about
Capture of endothelial cells under flow using immobilized vascular endothelial growth factorBiocompatible and bioactive surface modifications for prolonged in vivo efficacyBioengineering and the cardiovascular systemSmooth muscle and other cell sources for human blood vessel engineeringEpithelial machines of morphogenesis and their potential application in organ assembly and tissue engineeringTissue engineering: from research to dental clinicsEndothelial cells derived from nuclear reprogrammingScaffolds in vascular regeneration: current statusThe role of mechanotransduction on vascular smooth muscle myocytes' [corrected] cytoskeleton and contractile functionStem cell sources for vascular tissue engineering and regenerationA cautionary tale for autologous vascular tissue engineering: impact of human demographics on the ability of adipose-derived mesenchymal stem cells to recruit and differentiate into smooth muscle cells.Dynamic, nondestructive imaging of a bioengineered vascular graft endotheliumHuman Vascular Microphysiological System for in vitro Drug Screening.Uniaxial mechanical strain modulates the differentiation of neural crest stem cells into smooth muscle lineage on micropatterned surfacesSuccessful development of small diameter tissue-engineering vascular vessels by our novel integrally designed pulsatile perfusion-based bioreactorThe Tissue-Engineered Vascular Graft-Past, Present, and Future.Harnessing systems biology approaches to engineer functional microvascular networksQCM-D sensitivity to protein adsorption reversibility.Engineering stem cell niches in bioreactors.A bilayered elastomeric scaffold for tissue engineering of small diameter vascular grafts.A novel cylindrical biaxial computer-controlled bioreactor and biomechanical testing device for vascular tissue engineering.Current advances in research and clinical applications of PLGA-based nanotechnology.Engineered microenvironments for controlled stem cell differentiation.Biohybrid thin films for measuring contractility in engineered cardiovascular muscle.Geometrically controlled endothelial tubulogenesis in micropatterned gels.Poly(ε-caprolactone)-based copolymers bearing pendant cyclic ketals and reactive acrylates for the fabrication of photocrosslinked elastomersThe use of optical clearing and multiphoton microscopy for investigation of three-dimensional tissue-engineered constructs.A Novel Bioreactor System for the Assessment of Endothelialization on Deformable Surfaces.Arterial graft with elastic layer structure grown from cellsDynamics of extracellular matrix production and turnover in tissue engineered cardiovascular structures.Utility of telomerase-pot1 fusion protein in vascular tissue engineering.Vascular tissue engineering by computer-aided laser micromachining.Construction of tissue-engineered small-diameter vascular grafts in fibrin scaffolds in 30 daysGeometry and force control of cell function.A biocompatible endothelial cell delivery system for in vitro tissue engineering.Hemodynamics and axial strain additively increase matrix remodeling and MMP-9, but not MMP-2, expression in arteries engineered by directed remodeling.Physiologic compliance in engineered small-diameter arterial constructs based on an elastomeric substrate.Vascularization strategies for tissue engineering.Functional small-diameter neovessels created using endothelial progenitor cells expanded ex vivo.Biomaterials for vascular tissue engineering
P2860
Q26782026-6C207FCB-36D1-4F49-8A33-7C5434F07587Q26823128-A51E5EE4-E7B3-48A4-BA62-B6FF10C3EF4FQ26827097-4935E1F7-9D7C-464C-9BE0-F163F876B028Q26862581-BA492880-5465-40FC-B9AB-BEB6502D75BEQ26863220-014593DC-BDE7-42F5-A5BD-363A2E15646CQ27010086-20B17D90-4517-4DE6-AD6E-5356676F46ACQ27011837-6C1B1B3F-5E77-4CC8-9846-0C8A3C6D3BBDQ27012628-1E726517-7C12-42D5-B819-7ACE66E1FD0BQ27026682-263E5FEF-2DFC-4CA4-AAE6-0CBA4F414F54Q27028106-2EDE9082-C20D-4730-9781-F5A3340A6463Q27306934-3A254453-ACA3-45F3-98B3-250CF601D42CQ27325395-1FD52A80-4E6B-46BB-8EA2-A0155662C1AEQ27346581-DCC276F0-C4AE-467C-A124-C9F5726A6DA5Q28477413-F9944FDE-EE7B-49F2-A960-DC4E51E33D35Q28482085-AB266E69-B31A-43BE-81BB-D50954255CCDQ30385854-3C9EFFC8-F213-4A61-982C-EAEC611166E2Q30432197-3088DCAF-DF07-4F24-B8A0-9306B76FBF3AQ30446525-D60B4783-AD34-4A60-B6DE-047E9C7B887AQ30447912-56AFEC7E-5439-4BC8-A1B6-463E092F0DD1Q30473600-53D22464-1302-43AA-ADDA-AA4F5AEB7A8DQ30478997-82925ABA-BC99-4534-8EBD-555EEF9D9A8CQ30482916-6F1E5F84-AFAA-4D87-BA69-7E395601674FQ30488054-E9BDE983-56DD-49C4-AF73-B52712806021Q30493650-0C066C7E-ED1D-4244-A695-61571366A888Q30496819-21208B4D-034C-4A61-8047-190BE8962E85Q30542093-2672D45B-5FE7-433F-923F-4C0B32700B7BQ30581964-C98C5D34-FC94-4B90-981F-43714E0CE194Q30831562-113BA6DB-C9BD-4AF1-8C66-2336B5B81A0FQ30849415-80405A7F-7025-4F3C-B845-240CA25CCE0BQ32162656-C1DAB0FC-B267-444B-9020-E106D7362F7BQ33514152-D8CCCB39-1BE9-4FA3-9B2E-BE62E957E1F6Q33544089-8B0C31E1-59FA-4CC1-BF2A-D47FAD364B97Q33571735-1158516C-01A3-4AA5-8A01-9DB400795B38Q33579752-47E3DC52-123E-4A1C-BE93-B31F6A146814Q33590528-DEB50D90-1B81-45D4-844F-0EB0EB47DD4BQ33606446-23BC9012-63B0-4C64-B3DA-F883563293F3Q33620849-694356E0-8D1B-456B-8FFA-ED2173DBD318Q33634565-A79BE15C-B7D5-4916-BE93-58124DB492F5Q33640562-E8BFB9F8-A608-4A58-A9BB-1F7F0F8C67FDQ33655808-2B2E1D4A-1168-4D6C-BF36-1CD7A00462BD
P2860
description
1999 nî lūn-bûn
@nan
1999 թուականի Ապրիլին հրատարակուած գիտական յօդուած
@hyw
1999 թվականի ապրիլին հրատարակված գիտական հոդված
@hy
1999年の論文
@ja
1999年論文
@yue
1999年論文
@zh-hant
1999年論文
@zh-hk
1999年論文
@zh-mo
1999年論文
@zh-tw
1999年论文
@wuu
name
Functional arteries grown in vitro.
@ast
Functional arteries grown in vitro.
@en
type
label
Functional arteries grown in vitro.
@ast
Functional arteries grown in vitro.
@en
prefLabel
Functional arteries grown in vitro.
@ast
Functional arteries grown in vitro.
@en
P2093
P1433
P1476
Functional arteries grown in vitro.
@en
P2093
Hirschi KK
Niklason LE
P304
P356
10.1126/SCIENCE.284.5413.489
P407
P577
1999-04-01T00:00:00Z