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利用水凝胶通道,通过一种新的体外实验和计算方法来理解纳米颗粒流动。

Understanding nanoparticle flow with a new in vitro experimental and computational approach using hydrogel channels.

作者信息

Boutchuen Armel, Zimmerman Dell, Arabshahi Abdollah, Melnyczuk John, Palchoudhury Soubantika

机构信息

Department of Civil and Chemical Engineering, University of Tennessee at Chattanooga, Chattanooga, Tennessee 37403, United States.

SimCenter, University of Tennessee at Chattanooga, Chattanooga, Tennessee 37403, United States.

出版信息

Beilstein J Nanotechnol. 2020 Feb 6;11:296-309. doi: 10.3762/bjnano.11.22. eCollection 2020.

DOI:10.3762/bjnano.11.22
PMID:32117668
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7034222/
Abstract

Nanoparticles (NPs) are considered as one of the most promising drug delivery vehicles and a next-generation solution for current medical challenges. In this context, variables related to flow of NPs such as the quantity of NPs lost during transport and flow trajectory greatly affect the clinical efficiency of NP drug delivery systems. Currently, there is little knowledge of the physical mechanisms dominating NP flow inside the human body due to the limitations of available experimental tools for mimicking complex physiological environments at the preclinical stage. Here, we report a coupled experimental and computational fluid dynamics (CFD)-based novel in vitro approach to predict the flow velocity and binding of NP drug delivery systems during transport through vasculature. Poly(hydroxyethyl)methacrylate hydrogels were used to form soft cylindrical constructs mimicking vascular sections as flow channels for synthesized iron oxide NPs in these first-of-its-kind transport experiments. Brownian dynamics and material of the flow channels played key roles in NP flow, based on the measurements of NP flow velocity over seven different mass concentrations. A fully developed laminar flow of the NPs under these conditions was simultaneously predicted using CFD. Results from the mass loss of NPs during flow indicated a diffusion-dominated flow at higher particle concentrations but a flow controlled by the surrounding fluid and Brownian dynamics at the lowest NP concentrations. The CFD model predicted a mass loss of 1.341% and 6.253% for the 4.12 g·mL and 2.008 g·mL inlet mass concentrations of the NPs, in close confirmation with the experimental results. This further highlights the reliability of our new in vitro technique in providing mechanistic insights of NP flow for potential preclinical stage applications.

摘要

纳米颗粒(NPs)被认为是最有前途的药物递送载体之一,也是应对当前医学挑战的下一代解决方案。在这种背景下,与纳米颗粒流动相关的变量,如运输过程中损失的纳米颗粒数量和流动轨迹,会极大地影响纳米颗粒药物递送系统的临床效率。目前,由于临床前阶段模拟复杂生理环境的现有实验工具存在局限性,人们对主导纳米颗粒在人体内流动的物理机制了解甚少。在此,我们报告一种基于实验和计算流体动力学(CFD)的新型体外方法,用于预测纳米颗粒药物递送系统在通过脉管系统运输过程中的流速和结合情况。在这些首创的运输实验中,聚(甲基丙烯酸羟乙酯)水凝胶被用于形成模拟血管段的软圆柱形结构,作为合成氧化铁纳米颗粒的流动通道。基于对七种不同质量浓度下纳米颗粒流速的测量,布朗动力学和流动通道材料在纳米颗粒流动中起关键作用。在这些条件下,使用CFD同时预测了纳米颗粒充分发展的层流。纳米颗粒在流动过程中的质量损失结果表明,在较高颗粒浓度下,流动以扩散为主,但在最低纳米颗粒浓度下,流动由周围流体和布朗动力学控制。CFD模型预测,纳米颗粒入口质量浓度为4.12 g·mL和2.008 g·mL时,质量损失分别为1.341%和6.253%,与实验结果密切相符。这进一步突出了我们新的体外技术在为潜在临床前阶段应用提供纳米颗粒流动机制见解方面的可靠性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/fc8f5f5068ce/Beilstein_J_Nanotechnol-11-296-g011.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/e66e399c9024/Beilstein_J_Nanotechnol-11-296-g002.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/91ee20bdd200/Beilstein_J_Nanotechnol-11-296-g003.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/ef32a123c5fa/Beilstein_J_Nanotechnol-11-296-g004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/77568638c614/Beilstein_J_Nanotechnol-11-296-g005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/5a62ac9b54bd/Beilstein_J_Nanotechnol-11-296-g006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/6e0488cee7f8/Beilstein_J_Nanotechnol-11-296-g007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/0ba429344db8/Beilstein_J_Nanotechnol-11-296-g008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/2f254707a0d5/Beilstein_J_Nanotechnol-11-296-g009.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/be35db4b3eff/Beilstein_J_Nanotechnol-11-296-g010.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/fc8f5f5068ce/Beilstein_J_Nanotechnol-11-296-g011.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/e66e399c9024/Beilstein_J_Nanotechnol-11-296-g002.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/91ee20bdd200/Beilstein_J_Nanotechnol-11-296-g003.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/ef32a123c5fa/Beilstein_J_Nanotechnol-11-296-g004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/77568638c614/Beilstein_J_Nanotechnol-11-296-g005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/5a62ac9b54bd/Beilstein_J_Nanotechnol-11-296-g006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/6e0488cee7f8/Beilstein_J_Nanotechnol-11-296-g007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/0ba429344db8/Beilstein_J_Nanotechnol-11-296-g008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/2f254707a0d5/Beilstein_J_Nanotechnol-11-296-g009.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/be35db4b3eff/Beilstein_J_Nanotechnol-11-296-g010.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d483/7034222/fc8f5f5068ce/Beilstein_J_Nanotechnol-11-296-g011.jpg

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