Targeting pancreatic islets with phage display assisted by laser pressure catapult microdissection.
about
Targeting the Eph System with Peptides and Peptide ConjugatesCrystal Structure and NMR Binding Reveal That Two Small Molecule Antagonists Target the High Affinity Ephrin-binding Channel of the EphA4 ReceptorCombinatorial peptide libraries: mining for cell-binding peptides.Identification of clinically significant tumor antigens by selecting phage antibody library on tumor cells in situ using laser capture microdissection.Display technologies: application for the discovery of drug and gene delivery agents.Screening and identification of a targeting peptide to hepatocarcinoma from a phage display peptide library.Procuration and identification of bacteria in paraffin-embedded liver tissues of hepatocellular carcinoma by laser-assisted microdissection technique.IFATS collection: Combinatorial peptides identify alpha5beta1 integrin as a receptor for the matricellular protein SPARC on adipose stromal cells.Targeted induction of lung endothelial cell apoptosis causes emphysema-like changes in the mouse.Mouse thymus targeted peptide isolated by in vivo phage display can inhibit bioactivity of thymus output in vivo.Phage-display selection on tumor histological specimens with laser capture microdissection.Combinatorial ligand-directed lung targeting.Potential of phage-displayed peptide library technology to identify functional targeting peptidesPhage display in molecular imaging and diagnosis of cancer.In vitro phage display in a rat beta cell line: a simple approach for the generation of a single-chain antibody targeting a novel beta cell-specific epitope.Ephrin-B3 supports glioblastoma growth by inhibiting apoptosis induced by the dependence receptor EphA4Identification of a cardiac specific protein transduction domain by in vivo biopanning using a M13 phage peptide display library in miceBioreducible polymers for therapeutic gene deliveryIn vivo phage display selection of an ovarian cancer targeting peptide for SPECT/CT imaging.By-passing large screening experiments using sequencing as a tool to identify scFv fragments targeting atherosclerotic lesions in a novel in vivo phage display selection.Selection and identification of ligand peptides targeting a model of castrate-resistant osteogenic prostate cancer and their receptors.A disalicylic acid-furanyl derivative inhibits ephrin binding to a subset of Eph receptorsSelection of cell-type specific antibodies on tissue-sections using phage displaySelection strategies for anticancer antibody discovery: searching off the beaten path.Ligand-targeted theranostic nanomedicines against cancerPolymeric delivery of therapeutic RAE-1 plasmid to the pancreatic islets for the prevention of type 1 diabetes.A novel excision selection method for isolation of antibodies binding antigens expressed specifically by rare cells in tissue sectionsAAVP displaying octreotide for ligand-directed therapeutic transgene delivery in neuroendocrine tumors of the pancreas.Noninvasive imaging of islet transplantation and rejection.The Use of Phage-Displayed Peptide Libraries to Develop Tumor-Targeting Drugs.A comparison of peptide and folate receptor targeting of cancer cells: from single agent to nanoparticle.Design, functionalization strategies and biomedical applications of targeted biodegradable/biocompatible polymer-based nanocarriers for drug delivery.Therapeutic gene delivery using bioreducible polymers.Intra-islet endothelial cell and β-cell crosstalk: Implication for islet cell transplantation.EphA2 targeting peptide tethered bioreducible poly(cystamine bisacrylamide-diamino hexane) for the delivery of therapeutic pCMV-RAE-1γ to pancreatic islets.Polymeric nanomaterials for islet targeting and immunotherapeutic delivery.Small molecules can selectively inhibit ephrin binding to the EphA4 and EphA2 receptorsChanges in islet microvasculature following streptozotocin-induced beta-cell loss and subsequent replacement in the neonatal rat.Drug delivery vectors based on filamentous bacteriophages and phage-mimetic nanoparticles.Autonomous self-navigating drug-delivery vehicles: from science fiction to reality.
