Abstract Background Developing effective therapies for Inflammatory Bowel Disease (IBD) necessitates advanced in vitro models that faithfully replicate the intricacies of the gut. The current challenge is to create models that encompass the 3D morphology, heterogeneity, and boundary characteristics of intestinal tissue while also being amenable to high-throughput screening. Microfluidic techniques are emerging as vital tools to introduce physiologically relevant cues into conventional cell cultures. Methods We present an innovative in vitro model employing human adult stem cell-derived colon organoids cultivated as perfused epithelial tubules within the MIMETAS OrganoPlate®. This microfluidic platform facilitates the simultaneous culture of up to 64 independent gut tubules on an extracellular matrix, offering continuous media perfusion without artificial membrane interference. The barrier function of the epithelial tubules is assessed in real-time through transepithelial electrical resistance (TEER) measurements. Immunostaining and 3D reconstruction of confocal images evaluate the expression of relevant epithelial markers. Results The tubular epithelial model of the intestinal tract demonstrated rapid cell polarization, expression of cell-specific markers, tight junction formation, and the presence of functional transporters. TEER measurements indicated functional and reproducible barrier integrity across tubules generated from different organoid donors for at least 10 days. Incorporation of additional cell types, such as patient-derived immune cells and endothelium, marks a groundbreaking advancement in understanding disease pathogenesis. The plug-and-play modularity of these models allows for flexibility in incorporating specific cell types based on the biological pathway of interest. Conclusion Our next-generation gut-on-a-chip model faithfully mimics the IBD phenotype and facilitates screening for potential drug targets. Combining adult human stem cell-derived intestinal organoids with microfluidic technology provides a robust platform to study physiology and disease mechanisms in patient-specific gut models. The inclusion of IBD patient-derived cells promises further refinement, enabling a more profound exploration of disease phenotypes and treatment responsiveness. Moreover, organoids, as one of the most physiologically relevant cell sources, authentically represent patient biology, enhancing the translational potential of our findings.
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