Mechanism(s) of increased vascular cell adhesion on nanostructured poly(lactic-co-glycolic acid) films.
about
Surface modification of biomaterials: a quest for blood compatibilityNanotechnology in diagnosis and treatment of coronary artery disease.Electrospun poly(lactic acid-co-glycolic acid) scaffolds for skin tissue engineering.Fibronectin terminated multilayer films: protein adsorption and cell attachment studies.Nanomedicine for the reduction of the thrombogenicity of stent coatings.Nanoscale engineering of biomimetic surfaces: cues from the extracellular matrix.Biocompatibility and favorable response of mesenchymal stem cells on fibronectin-gold nanocomposites.Urokinase receptor counteracts vascular smooth muscle cell functional changes induced by surface topographySingle-walled carbon nanotubes promote rat vascular adventitial fibroblasts to transform into myofibroblasts by SM22-α expressionNanotechnology for cell-substrate interactions.Increased endothelial and vascular smooth muscle cell adhesion on nanostructured titanium and CoCrMoFibroblast response is enhanced by poly(L-lactic acid) nanotopography edge density and proximityBladder tissue engineering through nanotechnology.Using mathematical models to understand the effect of nanoscale roughness on protein adsorption for improving medical devicesDevelopment of cardiovascular bypass grafts: endothelialization and applications of nanotechnology.Urologic tissue engineering in pediatrics: from nanostructures to bladders.Novel nano-rough polymers for cartilage tissue engineering.Nanotechnology and its relationship to interventional radiology. Part II: Drug Delivery, Thermotherapy, and Vascular Intervention.Novel approach by nanobiomaterials in vascular tissue engineering.Nano-regenerative medicine towards clinical outcome of stem cell and tissue engineering in humans.Additive Manufacturing of Vascular Grafts and Vascularized Tissue Constructs.Surface-modified bacterial nanofibrillar PHB scaffolds for bladder tissue repair.Control of cell behavior by aligned micro/nanofibrous biomaterial scaffolds fabricated by spinneret-based tunable engineered parameters (STEP) technique.Submicron poly(L-lactic acid) pillars affect fibroblast adhesion and proliferation.Human mesenchymal stem cell adhesion and proliferation in response to ceramic chemistry and nanoscale topography.Preparation and cytocompatibility of PLGA scaffolds with controllable fiber morphology and diameter using electrospinning method.PLGA nanometer surface features manipulate fibronectin interactions for improved vascular cell adhesion.Select bladder smooth muscle cell functions were enhanced on three-dimensional, nano-structured poly(ether urethane) scaffolds.Adhesion of mesenchymal stem cells to polymer scaffolds occurs via distinct ECM ligands and controls their osteogenic differentiation.Fabrication of Multifaceted Micropatterned Surfaces with Laser Scanning Lithography.Effect of Silicon, Titanium, and Zirconium Ion Implantation on NiTi Biocompatibility
P2860
Q28728811-4FAD53E9-5B36-466D-BFE1-C7E0822F8001Q30362371-16515B9A-6D41-4250-9315-367C2FB09CF7Q30438271-C7C1CC5F-121B-40D7-A274-255CE30FE891Q30542661-04D19992-A61B-4BBD-9081-F18127E6CE1AQ33576893-2C02D38A-4E34-4BE3-882F-C412F790472DQ34613616-40C88CF5-070F-40C9-89FE-068165881CD4Q34795651-621F5EF3-7DFA-4683-AF33-5C63E62F3BC4Q34811842-BD62BBAF-EB9E-471E-8FDA-9276FE74F858Q36161017-71D3FAB4-75CC-44B7-99A5-63316B2D2EC0Q36416889-29E2B96F-B9C0-40E0-9D14-C21C97F237F3Q36717948-0EF55B17-BD00-437B-9C96-099336E5AF84Q37171098-C540365A-9F56-43CC-9415-CAF88F7C965BQ37184512-9011D652-91E9-4671-9ABF-94FDCE1ACDD8Q37214638-53DF001C-9B02-42CE-AC31-D2DF4A2D0DB5Q37304690-02C4955A-4D30-4F0B-B07A-E90F561C46C3Q37675833-1CA3139D-ACA6-42D0-8982-FD7447CB1474Q37721867-B1CCAF25-C34A-4420-A546-720D5035DE65Q37789181-F1BA071E-49F8-4AA5-9C9A-54088B27CF8EQ37795970-A6B36D81-EFC4-4E2E-A483-C851C1C65097Q37977128-8DCC343B-618D-410A-9835-233EB67EB75CQ38782144-6EC9C228-A178-4243-A037-D20E1293E2ADQ38991278-84837E20-E74D-4824-915B-8BA664DECA1FQ39957820-86DC2648-460F-4918-B5E1-135E35A96CF9Q40176223-2B855A34-11BE-45B0-81C2-D0B0C3D4D4F8Q47627195-4F42D1DF-05C6-4B8B-977A-E58B2B8A9CEEQ47798949-C4E7C2B3-0276-473F-BBE8-6934B1973417Q51091707-9A29E4DD-B5B3-4B3A-81CE-53A6A0321298Q51093027-80D21A66-956E-4B2C-A402-4D2A28F93DE6Q51230852-6C3BAFA6-49C5-4BEC-A631-DB66B8414039Q54963170-74790FA6-E6D1-45A7-BC26-C507006DEC27Q58699781-EE86196E-F951-4A7D-AC49-B564552703E3
P2860
Mechanism(s) of increased vascular cell adhesion on nanostructured poly(lactic-co-glycolic acid) films.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh-hant
name
Mechanism(s) of increased vasc ...... actic-co-glycolic acid) films.
@en
type
label
Mechanism(s) of increased vasc ...... actic-co-glycolic acid) films.
@en
prefLabel
Mechanism(s) of increased vasc ...... actic-co-glycolic acid) films.
@en
P2093
P356
P1476
Mechanism(s) of increased vasc ...... actic-co-glycolic acid) films.
@en
P2093
Derick C Miller
Karen M Haberstroh
Thomas J Webster
P304
P356
10.1002/JBM.A.30318
P577
2005-06-01T00:00:00Z