about
Cell Culture, Technology: Enhancing the Culture of Diagnosing Human DiseasesRecent advances of biomaterials in biotherapyHydrogels for Engineering of Perfusable Vascular NetworksAdult Stem Cell Responses to NanostimuliElectrical stimulation as a biomimicry tool for regulating muscle cell behaviorMicroporous membrane-based liver tissue engineering for the reconstruction of three-dimensional functional liver tissues in vitroCell origami: self-folding of three-dimensional cell-laden microstructures driven by cell traction forceMultiscale tissue engineering for liver reconstructionNanocomposite hydrogels for biomedical applicationsAdvancing Tissue Engineering: A Tale of Nano-, Micro-, and Macroscale Integration.Spatial patterning of endothelial cells and vascular network formation using ultrasound standing wave fields.Vascularization of three-dimensional collagen hydrogels using ultrasound standing wave fieldsControlling the spatial organization of cells and extracellular matrix proteins in engineered tissues using ultrasound standing wave fields.Exploitation of physical and chemical constraints for three-dimensional microtissue construction in microfluidics.Sequential assembly of cell-laden hydrogel constructs to engineer vascular-like microchannels.Highly elastomeric poly(glycerol sebacate)-co-poly(ethylene glycol) amphiphilic block copolymers.Cell-adhesive and mechanically tunable glucose-based biodegradable hydrogelsInterface-directed self-assembly of cell-laden microgels.Amphiphilic beads as depots for sustained drug release integrated into fibrillar scaffolds.Cell-laden microengineered gelatin methacrylate hydrogels.Directed 3D cell alignment and elongation in microengineered hydrogels.3D Bioprinting for Tissue and Organ Fabrication.Nanoclay-enriched poly(ɛ-caprolactone) electrospun scaffolds for osteogenic differentiation of human mesenchymal stem cells.Injectable graphene oxide/hydrogel-based angiogenic gene delivery system for vasculogenesis and cardiac repair.Nanotechnology in drug delivery and tissue engineering: from discovery to applicationsBiomimetic poly(ethylene glycol)-based hydrogels as scaffolds for inducing endothelial adhesion and capillary-like network formation.Hybrid PGS-PCL microfibrous scaffolds with improved mechanical and biological properties.Potential therapeutic applications of muscle-derived mesenchymal stem and progenitor cells.Electrospun nanofibers for regenerative medicine.Directed assembly of cell-laden hydrogels for engineering functional tissues.Cell-laden microengineered pullulan methacrylate hydrogels promote cell proliferation and 3D cluster formation.Synthesis and characterization of photocrosslinkable gelatin and silk fibroin interpenetrating polymer network hydrogels.Synthesis and characterization of tunable poly(ethylene glycol): gelatin methacrylate composite hydrogelsEndothelial progenitor cells promote directional three-dimensional endothelial network formation by secreting vascular endothelial growth factor.Microscale technologies and modular approaches for tissue engineering: moving toward the fabrication of complex functional structures.Monitoring fibrous scaffold guidance of three-dimensional collagen organisation using minimally-invasive second harmonic generation.Chemistry and material science at the cell surface.Controlling the fibroblastic differentiation of mesenchymal stem cells via the combination of fibrous scaffolds and connective tissue growth factor.Hyaluronic Acid-Based Hydrogels: from a Natural Polysaccharide to Complex NetworksThe integration of 3-D cell printing and mesoscopic fluorescence molecular tomography of vascular constructs within thick hydrogel scaffolds
P2860
Q26748487-1E6367B1-DF86-4678-8808-A94822423E2DQ26752054-AA46DF56-273D-453D-8073-70EDC2361939Q26799978-BD8ADECA-0E40-4A00-8EB6-64298B1DBE28Q26801738-70830A08-154F-4E1E-B624-98C0DFD4276AQ26826818-27AA1347-EE80-4255-B7CC-0E652CF7BC47Q26996192-E73EF0CD-72B2-4DAA-A4A8-33F28BB351D9Q27332348-25EAC505-BB51-4A70-8429-C8B24A7B897EQ27687128-B685983D-73A9-4521-9C9A-EB1233439D23Q28302499-B2EAFAAF-1D82-485E-A021-61E32CF4D7CDQ30358039-40713D0B-42C5-454A-AA73-ED48187E7C59Q30433706-B5DA6DCC-794C-4355-B764-C923309875E2Q30462019-AA49F663-082A-41C9-87BE-D57180D64B7BQ30473380-1BC14D21-9107-4251-838D-1B1F8E79A92AQ30474710-22F19C3A-CD62-45BC-8922-7901B9DA9E23Q30500331-6BD75D81-C9B0-4BB9-8A26-2E5FAAC6CCE4Q30596389-A5661130-C972-4F2B-8D86-A29BC8A02A52Q33637078-F07A8510-5E20-4BB8-A285-2511B0EF6B8AQ33805078-DEFEFC58-4F46-4C01-B6CE-D98B7B6DB25CQ33838612-FBB51F3B-7B86-4C2C-B572-F27ED61E6ABCQ33885553-C3EE37FF-FD69-4FFD-9B77-FA7DDC3C6FE8Q34015673-DD48E648-008B-488B-B3B6-555C56F0D117Q34046716-08E807FC-2239-4816-919C-4E2184928522Q34063639-C11D4E1B-E8AB-4368-B703-23F4B59ABB18Q34104323-DCFB5E38-2C01-4B89-866A-EBE45DA142B2Q34112647-60013529-5C2E-46F2-BC3F-B96239790A31Q34148059-9573C083-9055-462D-BD95-D54FAD69643CQ34274170-6CE0CABE-571F-4467-B800-0EB9C29E0E1DQ34479398-7581DEB0-4DAB-4D9F-AA07-B5D7702B957BQ34660947-A7810FE5-C6BF-4A4A-815C-E0FAC83E1F5BQ34661715-269FB1A4-BDD4-4ECA-A696-73E5BAF344F1Q34670073-E54C3371-5DC6-4F4E-BB39-D70BC0726157Q34901176-A428CBE7-1FBF-4F2F-AE15-FC9DF7C2F9E9Q35055861-E8C90F26-CBEE-464E-B0A5-C9F15BA57653Q35061453-DB11CF9A-DFDC-4510-A21F-1774D3B3D374Q35094563-30EB2486-BBA1-4AFC-8762-FB8C20716407Q35108040-A530B6A6-FD2A-4796-8637-86BEC2444359Q35170330-91FF93FC-6F59-4073-B15F-64F3D12C5A83Q35476838-CFAA0535-E0C2-4FDD-AF70-7D3035D8DF48Q35820730-61257852-554A-4803-A19B-D580ED75C659Q35973442-849C9442-4438-48BD-9332-307521601114
P2860
description
2009 nî lūn-bûn
@nan
2009年の論文
@ja
2009年学术文章
@wuu
2009年学术文章
@zh-cn
2009年学术文章
@zh-hans
2009年学术文章
@zh-my
2009年学术文章
@zh-sg
2009年學術文章
@yue
2009年學術文章
@zh
2009年學術文章
@zh-hant
name
Progress in tissue engineering.
@en
Progress in tissue engineering.
@nl
type
label
Progress in tissue engineering.
@en
Progress in tissue engineering.
@nl
prefLabel
Progress in tissue engineering.
@en
Progress in tissue engineering.
@nl
P2093
P1433
P1476
Progress in tissue engineering.
@en
P2093
Ali Khademhosseini
Joseph P Vacanti
Robert Langer
P577
2009-05-01T00:00:00Z