Technological Innovations and the Translational Path of Kidney Organoids

Kidney organoids, as three-dimensional microstructures derived from human pluripotent stem cells or adult stem cells, precisely simulate the cellular heterogeneity, spatial conformation, and some physiological functions of human kidney units in vitro. Kidney organoids are three-dimensional microstructures derived from human pluripotent stem cells (hPSCs). They precisely simulate the cellular heterogeneity, spatial conformation, and key physiological functions of human kidney units in vitro. This technology, by replicating the interaction network between the glomerulus and renal tubules, provides an unprecedented window for observing the dynamic development and pathological processes of human kidneys. This technology replicates the interaction network between the glomerulus and renal tubules. It thereby provides an unprecedented window into human kidney development and disease. Based on the strong similarity between organoids and native organs, as well as the human genetic information they carry, both iPSC-derived and patient-specific organoids have demonstrated significant value in kidney disease modeling, drug toxicity testing, and the development of regenerative treatment strategies. This review systematically elucidates the key advancements in the field of kidney organoids, including optimized strategies for stem cell-directed differentiation, innovations in culture systems driven by biomaterials engineering, technological breakthroughs in disease model construction, and applications of organoids in drug screening platforms and regenerative medicine. Additionally, it analyzes translational challenges such as the lack of vascularization, insufficient functional maturity, and obstacles in standardized production. These insights will deepen the understanding of kidney pathological mechanisms and propel organoid technology towards substantial clinical therapeutic applications. This review summarizes how convergent technologies in stem cell biology and bioengineering aim to bridge this functional gap. We examine the use of advanced organoids in disease modeling and drug discovery. We also highlight their current limitations. Our focus is on the core translational bottlenecks: vascularization, long-term maturation, and scalable production. Overcoming these hurdles is essential to transform kidney organoids from a research tool into a platform for precision medicine and regenerative therapy.