Modeling adhesion dynamics of nanoparticles: The effect of flow rates and ligand density

机译：模拟纳米颗粒的粘附动力学：流速和配体密度的影响

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Adhesion of micro and nanoparticles onto cardiovascular walls is a critical process in applications such as targeted drug delivery, biomedical imaging, and cancer treatment. This paper intends to develop an understanding of the dynamic interaction between particle and vessel wall through computational modeling. The ligand-receptor binding dynamics is coupled with immersed finite element method to study the adhesion process of particles with different shapes, bonding strengths, and physical configurations. Non-spherical particle is found to contact and adhere to the wall easier than spherical particle under the same configuration. This research work will help design of microanoparticles for enhanced targeted adhesion to cells of interest.

机译：在诸如靶向药物输送，生物医学成像和癌症治疗等应用中，微粒和纳米颗粒在心血管壁上的粘附是关键过程。本文旨在通过计算建模来加深对粒子与容器壁之间动态相互作用的理解。配体-受体结合动力学与沉浸有限元方法相结合，以研究具有不同形状，结合强度和物理构型的颗粒的粘附过程。发现在相同配置下，非球形粒子比球形粒子更容易接触和粘附到壁上。这项研究工作将有助于设计微米/纳米颗粒，以增强对目标细胞的靶向粘附。

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《Biomedical Science amp; Engineering Conference, 2009. BSEC 2009》|2009年|1-4|共4页
会议地点 Oak Ridge TN(US);Oak Ridge TN(US);Oak Ridge TN(US)
作者
Shah S.; Yaling Liu; Wenchuang Hu; Jinming Gao;
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Univ. of Texas at Arlington, Arlington, TX;

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adhesion; biological fluid dynamics; blood vessels; cardiovascular system; cellular biophysics; diseases; finite element analysis; molecular biophysics; nanoparticles; nanotechnology; adhesion process; bond strength; cardiovascular wall; disease cell; flow rate effect; immersed finite element method; ligand-receptor binding dynamic interaction; microparticle; nanoparticle; nonspherical particle; physical configuration; vessel wall;

机译：黏附;生物流体动力学;血管;心血管系统;细胞生物物理学;疾病;有限元分析;分子生物物理学;纳米粒子;纳米技术;黏附过程;粘结强度;心血管壁;疾病细胞;流速效应;浸入有限元法;配体受体结合动态相互作用；微粒；纳米粒子；非球形粒子；物理构型；血管壁;
入库时间 2022-08-26 14:25:46

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1. Modeling Cell Adhesion to a Substrate with Gradient in Ligand Density [J] . Alireza S. Sarvestani, Esmaiel Jabbari AIChE Journal . 2009,第11期

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2. Assessing potential peptide targeting ligands by quantification of cellular adhesion of model nanoparticles under flow conditions [J] . Broda Ellen, Mickler Frauke Martina, Laechelt Ulrich, Journal of Controlled Release: Official Journal of the Controlled Release Society . 2015,第Null期

机译：通过定量流动条件下模型纳米颗粒的细胞粘附力来评估潜在的靶向肽的配体
3. Thermodynamic Evidence for Ca~(2+)-Mediated Self-Aggregation of Lewis X Gold Glyconanoparticles.A Model for Cell Adhesion via Carbohydrate-Carbohydrate Interaction [J] . Jesus M.de la Fuente, Peter Eaton, Africa G.Barrientos, Journal of the American Chemical Society . 2005,第17期

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4. Modeling Adhesion Dynamics of Nanoparticles: The Effect of Flow Rates and Ligand Density [C] . Samar Shah, Yaling Liu, Wenchuang Hu, Annual ORNL Biomedical Science Engineering Conference: Exploring the Intersections of Interdisciplinary Biomedical Research . 2009

机译：纳米粒子的建模粘附动力学：流速和配体密度的影响
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Modeling adhesion dynamics of nanoparticles: The effect of flow rates and ligand density

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