Spatiotemporal controlled delivery of nanoparticles to injured vasculature
about
Annexin A1-containing extracellular vesicles and polymeric nanoparticles promote epithelial wound repair.Versatile Nanosystem-Based Cancer Theranostics: Design Inspiration and Predetermined RoutingDrug-Initiated Synthesis of Polymer Prodrugs: Combining Simplicity and Efficacy in Drug DeliveryInsulin resistance, hyperglycemia, and atherosclerosisTargeted therapy using nanotechnology: focus on cancerIntrapericardial delivery of gelfoam enables the targeted delivery of Periostin peptide after myocardial infarction by inducing fibrin clot formationThe prevention and regression of atherosclerotic plaques: emerging treatments.Controlled Drug Release from Pharmaceutical NanocarriersInteractions of nanomaterials and biological systems: Implications to personalized nanomedicineAn emerging interface between life science and nanotechnology: present status and prospects of reproductive healthcare aided by nano-biotechnologyMacrophages in the pathogenesis of atherosclerosisLipid-Based Drug Delivery Systems in Cancer Therapy: What Is Available and What Is Yet to Come.Polymeric Nanostructures for Imaging and TherapyNanostructured ultra-thin patches for ultrasound-modulated delivery of anti-restenotic drugPerspectives and opportunities for nanomedicine in the management of atherosclerosis.Inflamed leukocyte-mimetic nanoparticles for molecular imaging of inflammationNanoparticle targeting to diseased vasculature for imaging and therapy.Removing vascular obstructions: a challenge, yet an opportunity for interventional microdevices.Magnetic nanomaterials for hyperthermia-based therapy and controlled drug delivery.Cancer nanotechnology: the impact of passive and active targeting in the era of modern cancer biology.Targeted delivery of nanoparticles to ischemic muscle for imaging and therapeutic angiogenesis.Synthesis and characterization of lipid-polymer hybrid nanoparticles with pH-triggered poly(ethylene glycol) shedding.In vivo prevention of arterial restenosis with paclitaxel-encapsulated targeted lipid-polymeric nanoparticlesPolymer-based therapeutics: nanoassemblies and nanoparticles for management of atherosclerosisShape-Dependent Targeting of Injured Blood Vessels by Peptide Amphiphile Supramolecular NanostructuresRedox-Responsive Self-Assembled Chain-Shattering Polymeric Therapeutics.Engineering of targeted nanoparticles for cancer therapy using internalizing aptamers isolated by cell-uptake selection.Painting blood vessels and atherosclerotic plaques with an adhesive drug depotSynthesis of water-soluble poly(α-hydroxy acids) from living ring-opening polymerization of O-benzyl-L-serine carboxyanhydrides.Targeted Nitric Oxide Delivery by Supramolecular Nanofibers for the Prevention of Restenosis After Arterial Injury.Development and in vivo efficacy of targeted polymeric inflammation-resolving nanoparticles.Augmenting drug-carrier compatibility improves tumour nanotherapy efficacy.Light-triggered theranostics based on photosensitizer-conjugated carbon dots for simultaneous enhanced-fluorescence imaging and photodynamic therapy.Making things stick in the fight against atherosclerosisNanoparticle biointerfacing by platelet membrane cloaking.Targeted polymeric therapeutic nanoparticles: design, development and clinical translationLiposome-like Nanostructures for Drug Delivery.Targeted Interleukin-10 Nanotherapeutics Developed with a Microfluidic Chip Enhance Resolution of Inflammation in Advanced Atherosclerosis.Systemically administered collagen-targeted gold nanoparticles bind to arterial injury following vascular interventions.Synthesis of a cell penetrating peptide modified superparamagnetic iron oxide and MRI detection of bladder cancer.
