered chimeric skin substitute tissues, providing immediate formal woun
63 red keratinocytes, cultured fibroblasts, and skin substitutes using Affymetrix gene chip microarrays.
65 y 12 h, however, the wounded human bilayered skin substitute was healed by day 3, and a stratum corne
70 limitation of hair regeneration, engineered skin substitutes were prepared with chimeric populations