A comprehensive review on organ-on-chips as powerful preclinical models to study tissue barriers

Yagmur Filiz, Alessio Esposito, Carmelo De Maria, Giovanni Vozzi and Ozlem Yesil-Celiktas
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Abstract

In the preclinical stage of drug development, 2D and 3D cell cultures under static conditions followed by animal models are utilized. However, these models are insufficient to recapitulate the complexity of human physiology. With the developing organ-on-chip (OoC) technology in recent years, human physiology and pathophysiology can be modeled better than traditional models. In this review, the need for OoC platforms is discussed and evaluated from both biological and engineering perspectives. The cellular and extracellular matrix components are discussed from a biological perspective, whereas the technical aspects such as the intricate working principles of these systems, the pivotal role played by flow dynamics and sensor integration within OoCs are elucidated from an engineering perspective. Combining these two perspectives, bioengineering applications are critically discussed with a focus on tissue barriers such as blood-brain barrier, ocular barrier, nasal barrier, pulmonary barrier and gastrointestinal barrier, featuring recent examples from the literature. Furthermore, this review offers insights into the practical utility of OoC platforms for modeling tissue barriers, showcasing their potential and drawbacks while providing future projections for innovative technologies.
器官芯片作为研究组织屏障的强大临床前模型的全面综述
在药物开发的临床前阶段,人们利用静态条件下的二维和三维细胞培养物以及动物模型。然而,这些模型不足以再现人体生理的复杂性。近年来,随着片上器官(OoC)技术的发展,人体生理和病理生理学的建模效果比传统模型更好。本综述将从生物学和工程学的角度讨论和评估 OoC 平台的需求。从生物学的角度讨论了细胞和细胞外基质的成分,而从工程学的角度阐明了这些系统复杂的工作原理、流动动力学所起的关键作用以及 OoCs 中的传感器集成等技术方面的问题。结合这两个视角,本综述对生物工程应用进行了批判性讨论,重点关注血脑屏障、眼屏障、鼻屏障、肺屏障和胃肠道屏障等组织屏障,并列举了最新的文献实例。此外,本综述还深入探讨了 OoC 平台在组织屏障建模中的实际效用,展示了其潜力和缺点,并对创新技术的未来进行了预测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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