Organoids: development and applications in disease models, drug discovery, precision medicine, and regenerative medicine

Abstract Organoids are miniature, highly accurate representations of organs that capture the structure and unique functions of specific organs. Although the field of organoids has experienced exponential growth, driven by advances in artificial intelligence, gene editing, and bioinstrumentation, a comprehensive and accurate overview of organoid applications remains necessary. This review offers a detailed exploration of the historical origins and characteristics of various organoid types, their applications—including disease modeling, drug toxicity and efficacy assessments, precision medicine, and regenerative medicine—as well as the current challenges and future directions of organoid research. Organoids have proven instrumental in elucidating genetic cell fate in hereditary diseases, infectious diseases, metabolic disorders, and malignancies, as well as in the study of processes such as embryonic development, molecular mechanisms, and host–microbe interactions. Furthermore, the integration of organoid technology with artificial intelligence and microfluidics has significantly advanced large‐scale, rapid, and cost‐effective drug toxicity and efficacy assessments, thereby propelling progress in precision medicine. Finally, with the advent of high‐performance materials, three‐dimensional printing technology, and gene editing, organoids are also gaining prominence in the field of regenerative medicine. Our insights and predictions aim to provide valuable guidance to current researchers and to support the continued advancement of this rapidly developing field.