Synergistic innovation in organ-on-a-chip and organoid technologies: Reshaping the future of disease modeling, drug development and precision medicine.

IF 13.6 1区生物学 Q1 CELL BIOLOGY

Protein & Cell Pub Date : 2025-07-13 DOI:10.1093/procel/pwaf058

Bing Li,Yuanjun Tang,Zhanya Huang,Lijun Ma,Jiagui Song,Lixiang Xue

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引用次数: 0

Abstract

FDA issued guidance on April 10th, 2025 to phase out animal trials in favor of organoids and organ-on-a-chip systems. This pivotal move was swiftly followed by National Institutes of Health (NIH) on April 29th, when it inaugurated the Office of Research Innovation, Validation, and Application (ORIVA). The establishment of ORIVA aims to spearhead the advancement of human-centric organ-on-a-chip technologies, marking a major stride toward more accurate, ethical, and efficient research methods in the biomedical field. Compared to traditional 2D cell cultures and animal models, organ-on-a-chip systems enable precise control of hydrodynamic parameters and biomechanical microenvironments. This review systematically elaborates on applications of single-organ, multi-organ, and organoid-on-a-chip technologies in modeling complex diseases, host-microbiome interactions, inter-organ physiological networks, and quantitative prediction of pharmacokinetics, toxicity responses, and personalized therapies. Furthermore, the core challenges in translating these technologies to pharmaceutical development and clinical practice are critically analyzed. With interdisciplinary integration of materials engineering, biosensing, and artificial intelligence, organ-on-a-chip technologies are transcending the limitations of conventional preclinical research. Their strategic value as 'patient surrogates' is poised to accelerate breakthroughs in precision medicine and rare disease treatments.

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芯片上器官和类器官技术的协同创新：重塑疾病建模、药物开发和精准医学的未来。

FDA于2025年4月10日发布指导意见，逐步淘汰动物试验，转而支持类器官和器官芯片系统。4月29日，美国国立卫生研究院（NIH）迅速跟进了这一关键举措，成立了研究创新、验证和应用办公室（ORIVA）。ORIVA的成立旨在引领以人类为中心的器官芯片技术的发展，标志着在生物医学领域朝着更准确、更伦理、更高效的研究方法迈出了一大步。与传统的2D细胞培养和动物模型相比，器官芯片系统能够精确控制流体动力学参数和生物力学微环境。本文系统阐述了单器官、多器官和类器官芯片技术在复杂疾病建模、宿主-微生物组相互作用、器官间生理网络、药物动力学定量预测、毒性反应和个性化治疗等方面的应用。此外，将这些技术转化为药物开发和临床实践的核心挑战进行了批判性分析。随着材料工程、生物传感和人工智能的跨学科融合，器官芯片技术正在超越传统临床前研究的局限性。它们作为“患者替代品”的战略价值将加速精准医疗和罕见疾病治疗的突破。

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来源期刊

Protein & Cell CELL BIOLOGY-

CiteScore

24.00

自引率

0.90%

发文量

1029

审稿时长

6-12 weeks

期刊介绍： Protein & Cell is a monthly, peer-reviewed, open-access journal focusing on multidisciplinary aspects of biology and biomedicine, with a primary emphasis on protein and cell research. It publishes original research articles, reviews, and commentaries across various fields including biochemistry, biophysics, cell biology, genetics, immunology, microbiology, molecular biology, neuroscience, oncology, protein science, structural biology, and translational medicine. The journal also features content on research policies, funding trends in China, and serves as a platform for academic exchange among life science researchers.