集成了多功能传感器的器官芯片可在受控氧气水平下对新陈代谢进行连续监测

bioRxiv Pub Date : 2024-08-09 DOI:10.1101/2024.08.08.606660
Z. Izadifar, Berenice Charrez, Micaela Almeida, Stijn Robben, K. Pilobello, Janet van der Graaf-Mas, Max Benz, Susan Marquez, Thomas C. Ferrante, K. Shcherbina, Russell Gould, Nina LoGrande, A. Sesay, Donald E Ingber
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引用次数: 0

摘要

尽管器官芯片(Organ-on-a-chip)微流体培养技术取得了长足进步,但重现组织相关生理条件(如特定区域的氧气浓度)仍是一项艰巨的技术挑战,而且组织功能分析通常一次只使用一种分析技术。在这里,我们描述了由聚二甲基硅氧烷和不透气聚碳酸酯材料制成的双通道器官芯片微流控装置,该装置集成了多个传感器,安装在印刷电路板上,并使用市售的器官芯片培养仪进行操作。该系统的新颖之处在于,它能再现与生理相关的组织-组织界面和氧张力,并能无创连续测量跨上皮电阻、氧浓度和 pH 值,同时分析细胞代谢活动(ATP/ADP 比值)、细胞形态和组织表型。我们在活体人体肠道和肝脏芯片培养物中展示了这一系统可靠、可重复的功能。我们在芯片上对组织屏障功能和氧张力的变化以及它们对化学刺激(如钙螯合、低聚霉素)的功能和代谢反应进行了长达 23 天的连续无创监测。肠道芯片还展示了支持人类肠道细胞与乳酸乳球菌共培养的生理相关微氧微环境。将多功能传感器集成到器官芯片中为同时、连续和无创监测多种生理功能提供了一个稳健且可扩展的平台,可显著提高器官芯片模型中工程组织在基础研究、临床前建模和药物开发中的全面可靠评估。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Organ Chips with integrated multifunctional sensors enable continuous metabolic monitoring at controlled oxygen levels
Despite remarkable advances in Organ-on-a-chip (Organ Chip) microfluidic culture technology, recreating tissue-relevant physiological conditions, such as the region-specific oxygen concentrations, remains a formidable technical challenge, and analysis of tissue functions is commonly carried out using one analytical technique at a time. Here, we describe two-channel Organ Chip microfluidic devices fabricated from polydimethylsiloxane and gas impermeable polycarbonate materials that are integrated with multiple sensors, mounted on a printed circuit board and operated using a commercially available Organ Chip culture instrument. The novelty of this system is that it enables the recreation of physiologically relevant tissue-tissue interfaces and oxygen tension as well as non-invasive continuous measurement of transepithelial electrical resistance, oxygen concentration and pH, combined with simultaneous analysis of cellular metabolic activity (ATP/ADP ratio), cell morphology, and tissue phenotype. We demonstrate the reliable and reproducible functionality of this system in living human Gut and Liver Chip cultures. Changes in tissue barrier function and oxygen tension along with their functional and metabolic responses to chemical stimuli (e.g., calcium chelation, oligomycin) were continuously and noninvasively monitored on-chip for up to 23 days. A physiologically relevant microaerobic microenvironment that supports co-culture of human intestinal cells with living Lactococcus lactis bacteria also was demonstrated in the Gut Chip. The integration of multi-functional sensors into Organ Chips provides a robust and scalable platform for the simultaneous, continuous, and non-invasive monitoring of multiple physiological functions that can significantly enhance the comprehensive and reliable evaluation of engineered tissues in Organ Chip models in basic research, preclinical modeling, and drug development.
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