用于可重构多（芯片上器官）组装的低成本微流控芯片及微流控路由系统的设计与制造

Design and Fabrication of Low-Cost Microfluidic Chips and Microfluidic Routing System for Reconfigurable Multi-(Organ-on-a-Chip) Assembly.

作者信息

Abu-Dawas Sadeq, Alawami Hawra, Zourob Mohammed, Ramadan Qasem

机构信息

College of Science and General Studies, Alfaisal University, Riyadh 11533, Saudi Arabia.

出版信息

Micromachines (Basel). 2021 Dec 11;12(12):1542. doi: 10.3390/mi12121542.

DOI:10.3390/mi12121542

PMID:34945392

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8707086/

Abstract

A low-cost, versatile, and reconfigurable fluidic routing system and chip assembly have been fabricated and tested. The platform and its accessories were fabricated in-house without the need for costly and specialized equipment nor specific expertise. An agarose-based artificial membrane was integrated into the chips and employed to test the chip-to-chip communication in various configurations. Various chip assemblies were constructed and tested which demonstrate the versatile utility of the fluidic routing system that enables the custom design of the chip-to-chip communication and the possibility of fitting a variety of (organ-on-a-chip)-based biological models with multicell architectures. The reconfigurable chip assembly would enable selective linking/isolating the desired chip/compartment, hence allowing the study of the contribution of specific cell/tissue within the in vitro models.

摘要

一种低成本、多功能且可重新配置的流体路由系统及芯片组件已制造并测试完毕。该平台及其配件均在内部制造，无需昂贵的专业设备，也无需特定专业知识。一种基于琼脂糖的人工膜被集成到芯片中，并用于测试各种配置下芯片间的通信。构建并测试了各种芯片组件，这些组件展示了流体路由系统的多功能用途，该系统能够实现芯片间通信的定制设计，并有可能适配多种具有多细胞架构的基于（芯片上的器官）的生物模型。可重新配置的芯片组件能够选择性地连接/隔离所需的芯片/隔室，从而允许研究体外模型中特定细胞/组织的作用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ad82/8707086/ec8092a83745/micromachines-12-01542-g002a.jpg

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用于可重构多（芯片上器官）组装的低成本微流控芯片及微流控路由系统的设计与制造

Design and Fabrication of Low-Cost Microfluidic Chips and Microfluidic Routing System for Reconfigurable Multi-(Organ-on-a-Chip) Assembly.

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