Sophia R. Meyer , Charles J. Zhang , Max A. Garcia , Megan C. Procario , Sanghee Yoo , Amber L. Jolly , Sumin Kim , Jiho Kim , Kyusuk Baek , Roland D. Kersten , Robert J. Fontana , Jonathan Z. Sexton
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Human-induced pluripotent stem cells were differentiated into human liver organoids, and their viability, liver-specific functions, and pharmacological responses were assessed over 28 days.</div></div><div><h3>Results</h3><div>The Curiochips successfully maintained liver physiology and function, showing strong albumin secretion and cytochrome (CYP) P450 activities for 28 days. Unlike traditional models requiring millimolar drug concentrations to detect hepatotoxicity, this platform showed increased sensitivity for acetaminophen and fialuridine at micromolar concentrations. <em>In situ</em> differentiation of foregut spheroids to liver organoids was also achieved, further simplifying the establishment of liver chips. 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引用次数: 0
摘要
背景与目的药物诱导的肝损伤(DILI)是药物开发中的一种主要失败模式。本研究旨在通过评估被称为 "Curio Barrier 肝芯片 "的高通量微流控肝芯片系统及其通过代谢和表型特征重现慢性肝毒性药物治疗效果的能力,解决现有临床前模型的局限性。结果Curio芯片成功地维持了肝脏的生理和功能,在28天内显示出强大的白蛋白分泌和细胞色素(CYP)P450活性。与需要毫摩尔药物浓度才能检测肝毒性的传统模型不同,该平台对微摩浓度的对乙酰氨基酚和非亚尿苷显示出更高的灵敏度。还实现了前肠球体到肝脏器官组织的原位分化,进一步简化了肝脏芯片的建立。此外,与其他可用的系统或原代人类肝细胞相比,这种芯片在 28 天内都表现出活力、功能和对 DILI 的反应能力,使其成为研究特异性 DILI 的改良模型,具有长时间药物暴露和高通量能力。诱导多能干细胞肝脏器官组织与 Curiochip 相结合,提供了一个功能强大、药理反应灵敏的高通量平台,使其成为一种很有前途的工具,可用于改善对 DILI 风险预测的预测和理解,尤其是在长期药物暴露的情况下。该模型还为其他慢性肝病的研究开辟了新途径。
A High-Throughput Microphysiological Liver Chip System to Model Drug-Induced Liver Injury Using Human Liver Organoids
Background and Aims
Drug-induced liver injury (DILI) is a major failure mode in pharmaceutical development. This study aims to address the limitations of existing preclinical models by assessing a high-throughput, microfluidic liver-on-a-chip system, termed “Curio Barrier Liver Chips,” and its capacity to recapitulate the effects of chronic hepatotoxic drug treatment through metabolic and phenotypic characterization.
Methods
Curio Barrier liver chips (Curiochips), fabricated in an 8 × 2 well configuration, were utilized to establish three dimensional liver organoid cultures. Human-induced pluripotent stem cells were differentiated into human liver organoids, and their viability, liver-specific functions, and pharmacological responses were assessed over 28 days.
Results
The Curiochips successfully maintained liver physiology and function, showing strong albumin secretion and cytochrome (CYP) P450 activities for 28 days. Unlike traditional models requiring millimolar drug concentrations to detect hepatotoxicity, this platform showed increased sensitivity for acetaminophen and fialuridine at micromolar concentrations. In situ differentiation of foregut spheroids to liver organoids was also achieved, further simplifying the establishment of liver chips. Furthermore, the chips demonstrated viability, function, and DILI responsiveness for 28 days, making this an improved model for studying idiosyncratic DILI with prolonged drug exposure and high-throughput capabilities compared to other available systems or primary human hepatocytes.
Conclusion
The Curiochips offer an advanced, miniaturized in vitro model for early-stage drug development and a sensitive, responsive, and cost-effective means to detect direct hepatotoxicity. Induced pluripotent stem cell liver organoids, in conjunction with the Curiochip, deliver a high-throughput platform with robust functionality and pharmacological responsiveness that make it a promising tool for improving the prediction and understanding of DILI risk prediction, especially with prolonged drug exposure. The model also opens new avenues for research in other chronic liver diseases.
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