Using poly(lactide-co-glycolide) electrospun scaffolds to deliver cultured epithelial cells to the cornea.
about
Limbal Stem Cell Deficiency: Current Treatment Options and Emerging TherapiesPre-Clinical Cell-Based Therapy for Limbal Stem Cell DeficiencyTowards the use of hydrogels in the treatment of limbal stem cell deficiencyHuman anterior lens capsule serving as a substrate for human trabecular meshwork cells cultivation.Monitoring fibrous scaffold guidance of three-dimensional collagen organisation using minimally-invasive second harmonic generation.Application of adipose-derived stem cells on scleral contact lens carrier in an animal model of severe acute alkaline burn.Synthetic vs natural scaffolds for human limbal stem cells.Corneal Stroma Regeneration with Acellular Corneal Stroma Sheets and Keratocytes in a Rabbit Model.Optimization of optical and mechanical properties of real architecture for 3-dimensional tissue equivalents: Towards treatment of limbal epithelial stem cell deficiency.Human corneal stromal stem cells exhibit survival capacity following isolation from stored organ-culture corneas.An Ultra-thin Amniotic Membrane as Carrier in Corneal Epithelium Tissue-Engineering.Artificial Polymeric Scaffolds as Extracellular Matrix Substitutes for Autologous Conjunctival Goblet Cell Expansion.Scaffolds and stem cells: delivery of cell transplants for retinal degenerationsReview of alternative carrier materials for ocular surface reconstruction.Electrospun Scaffolds for Corneal Tissue Engineering: A ReviewGelatin-Based Materials in Ocular Tissue Engineering.Enhanced viability of corneal epithelial cells for efficient transport/storage using a structurally modified calcium alginate hydrogel.Combination of microstereolithography and electrospinning to produce membranes equipped with niches for corneal regeneration.Electro-spun Membranes as Scaffolds for Human Corneal Endothelial Cells.[New biomaterials and alternative stem cell sources for the reconstruction of the limbal stem cell niche].Frontal Cryosectioning: An Improved Protocol for Sectioning Large Areas of Fibrous Scaffolds
P2860
Q26770834-AD317DBA-FEB3-4ECB-B96E-89602821EF3FQ26783564-192742B4-FF8E-4CD0-8664-E06DB6E5E14EQ27010179-B1FFFC87-6A07-409B-9E5C-59C4B74C1A7AQ34353452-DBF41F23-2864-4492-A8D4-CBD72040A229Q35108040-7C081EE0-923C-46CF-809F-BA738CFA3EBFQ35195075-3EC4638F-6E17-42BF-B758-172B56B3FC18Q35668002-69621B32-3A65-4B08-8FB0-57A25A4FF7C2Q35689451-9FFA468E-18CF-4E84-98B3-91F0B7D35B6BQ35998218-FEF2E417-9A58-4E1F-9EC8-041E336F26D8Q36072935-2A38B72F-9CB1-44B7-82F1-844E0BFDEBE2Q36579612-81516068-ACCE-4A20-8A62-960DCB3DAB74Q37407579-F8AE709B-B7B9-4B11-95B1-B5D48113FBFEQ38098988-7E4D0754-0B75-4D82-B825-5B52217D7CD6Q38176949-A96FDD63-1798-4D99-BF72-185DA5CA2E60Q38647321-4EB1DBDD-774C-492E-9E10-D719BE038DF9Q39209355-BA94FA95-5BAD-4D22-9300-0362D0FB7B22Q39346835-5462D59F-29D6-4926-8BDD-2A0061A2DAC4Q40045371-E302A1BF-CE2D-46F0-AB13-B21B3B32CE1BQ47215938-EE6D6A5B-C9FD-4523-AEAE-EC281D51FF28Q52883849-BECE4E69-5C14-4244-BA5A-100023D98CBAQ59113366-DA2142E4-642D-4DA1-9E37-02D481102AEF
P2860
Using poly(lactide-co-glycolide) electrospun scaffolds to deliver cultured epithelial cells to the cornea.
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
2010年學術文章
@zh-hant
name
Using poly(lactide-co-glycolid ...... pithelial cells to the cornea.
@en
type
label
Using poly(lactide-co-glycolid ...... pithelial cells to the cornea.
@en
prefLabel
Using poly(lactide-co-glycolid ...... pithelial cells to the cornea.
@en
P2093
P2860
P356
P1476
Using poly(lactide-co-glycolid ...... pithelial cells to the cornea.
@en
P2093
Adekemi Ogunbanjo
Keith A Blackwood
Richard A Senior
Rob McKean
Sheila MacNeil
P2860
P304
P356
10.2217/RME.10.16
P577
2010-05-01T00:00:00Z