earticle

영어

Background: Embryo implantation is a complex process regulated by interactions between endometrial epithelial and stromal cells. The endometrium plays a critical role in this process, providing a supportive environment for embryo attachment. However, conventional 2D cell culture models fail to fully replicate the complex 3D structure and cellular interactions of the endometrium. To overcome these limitations, 3D organoid models have been developed to better mimic the in vivo endometrial environment. Methods: In this study, a multicellular uterine organoid model was developed using porcine endometrial epithelial cells (pEECs) and porcine endometrial stromal cells (pESCs) to evaluate the effects of the endometrial environment on embryo implantation. First, single-cell endometrial organoids (pEOs) were formed by culturing pEECs in Matrigel, and their basic cellular characteristics were assessed. Then, a multicellular uterine organoid model was established by combining pEOs with pESCs. Finally, porcine embryos were co-cultured with this model to examine its effect on embryo attachment. Results: The multicellular uterine organoid model facilitated embryo attachment, demonstrating that the 3D structure and cellular interactions of the endometrium play a significant role in embryo implantation. The presence of both epithelial and stromal cells contributed to a more physiologically relevant environment that supported embryo adhesion. Conclusions: This study demonstrates that a multicellular uterine organoid model can serve as a useful in vitro system for porcine embryo implantation research. This model may contribute to a better understanding of embryo development and implantation mechanisms, with potential applications in regenerative medicine and biotechnology.