Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
about
Self-assembling amphiphilic peptidesTherapeutic angiogenesis: controlled delivery of angiogenic factors.Highly angiogenic peptide nanofibersRational design of fiber forming supramolecular structuresNew Bioengineering Breakthroughs and Enabling Tools in Regenerative MedicineStimuli-responsive nanomaterials for biomedical applicationsTuning supramolecular mechanics to guide neuron developmentGd(III)-labeled peptide nanofibers for reporting on biomaterial localization in vivo(19)F Magnetic Resonance Imaging Signals from Peptide Amphiphile Nanostructures Are Strongly Affected by Their ShapeSynthesis and patterning of tunable multiscale materials with engineered cells.Enhanced potency of cell-based therapy for ischemic tissue repair using an injectable bioactive epitope presenting nanofiber support matrixConcise review: injectable biomaterials for the treatment of myocardial infarction and peripheral artery disease: translational challenges and progress.Esterase-activated release of naproxen from supramolecular nanofibres.Gel scaffolds of BMP-2-binding peptide amphiphile nanofibers for spinal arthrodesisThe promotion of functional urinary bladder regeneration using anti-inflammatory nanofibersCapillary Network-Like Organization of Endothelial Cells in PEGDA Scaffolds Encoded with Angiogenic Signals via Triple Helical Hybridization.Supramolecular assembly of multifunctional maspin-mimetic nanostructures as a potent peptide-based angiogenesis inhibitor.Bioactive DNA-peptide nanotubes enhance the differentiation of neural stem cells into neurons.Epitope topography controls bioactivity in supramolecular nanofibersPeptide amphiphile micelles self-adjuvant group A streptococcal vaccinationThe powerful functions of peptide-based bioactive matrices for regenerative medicine.Fabrication and characterization of injectable hydrogels derived from decellularized skeletal and cardiac muscle.Self-assembling peptide scaffolds for regenerative medicineThe role of nanoscale architecture in supramolecular templating of biomimetic hydroxyapatite mineralization.VEGF-loaded graphene oxide as theranostics for multi-modality imaging-monitored targeting therapeutic angiogenesis of ischemic muscle.Coassembled cytotoxic and pegylated peptide amphiphiles form filamentous nanostructures with potent antitumor activity in models of breast cancer.Nanostructure-templated control of drug release from peptide amphiphile nanofiber gelsAdvances in cryogenic transmission electron microscopy for the characterization of dynamic self-assembling nanostructures.Injectable skeletal muscle matrix hydrogel promotes neovascularization and muscle cell infiltration in a hindlimb ischemia modelPhotodynamic control of bioactivity in a nanofiber matrix.Controlled Angiogenesis in Peptide Nanofiber Composite HydrogelsSelf-Assembly for the Synthesis of Functional BiomaterialsTuning nanostructure dimensions with supramolecular twisting.A perspective on the clinical translation of scaffolds for tissue engineeringBiopolymers and supramolecular polymers as biomaterials for biomedical applications.Energy landscapes and functions of supramolecular systemsNucleation and Growth of Ordered Arrays of Silver Nanoparticles on Peptide Nanofibers: Hybrid Nanostructures with Antimicrobial Properties.Building stem cell niches from the molecule up through engineered peptide materialsSupramolecular Nanofibers Enhance Growth Factor Signaling by Increasing Lipid Raft Mobility.Supramolecular Nanofibers of Peptide Amphiphiles for Medicine.
P2860
Q26860199-48C53A68-57A0-4142-BA82-26AB9E297393Q27023731-F2EB930E-CC2D-47CA-A8FD-77BC8CE89158Q27334887-2D0B4E03-2F52-4493-A372-5943E424BFEEQ28829633-331C584A-09CD-4250-B4E8-F2C908D0BFCEQ30354756-18ADAED8-E5F1-47C3-A7C1-DD28AB7D0CDEQ30396768-74C11B23-986A-495E-A30C-3442BB992440Q30539179-96584660-DB14-4621-A456-1E26D4ECFAEBQ30831724-D0585DC9-61A4-4B81-9E47-C0D8EA486D99Q31115271-48A01C16-AA98-4C6E-820C-E055EB841AFAQ33777722-906839B2-3A9E-4A58-8498-9BCD27844509Q34055868-FEBCCE9F-1164-4B74-9E12-B292EE8D0761Q34109419-41F315BB-DBC4-48E6-9DC6-46DA82985E98Q34362010-86C557BF-693C-4873-9AEC-5672F4B5FFAFQ34389497-837D7A28-CE35-4489-A76A-21AA4A957A2EQ34722403-ACBFDE46-D19F-4BEC-A068-947CC52A6E37Q34756553-530F3264-13DB-434C-9A2A-77CB313DF9B6Q34758649-BD8B4BB7-0210-4BC3-AC10-8FD9FECF1E31Q34977505-D7A0A2BE-F91F-4E67-9D14-9F1C8E8EC90AQ35136268-42E5C3C9-242A-4FDA-BE68-C0CE6D6D4AE4Q35192883-D732B8EC-F88E-4B14-98A0-F3F91A18FC91Q35235519-EE90AB4C-49B8-43D1-A173-5BCBDDB25C7DQ35920945-C51E64D8-01D5-4CED-824A-CAA2EE8AC3BEQ35968451-8758DB8C-2AD4-4B10-B246-B51DEB650CF4Q36104420-4F6021F5-3F81-4ECA-B71E-4E34AE6C9AA0Q36165427-E7BC753D-20A5-4A94-93A0-F93A145119D4Q36279390-A4A37250-AAAC-4D2C-83A6-02880DF9FC82Q36366440-0772128B-DFB5-4FEE-8D2D-36E71211FE9CQ36433733-1ACB9242-6606-4F13-BFE8-3EB451C5B048Q36472391-01CACFF2-5168-4818-81DC-1F2CDA421975Q36484516-69E492EE-B609-4BC5-A8A9-C6A58E0633ABQ36623213-8BF93A93-4990-4C88-B6E8-3DEE72923524Q36634365-55610D3D-D0FD-484E-BE0B-CE001B1148C7Q36652231-7D450476-18FA-4565-8096-CE5D21971868Q36671386-B37CC661-0F3C-4E6E-AC70-CB37F86A3C9FQ36683929-EF68E7BF-C164-4EE5-A899-A0D2E02A657EQ36723103-10B6B0ED-3DA9-45A5-8196-B5AD4FCC6413Q36877342-C86BCBE9-9C97-428E-87ED-146FC29DFDF1Q36950990-CF591E83-BD88-4F9B-8D7C-BEBA8071E641Q37104025-000E4889-11BD-430C-A0EA-8B9F47614349Q37579963-EF5F380F-67DB-4D1C-8EC1-505EF4516976
P2860
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
description
2011 nî lūn-bûn
@nan
2011 թուականի Օգոստոսին հրատարակուած գիտական յօդուած
@hyw
2011 թվականի օգոստոսին հրատարակված գիտական հոդված
@hy
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
name
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@ast
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@en
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@nl
type
label
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@ast
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@en
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@nl
prefLabel
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@ast
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@en
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@nl
P2093
P2860
P356
P1476
Supramolecular nanostructures that mimic VEGF as a strategy for ischemic tissue repair
@en
P2093
Christina J Newcomb
Douglas W Losordo
Johann Bauersachs
Jörn Tongers
Katja-Theres Marquardt
Matthew J Webber
P2860
P304
13438-13443
P356
10.1073/PNAS.1016546108
P407
P577
2011-08-01T00:00:00Z