P2860
Q24318444-F2E7493F-E557-4E7A-8C65-3E44A140F147Q26746171-CDA8A324-722E-4E6D-AA30-C365ECCD5453Q26752989-EAA5F962-3D9B-454B-93D7-4239C82A1C26Q27011696-6BA72163-6333-4BD9-B067-8BEA0A2C6AD1Q27023361-57CF389E-D27D-4904-BA03-FD9660E31FFCQ27303167-1237BA7C-9583-443C-A754-A7548419B308Q27691367-2E3AD42E-114F-4062-BCBE-91CE75D3D24AQ28257050-24233DEA-CE4C-463D-B1D7-A7620985AE53Q28391849-18331A5C-E0D3-492C-92AA-923893ED89E7Q28658189-0E66B0F3-2A41-4FD9-8B7E-97F22A660C51Q29617765-FAEB8F0A-0B8F-4121-A9B3-358E2BD55F64Q30366990-42D19317-9FEA-441E-A66C-263CCE18BE6EQ30372383-44F0726C-C287-4E3D-937D-C71235FE5636Q30394513-485EFE72-A4D1-4DCC-8D16-8527DF658C53Q30455490-6CF5BA5A-E6C7-4EC3-AB98-2619829EFD26Q30462815-A04C6F40-033B-403F-AA6B-2114FC4B8ADAQ33831738-A9D68494-1A8A-4C8B-A2E0-ED769EF57A32Q34158094-AEF7096B-263E-4493-BCE5-3F8FF5D3791CQ34174125-D7AD0EAB-AB33-409E-B97A-204FB1BBE632Q34447986-DFD7A1B4-6BD3-4FFB-963D-C0C5A435A26EQ34776009-87A94430-13A3-4817-BF25-351CA968E293Q35193987-DA037F74-10DB-4BE4-99DF-7F5B2B0DC0ACQ35585791-2A1CBBB3-3C5C-4C23-BE05-E7CA31E1E6C4Q35710262-A02E8A72-C2ED-498D-BC6F-C61F0ADD112FQ35772871-8A9C5683-8DEE-4D73-8B79-67DBB1E96C3DQ35801338-1FED152E-29AC-4FF3-8AFC-B9A357E3E5F1Q36448777-06085F51-41D3-451A-A717-A32A6E350E91Q36504186-AAD5B385-F665-41E6-B5F7-38D7F286D9EEQ36562694-D1AC3201-CBC7-42A6-B89C-F48C78239016Q36661502-727B57CD-830D-4DE5-9861-D7A51FE99318Q36782010-902AA0EE-4BD9-4F2D-8C46-3C4A26DFA231Q36804366-3B56C427-2531-4707-8CC9-60B521A670F7Q36854187-816C4127-2CFE-48EA-ADDF-B3048E02C628Q36870901-7D2D60F6-6794-4009-AC0E-CEA557BD8DC2Q36912680-A2D0FED7-F27E-42A2-B156-BA0A6256CC79Q36934007-1E2C1E87-9566-4E2E-A082-64C194EF51B7Q37424654-E74BB709-E8BE-41F1-8B5D-D8A603556542Q37544674-775B653E-6667-4804-937C-892D14D96441Q37670254-09B0A8B0-9A57-4923-936B-98AB4BA4F7ABQ37706245-CAD3F0EA-8F00-4D96-BF02-33B1DC6D2D11
P2860
Spatiotemporal controlled delivery of nanoparticles to injured vasculature
description
2010 nî lūn-bûn
@nan
2010 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Spatiotemporal controlled delivery of nanoparticles to injured vasculature
@ast
Spatiotemporal controlled delivery of nanoparticles to injured vasculature
@en
Spatiotemporal controlled delivery of nanoparticles to injured vasculature.
@nl
type
label
Spatiotemporal controlled delivery of nanoparticles to injured vasculature
@ast
Spatiotemporal controlled delivery of nanoparticles to injured vasculature
@en
Spatiotemporal controlled delivery of nanoparticles to injured vasculature.
@nl
prefLabel
Spatiotemporal controlled delivery of nanoparticles to injured vasculature
@ast
Spatiotemporal controlled delivery of nanoparticles to injured vasculature
@en
Spatiotemporal controlled delivery of nanoparticles to injured vasculature.
@nl
P2093
P2860
P50
P356
P1476
Spatiotemporal controlled delivery of nanoparticles to injured vasculature
@en
P2093
David Gray
Debuyati Ghosh
Grace Liao
Jianjun Cheng
June-Wha Rhee
Liangfang Zhang
Robert Langer
Weiwei Gao
P2860
P304
P356
10.1073/PNAS.0914585107
P407
P577
2010-01-19T00:00:00Z