3D MORPHOGENESIS AND BACTERIAL CO-CULTURE IN A CANINE GUT-ON-A-CHIP USING BIOPSY-DERIVED INTESTINAL ORGANOIDS FROM HEALTHY AND IBD PATIENTS

Abstract

Abstract The understanding of the role of intestinal bacteria in various intestinal diseases has been limited due to the lack of suitable in vitro models. However, recent advancements in Gut-on-a-Chip culture technology provide a promising avenue for exploring complex interactions between intestinal epithelium and bacteria. In this study, we aimed to create a microfluidic Gut-on-a-Chip co-culture system using dogs as a model. Dogs share similarities with humans in terms of intestinal disease pathophysiology, clinical presentations, and intestinal microbiome, making them a relevant model for various intestinal diseases, including inflammatory bowel disease (IBD). We cultured colonoids from both healthy dogs and dogs with IBD on the Gut-on-a-Chip platform to create villus-like structures under dynamic conditions. Co-cultures with non-pathogenic Escherichia coli (NPE) were established in the Gut-on-a-Chip with healthy colonoids, and we conducted a static Transwell (TW) co-culture for comparison. To assess epithelial barrier integrity, we measured transepithelial electrical resistance (TEER), and we evaluated the expression of ZO-1, a tight junction protein, through immunofluorescence staining (IF). Following 6-9 days of uninterrupted medium flow in the Gut-on-a-Chip models, we observed sporadic clusters of villus-like structures (i.e., 3D morphogenesis) in canine intestinal epithelial cells in both the models derived from healthy dogs and those with IBD. The IF confirmed the presence of ZO-1, indicating the establishment of tight junctions. Infection with NPE in the TW system resulted in a significant reduction in TEER (48.2±4.4% at 12 hours and 7.3±5.3% at 24 hours). In contrast, the Gut-on-a-Chip maintained TEER levels at 100.3±12.8% at 12 hours, 94.9±2.2% at 24 hours, and 88.8±15.0% at 48 hours, preserving the 3D structure. The innovative canine Gut-on-a-Chip model, capable of reproducing villus-like structures and preserving a 3D configuration using both healthy and diseased organoids (specifically, IBD), presents a valuable platform for investigating bacterial-epithelium interactions in both human and veterinary medicine. This dynamic microfluidic culture system enables the co-cultivation of living bacteria while maintaining epithelial integrity, facilitating the study of intricate interactions between intestinal bacteria and epithelial crosstalk.