P2860
Q26799461-6356BB69-64DB-4B5B-91C8-29B604DBBFE4Q27651657-D2FAFF23-D16D-4D7B-A5C7-D93F2EE93B2CQ31144876-E366CBE1-E288-4BF9-89B1-B3E9C4B4D6B1Q33257951-4BAC1981-9E67-41A7-9E3C-A6BEBA528DA9Q33264491-C628088D-3032-46FC-B598-2661337C503DQ33290432-A514C016-A0E0-4266-B48B-3386729A12DAQ33318553-F8D22621-7511-4C54-BA58-93421FA5F764Q33347082-6CCBD50C-0728-4829-9540-05BE2AEE5E90Q33362288-9A5BC66D-302F-460E-879A-D1D6CB2F58FDQ33382036-1C68FEF5-8000-4B3B-B847-09E4AF6F9CE9Q33470770-B4CCA5EA-C849-4478-8FED-71D8F620FA42Q33494276-C4AD1BD4-9822-43BF-981D-81FD2D6C4FC0Q33530848-11434387-6651-4CCF-813C-605ADE0662A0Q33532734-15717C38-F5F9-4B0D-B8D4-B541527DFB56Q33549733-39AA2D0B-A5A1-4C96-A66C-85DD58172927Q33618844-0BA86E43-158A-43E1-B2D8-892AD4CCA9E7Q33680616-8C25F943-517C-4609-A930-DAB0E0C7E4C3Q34079568-3D4E0EFB-B6A0-49BB-BFEC-896CCC5CE070Q34228815-2C46070F-945D-4899-BCB6-B65A9E178CDFQ34353740-CA3EC012-F526-4BFC-8E95-21098F508447Q35229487-A3F5EDD2-1BD6-44B7-9D16-13D7AEAB3ED0Q35385982-584DAEE3-531C-4F90-8E5D-496322A89183Q35586630-68084F6A-F9FD-462E-8D6E-3917D870F6CFQ35589427-A6416759-CC73-4E2C-AFF3-E5BDA29DBD2FQ35895637-1170E551-3972-4A42-B64D-2C311EAC2300Q36269185-2218234D-0CBC-4386-9A01-B3D9B297A69DQ36332226-4F94858B-1B54-4CC8-8D4B-E76B939A92D1Q36659064-74B6A713-1BBA-4108-9806-9044E3F32583Q36905225-7FC59257-5853-4A7C-8E61-ED6B57BE8069Q37183977-C54624E6-5BBA-451D-A86A-B3FE2B1B071AQ37838443-EC7D49FE-1060-43D0-94E7-500A8EC2533EQ38067265-F3F2EFF6-BDAF-484A-9147-97058411E06BQ38157750-738BAE30-C3A1-4FE1-B293-B643F6BDC7CDQ39308780-5D8C5CB8-F7D3-4D98-BFF8-89B0FB9FF96EQ39446880-9586A06E-F943-45ED-8809-917D8887297DQ41142767-B0BC0354-CACD-47C3-8F6C-4020FE5F2E8BQ41875227-1F719704-77E9-4F96-8120-260473C14663Q43093151-7752E1F6-870B-4EFD-96F5-51B1625BCC33Q47298251-B01134C6-D7FE-4F0C-8093-D9FEE0CA5430Q47417419-F4991879-550D-4EC6-AA2C-A6D4E92142AC
P2860
Targeting pancreatic islets with phage display assisted by laser pressure catapult microdissection.
description
2005 nî lūn-bûn
@nan
2005 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2005 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
name
Targeting pancreatic islets wi ...... sure catapult microdissection.
@ast
Targeting pancreatic islets wi ...... sure catapult microdissection.
@en
type
label
Targeting pancreatic islets wi ...... sure catapult microdissection.
@ast
Targeting pancreatic islets wi ...... sure catapult microdissection.
@en
prefLabel
Targeting pancreatic islets wi ...... sure catapult microdissection.
@ast
Targeting pancreatic islets wi ...... sure catapult microdissection.
@en
P2093
P2860
P1476
Targeting pancreatic islets wi ...... sure catapult microdissection.
@en
P2093
Donald M McDonald
Martin Trepel
Michael G Ozawa
Virginia J Yao
Wadih Arap
P2860
P304
P356
10.1016/S0002-9440(10)62283-3
P407
P577
2005-02-01T00:00:00Z