生物加工
计算机科学
可扩展性
过程(计算)
纳米技术
系统工程
个性化医疗
微流控
药物开发
再生医学
精密医学
领域(数学)
背景(考古学)
临床实习
转化研究
转化医学
钥匙(锁)
软件工程
可靠性(半导体)
风险分析(工程)
自动化
工程类
生化工程
可用性
适应性
作者
Yogendra Pratap Singh,Joseph Christakiran Moses,Myoung-Hwan Kim,Deepak Gupta,Vaibhav Pal,Irem Derman Deniz,Ethan Gerhard,İbrahim T. Özbolat
标识
DOI:10.1016/j.bioactmat.2025.11.024
摘要
The field of biofabrication is rapidly evolving, yet it faces persistent challenges, including long manufacturing latency, slow throughput, issues with reproducibility, and scalability limitations. High-throughput biofabrication (HTBF) has emerged as a powerful strategy which is presented here to address these gaps through a structured, three-tier framework. Tier 1 encompasses core HTBF methods, such as multi-modal bioprinting and robotic bioassembly, which enable the rapid fabrication of large, physiologically relevant tissue constructs. Tier 2 comprises assisting platforms, including microfluidics and microphysiological bioreactors, which provide perfusion, mechanical conditioning, multiplexable sensing, and process parallelization. Tier 3 represents HTBF outcomes, including organoids, organ-on-a-chip systems, and engineered tissue grafts that deliver clinically and pharmacologically relevant insights. These advancements enable the development of in-vitro models that streamline drug testing, making it more cost-effective and efficient, while enhancing the accuracy and reliability of preclinical drug evaluation. This review defines HTBF by outlining its core characteristics and framework, presenting insights into recent technological advancements and their applications in regenerative medicine and drug discovery. Additionally, it addresses the regulatory and clinical translation challenges that must be resolved to facilitate the adoption of HTBF in personalized healthcare.
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