Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
about
Active scaffolds for on-demand drug and cell delivery.Surface topography induces 3D self-orientation of cells and extracellular matrix resulting in improved tissue function.Cell therapy in dermatology.Making more matrix: enhancing the deposition of dermal-epidermal junction components in vitro and accelerating organotypic skin culture development, using macromolecular crowding.Combination of stromal cell-derived factor-1 and collagen-glycosaminoglycan scaffold delays contraction and accelerates reepithelialization of dermal wounds in wild-type miceTissue engineering: current strategies and future directionsHow biophysical in vivo testing techniques can be used to characterize full thickness skin equivalents.Nanomaterials can dynamically steer cell responses to biological ligands.MALDI-MSI for the analysis of a 3D tissue-engineered psoriatic skin modelBiological skin substitutes for wound cover and closure.Tissue engineering of replacement skin: the crossroads of biomaterials, wound healing, embryonic development, stem cells and regenerationSilk: a potential medium for tissue engineering.Improved Methods to Produce Tissue-Engineered Skin Substitutes Suitable for the Permanent Closure of Full-Thickness Skin Injuries.New era in health care: tissue engineering.Macromolecular crowding amplifies adipogenesis of human bone marrow-derived mesenchymal stem cells by enhancing the pro-adipogenic microenvironment.Emerging translational research on magnetic nanoparticles for regenerative medicine.A pathologist's perspective on induced pluripotent stem cells.Collagen matrix deposition is dramatically enhanced in vitro when crowded with charged macromolecules: the biological relevance of the excluded volume effect.Atopic Dermatitis Studies through In Vitro Models.Heparanase Inhibitors Facilitate the Assembly of the Basement Membrane in Artificial SkinA novel multiparameter in vitro model of three-dimensional cell ingress into scaffolds for dermal reconstruction to predict in vivo outcomeFabrication of cultured oral gingiva by tissue engineering techniques without materials of animal origin.Characterization of chitosan-gelatin scaffolds for dermal tissue engineering.Characterization of the structure of human skin substitutes by infrared microspectroscopy.IFATS collection: Using human adipose-derived stem/stromal cells for the production of new skin substitutes.Tissue-Engineered Tubular Heart Valves Combining a Novel Precontraction Phase with the Self-Assembly Method.Human Skin 3D Bioprinting Using Scaffold-Free Approach.Improving 2D and 3D Skin In Vitro Models Using Macromolecular Crowding.Tissue engineering of urinary bladder and urethra: advances from bench to patients.Towards an in vitro fibrogenesis model of human vocal fold scarring.Inexpensive production of near-native engineered stromas.In vivo evaluation of wound bed reaction and graft performance after cold skin graft storage: new targets for skin tissue engineering.Compressed Collagen Enhances Stem Cell Therapy for Corneal Scarring.Construction of 3D biological matrices using rapid prototyping technology
P2860
Q30497842-50A53DFA-50F5-4E9D-9283-FF9DD98F5131Q30656269-9006960D-17DE-4E2C-9C7C-B52350CE0321Q33653689-58AB66BC-5192-4367-A78C-719BCDB338DEQ34942129-EB99D1BB-B6A7-486B-9D96-0E8F580943BAQ35197435-537D9E51-D735-4936-8FA6-65F718132890Q35546159-586F8B33-C4B6-41F4-BC3A-A4CA34E17233Q35823814-727D41DD-FC17-47B0-8941-C2E73239A982Q35910753-BC3CC4DE-DC16-4B06-A598-75F8FB5A2A14Q36029835-276C0014-8F73-46E2-8FE5-89226355B123Q36471560-BE5EDF1B-F57F-4F2A-AD9C-FF575A64D345Q36717650-F2D03C33-74D4-4CD5-88F9-3ADB05F3F73FQ37322081-1CA4F895-F697-408B-B446-F08AB185759EQ37424866-B5153AD6-679E-4826-BA78-7807D741520DQ37535972-80A276D3-D493-49D8-ABAE-239132D0A9D0Q37610663-552A52B0-E6AB-4C05-BB61-2C8EC212125CQ38617021-A456BED8-99C2-4ADD-92E8-51711BB5BB73Q38649378-52F6A7C7-56C4-4F89-992D-AA4B57CB0A84Q40127292-A738E45F-D15F-447C-BD7E-3743D0AA811BQ41101918-E7803D77-6302-4EEE-8957-A81C93DF5BC4Q41504553-4BC364A2-595F-4677-9D8A-5FD854845E8FQ42155829-8F9FC268-C609-440D-A198-B7B30540892AQ43877535-9DA25B47-C9B4-471F-921A-6A28975DB980Q45132264-B111E10F-24F4-478A-A4CE-402DE40F6084Q46723966-111C78D5-F23D-4AF4-93CC-781F0B88B4CCQ47582559-C9E39797-A77A-47FA-8CB6-ED6F67C61FF8Q48118562-1C308E32-B356-4B38-86B0-9B6145F85DACQ51079289-369DFFD2-6355-45D0-AF08-56602B6FF177Q51176024-2FD03DF0-7AC9-4F8A-9ED0-891B9B127628Q51757076-76A28F10-AB42-407A-8102-B096591B3CC7Q52665494-9EADF72B-7C82-4751-B6F7-C19D2E68F7B7Q53492566-C8AD6F33-17CA-4FA0-9485-0C308BCA9F2BQ53659993-30A91FA0-E838-4516-A9BE-F5DA77A86B31Q55005465-6CA01D95-28B1-45B0-BC97-9B4283656348Q57765707-3B3B36C1-0893-4634-84BE-18F5681B6485
P2860
Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
2004年论文
@zh
2004年论文
@zh-cn
name
Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
@ast
Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
@en
type
label
Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
@ast
Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
@en
prefLabel
Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
@ast
Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
@en
P2093
P356
P1476
Tissue-engineered skin substitutes: from in vitro constructs to in vivo applications.
@en
P2093
François A Auger
François Berthod
Lucie Germain
Roxane Pouliot
Véronique Moulin
P304
P356
10.1042/BA20030229
P577
2004-06-01T00:00:00Z