Cell-free protein synthesis (CFPS) is an in vitro platform that enables rapid protein production using cell extracts, energy sources, and genetic templates. Owing to its fast response, elimination of cell culture, open reaction environment, lyophilization compatibility, and high programmability, CFPS has emerged as a versatile engine for diagnostic sensing. Recent advances have integrated CFPS with modular genetic circuits, CRISPR-based detection, isothermal amplification, and portable formats such as paper-based devices and microfluidic chips, enabling sensitive and specific detection of viral nucleic acids, pathogen antigens, and small-molecule targets. These platforms further support multiplexed and point-of-care testing, substantially reducing assay time, cost, and infrastructure requirements. Despite remaining challenges in biosensor design for novel targets, analytical sensitivity in complex samples, batch-to-batch reproducibility, and clinical translation, continued engineering optimization is rapidly improving CFPS performance and robustness. This review summarizes the fundamental principles of CFPS, its major technological platforms, recent progress in diagnostic applications, and key challenges and opportunities for future development.
Keywords: cell-free protein synthesis; clinical diagnostics; isothermal nucleic acid amplification; microfluidic biosensing; paper-based sensors; point-of-care testing; synthetic biology; synthetic genetic circuits.