The influence of size, shape and vessel geometry on nanoparticle distribution - Test2 - elhamkhani - TriplyDB

The influence of size, shape and vessel geometry on nanoparticle distribution

The influence of size, shape and vessel geometry on nanoparticle distribution

http://www.wikidata.org/entity/Q39428932

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Recent Advances in Subunit Vaccine Carriers Photodynamic nanomedicine in the treatment of solid tumors: perspectives and challenges Particle margination and its implications on intravenous anticancer drug delivery Stealth filaments: Polymer chain length and conformation affect the in vivo fate of PEGylated potato virus X.Vascular distribution of nanomaterials Virus-based nanomaterials as positron emission tomography and magnetic resonance contrast agents: from technology development to translational medicine Computational Modeling of Tumor Response to Drug Release from Vasculature-Bound Nanoparticles Bioinspired Microfluidic Assay for In Vitro Modeling of Leukocyte–Endothelium Interactions Radioactive 198Au-doped nanostructures with different shapes for in vivo analyses of their biodistribution, tumor uptake, and intratumoral distribution.Dual-modal magnetic resonance and fluorescence imaging of atherosclerotic plaques in vivo using VCAM-1 targeted tobacco mosaic virus Characterization of nanoparticle delivery in microcirculation using a microfluidic device Organ-on-a-chip platforms for studying drug delivery systems.Numerical simulation of particle transport and deposition in the pulmonary vasculature Non-Spherical Particles for Targeted Drug Delivery.Modeling Nanoparticle Targeting to a Vascular Surface in Shear Flow Through Diffusive Particle Dynamics.To Target or Not to Target: Active vs. Passive Tumor Homing of Filamentous Nanoparticles Based on Potato virus X Non-affinity factors modulating vascular targeting of nano- and microcarriers Principles of nanoparticle design for overcoming biological barriers to drug delivery Characterization of Nanoparticle Dispersion in Red Blood Cell Suspension by the Lattice Boltzmann-Immersed Boundary Method.Computational modeling of magnetic nanoparticle targeting to stent surface under high gradient field.Targeted radiotherapy with gold nanoparticles: current status and future perspectives.Microfluidic platforms for advanced risk assessments of nanomaterials.Nanomaterial translocation--the biokinetics, tissue accumulation, toxicity and fate of materials in secondary organs--a review.Polymeric nanoparticles: the future of nanomedicine.Multiscale Modeling in the Clinic: Drug Design and Development LumeNEXT: A Practical Method to Pattern Luminal Structures in ECM Gels.Red blood cells: Supercarriers for drugs, biologicals, and nanoparticles and inspiration for advanced delivery systems.Effect of fractional blood flow on plasma skimming in the microvasculature.Intrinsic functional and architectonic heterogeneity of tumor-targeted protein nanoparticles.Generalized plasma skimming model for cells and drug carriers in the microvasculature.Implantable Device-Related Infection.Current Challenges toward In Vitro Cellular Validation of Inorganic Nanoparticles.Increasing Binding Efficiency via Reporter Shape and Flux in a Viral Nanoparticle Lateral-Flow Assay.Role of nanoparticle size, shape and surface chemistry in oral drug delivery.Direct Tracking of Particles and Quantification of Margination in Blood Flow.Cell and nanoparticle transport in tumour microvasculature: the role of size, shape and surface functionality of nanoparticles.Particle Targeting in Complex Biological Media.A Cellular Model of Shear-Induced Hemolysis.Shape-mediated margination and demargination in flowing multicomponent suspensions of deformable capsules.A Microfluidic Method to Mimic Luminal Structures in the Tumor Microenvironment.

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P2860

The influence of size, shape and vessel geometry on nanoparticle distribution

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2012 nî lūn-bûn

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2012年學術文章

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name

The influence of size, shape and vessel geometry on nanoparticle distribution

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The influence of size, shape and vessel geometry on nanoparticle distribution.

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The influence of size, shape and vessel geometry on nanoparticle distribution

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The influence of size, shape and vessel geometry on nanoparticle distribution.

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The influence of size, shape and vessel geometry on nanoparticle distribution

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The influence of size, shape and vessel geometry on nanoparticle distribution.

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Microfluidics and Nanofluidics

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The influence of size, shape and vessel geometry on nanoparticle distribution

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Antony Thomas

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H Daniel Ou-Yang

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Samar Shah

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Yaling Liu

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P2860

Therapeutic nanoparticles for drug delivery in cancer

Models for the specific adhesion of cells to cells

Modeling particle shape-dependent dynamics in nanomedicine

Control of endothelial targeting and intracellular delivery of therapeutic enzymes by modulating the size and shape of ICAM-1-targeted carriers

A theoretical analysis for the effect of focal contact formation on cell-substrate attachment strength.

Receptor-mediated adhesion phenomena. Model studies with the Radical-Flow Detachment Assay.

Receptor-mediated cell attachment and detachment kinetics. I. Probabilistic model and analysis

Computational model for nanocarrier binding to endothelium validated using in vivo, in vitro, and atomic force microscopy experiments.

Biologically erodable microspheres as potential oral drug delivery systems.

Cell adhesion. Competition between nonspecific repulsion and specific bonding.

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s10404-012-1024-5

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