Applied Stem Cell Technologies, Technical Medical Centre, University of Twente, PO Box 217, Enschede 7500 AE, The Netherlands.
BIOS Lab on a Chip Group, MESA+ Institute for Nanotechnology, Technical Medical Centre, Max Planck Institute for Complex Fluid Dynamics, University of Twente, Enschede, 7500 AE, The Netherlands.
Lab Chip. 2022 Mar 15;22(6):1231-1243. doi: 10.1039/d1lc00999k.
Organs-on-chips are a unique class of microfluidic cell culture models, in which the tissue microenvironment is mimicked. Unfortunately, their widespread use is hampered by their operation complexity and incompatibility with end-user research settings. To address these issues, many commercial and non-commercial platforms have been developed for semi-automated culture of organs-on-chips. However, these organ-on-chip culture platforms each represent a closed ecosystem, with very little opportunity to interchange and integrate components from different platforms or to develop new ones. The translational organ-on-chip platform (TOP) is a multi-institutional effort to develop an open platform for automated organ-on-chip culture and integration of components from various developers. Central to TOP is the fluidic circuit board (FCB), a microfluidic plate with the form factor of a typical well plate. The FCB enables microfluidic control of multiple components like sensors or organ-on-chip devices through an interface based on openly available standards. Here, we report an FCB to integrate commercial and in-house developed components forming a stand-alone flow control system for organs-on-chips. The control system is able to achieve constant and pulsatile flow recirculation through a connected organ-on-chip device. We demonstrate that this system is able to automatically perfuse a heart-on-chip device containing co-cultures of cardiac tissues derived from human pluripotent stem cell-derived cardiomyocytes and monolayers of endothelial cells for five days. Altogether, we conclude that open technology platforms allow the integration of components from different sources to form functional and fit-for-purpose organ-on-chip systems. We anticipate that open platforms will play a central role in catalyzing and maturing further technological development of organ-on-chip culture systems.
器官芯片是一类独特的微流控细胞培养模型,可模拟组织微环境。不幸的是,由于其操作复杂且与终端用户研究环境不兼容,它们的广泛应用受到了阻碍。为了解决这些问题,已经开发了许多商业和非商业平台,用于器官芯片的半自动培养。然而,这些器官芯片培养平台各自代表了一个封闭的生态系统,几乎没有机会从不同平台互换和集成组件,也没有机会开发新的平台。翻译器官芯片平台(TOP)是一个多机构的努力,旨在开发一个用于自动化器官芯片培养和集成来自不同开发者组件的开放平台。TOP 的核心是流体电路板(FCB),这是一种具有典型孔板外形因子的微流控板。FCB 通过基于公开可用标准的接口,实现了对多个组件(如传感器或器官芯片设备)的微流体控制。在这里,我们报告了一种 FCB,用于集成商业和内部开发的组件,形成用于器官芯片的独立流量控制系统。该控制系统能够通过连接的器官芯片设备实现恒流和脉动循环。我们证明,该系统能够自动灌注包含源自人多能干细胞衍生的心肌细胞和内皮细胞单层的共培养物的心脏芯片设备五天。总之,我们得出结论,开放技术平台允许来自不同来源的组件集成,以形成功能齐全且适合用途的器官芯片系统。我们预计,开放平台将在促进和成熟器官芯片培养系统的进一步技术发展方面发挥核心作用。
