毛细管和组织中药物对流和扩散运输的计算模型

2015 IEEE 15th International Conference on Bioinformatics and Bioengineering (BIBE) Pub Date : 2015-11-02 DOI:10.1109/BIBE.2015.7367633

M. Kojic, M. Milošević, V. Isailović, V. Simić, M. Ferrari, A. Ziemys

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引用次数: 0

摘要

在本报告中，我们总结了小血管(毛细血管)和组织内对流和扩散药物运输的计算模型。提出的方法主要集中在药物运输通过微纳米粒子设计的纳米治疗癌症。我们最初的多尺度层次模型将纳米尺度分子动力学(MD)和宏观尺度连续体有限元(FE)离散化相结合。对流部分依赖于流体中运动体的固-流相互作用问题的有限元解，并采用网格重新划分程序。在扩散中，MD用于评价多孔连续体的有效扩散系数，其中包括传输分子与微观结构表面之间的物理化学相互作用，并将质量释放曲线视为本构曲线。几个典型的例子说明了我们的方法和开发的软件PAK的有效性。

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Computational models for convective and diffusive drug transport in capillaries and tissue

In this report we summarize computational models for convective and diffusive drug transport within small blood vessels (capillaries) and tissue. The presented methodology is primarily focused on drug transport via micro-nanoparticles designed for nanotherapeutics in cancer. Our original multiscale hierarchical models couple nanoscale molecular dynamics (MD) and macroscale continuum finite element (FE) discretization. The convective part relies on a FE solution of the solid-fluid interaction problem of moving bodies within fluid, with a remeshing procedure. In diffusion, MD is used to evaluate the effective diffusivity of a porous continuum, where the physico-chemical interaction between transported molecules and microstructural surface is included, and the mass release curves are considered as the constitutive curves. Several representative examples illustrate effectiveness of our methodology and developed software PAK.

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2015 IEEE 15th International Conference on Bioinformatics and Bioengineering (BIBE)

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