A computational model for predicting nanoparticle accumulation in tumor vasculature.
about
Current advances in mathematical modeling of anti-cancer drug penetration into tumor tissuesSui generis: gene therapy and delivery systems for the treatment of glioblastomaEvaluation of uptake and distribution of gold nanoparticles in solid tumorsTheory and Experimental Validation of a Spatio-temporal Model of Chemotherapy Transport to Enhance Tumor Cell KillComputational Modeling of Tumor Response to Drug Release from Vasculature-Bound NanoparticlesIntravital Microscopy Imaging Approaches for Image-Guided Drug Delivery SystemsModeling of nanotherapeutics delivery based on tumor perfusion.Understanding Drug Resistance in Breast Cancer with Mathematical OncologyRelease kinetics of paclitaxel and cisplatin from two and three layered gold nanoparticles.Detection of Phosphatidylcholine-Coated Gold Nanoparticles in Orthotopic Pancreatic Adenocarcinoma using Hyperspectral ImagingOxygen-Driven Tumour Growth Model: A Pathology-Relevant Mathematical Approach.Spatial Modeling of Drug Delivery Routes for Treatment of Disseminated Ovarian CancerSimulation of the Protein-Shedding Kinetics of a Fully Vascularized Tumor.Enhanced uptake and transport of PLGA-modified nanoparticles in cervical cancer.An interdisciplinary computational/experimental approach to evaluate drug-loaded gold nanoparticle tumor cytotoxicity.3D tumor models: history, advances and future perspectives.Impact of wall shear stress and ligand avidity on binding of anti-CD146-coated nanoparticles to murine tumor endothelium under flow.Mathematical modeling analysis of intratumoral disposition of anticancer agents and drug delivery systems.The effect of nanoparticle size on in vivo pharmacokinetics and cellular interaction.Generalized plasma skimming model for cells and drug carriers in the microvasculature.The Tumor Microenvironment as a Barrier to Cancer Nanotherapy.Enhanced penetration into 3D cell culture using two and three layered gold nanoparticles.Mathematical Based Calculation of Drug Penetration Depth in Solid Tumors.The effect of interstitial pressure on therapeutic agent transport: coupling with the tumor blood and lymphatic vascular systems.Activation of the HGF/c-Met axis in the tumor microenvironment: A multispecies model.A computational model of drug delivery through microcirculation to compare different tumor treatments.3D nano- and micro-patterning of biomaterials for controlled drug delivery.Advances in Glioblastoma Multiforme Treatment: New Models for Nanoparticle Therapy.Nanoparticle-mediated drug delivery to treat infections in the female reproductive tract: evaluation of experimental systems and the potential for mathematical modeling.
P2860
Q26827129-20051262-57D5-4338-A0DB-36BA16B8A72FQ26850467-D76AA267-7F53-404B-BB81-6F70AFA0186BQ28390095-FFE1543F-6783-485F-8786-406A70CB1A69Q28550211-630F602E-28C4-45C9-B46E-013BB65DA794Q28551529-F369A5E0-5D01-4D21-94B4-A73902151514Q28553638-2629E3BA-37F7-4519-B106-8C1D2E87A29FQ30544603-2291DE92-1E88-46E0-81A1-C6AB8BDFC907Q33690336-63A224EF-FCFD-4C78-B630-E2AD73F4BE87Q35602780-8CA87ED5-9F41-4A26-B134-482954716D41Q35653735-4D7F8054-28FC-4E72-B8F6-69D9E10F756AQ35827458-6C6A98F7-0E97-4046-8D67-001B7688BD2BQ35882323-92CC6283-9C49-4903-900A-FB97549C9013Q36395322-65FDFD24-1FF0-4E67-AB35-98DC8F9EDB4CQ36825251-3F86C518-079C-4D3A-B674-6B4E2F603550Q37013368-D2A475C9-2D31-45A0-A5F8-3A378A8952B3Q38221694-9250DD1C-226C-40F8-A7FB-74D3C1F3A10DQ38261727-C01F520D-D004-482A-9B69-BFDF5831D7EBQ38392523-62994A91-3ED3-41DC-B924-6B9DFD14D982Q38784932-F998025E-E54A-4E12-A016-4ED6CF1F9683Q38818820-D99DE3EF-1D72-4AE3-A7CD-EA06AE64FA2FQ38980088-3C816144-2AEA-40F3-BDEF-7E5BC0E98118Q39079234-5F3CC17B-088F-4414-823C-2AD6418F6897Q40626318-9D49054D-B3D9-499A-901D-AF9EE67DEAABQ42542776-C27DCEE2-D336-4101-AB1F-200D841B551EQ45991749-99E28084-DA5B-44BC-B17B-C02007F6076EQ51065832-3777AA84-3CAF-44D0-A6C6-087363F39D8BQ51075711-DCD96863-D430-49ED-8E8F-90F97A6524DCQ52608753-48322965-D9A3-4FCE-8CB5-57B632E16D3EQ54212001-333EAD07-CEB8-4B8E-B698-7056488567A7
P2860
A computational model for predicting nanoparticle accumulation in tumor vasculature.
description
2013 nî lūn-bûn
@nan
2013 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@ast
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@en
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@nl
type
label
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@ast
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@en
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@nl
prefLabel
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@ast
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@en
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@nl
P2093
P2860
P1433
P1476
A computational model for predicting nanoparticle accumulation in tumor vasculature.
@en
P2093
Hermann B Frieboes
John Lowengrub
Vittorio Cristini
P2860
P304
P356
10.1371/JOURNAL.PONE.0056876
P407
P577
2013-02-28T00:00:00Z