ETV2 Mediated Differentiation of Human Pluripotent Stem Cells Results in Functional Endothelial Cells for Engineering Advanced Vascularized Microphysiological Models

Authors

• Shun Zhang, Institute of Zoology Chinese Academy of Sciences
• Zhengpeng Wan, Michigan Technological UniversityFollow
• Lei Wang, MIT School of Engineering
• Caihong Wu, Institute of Zoology Chinese Academy of Sciences
• Junkai Zhang, Institute of Zoology Chinese Academy of Sciences
• Sarah Spitz, MIT School of Engineering
• Xun Wang, MIT School of Engineering
• Marie A. Floryan, MIT School of Engineering
• Mark F. Coughlin, MIT School of Engineering
• Francesca M. Pramotton, MIT School of Engineering
• Liling Xu, Massachusetts Institute of Technology
• Ron Weiss, MIT School of Engineering
• Roger D. Kamm, MIT School of Engineering

Document Type

Article

Publication Date

3-12-2026

Department

Department of Biomedical Engineering

Abstract

Patient-specific microphysiological models have become a valuable tool for broad applications, revolutionizing biomedical research. However, limitations persist, with functional vasculature being a significant challenge. With the discovery of ETV2's determinant role in specifying EC lineages during differentiation, researchers have adopted techniques involving ETV2 overexpression to produce h-iECs more efficiently and consistently. Here, we generated multiple h-iPSC lines with inducible ETV2 expression, and subsequently differentiated them into h-iECs, which were validated functionally and by key endothelial markers and RNA-seq analysis. These cells are capable of reproducibly self-organizing into stable microvascular networks (MVNs) in a microfluidic chip, forming lumenized and functional vessels that mimic the in vivo capillary bed in both morphology and function—a result not achieved using h-iECs differentiated with previous two-step methods using the same h-iPSC lines. Complex microphysiological models featuring perfusable vasculature were also successfully developed using ETV2-activated h-iECs, demonstrated with vascularized tumor and blood-brain barrier (BBB) models. Additionally, by pooling genetically engineered h-iPSCs with inducible ETV2, we employed an orthogonally induced differentiation approach to enhance vascularization of an organoid model. Our methodology opens avenues in precision medicine, leading to personalized microphysiological models with perfusable vasculature for various applications.

Publisher's Statement

© 2026 The Author(s). Advanced Healthcare Materials published by Wiley-VCH GmbH. Publisher’s version of record: https://doi.org/10.1002/adhm.202504849

Publication Title

Advanced Healthcare Materials

Recommended Citation

Zhang, S., Wan, Z., Wang, L., Wu, C., Zhang, J., Spitz, S., Wang, X., Floryan, M., Coughlin, M., Pramotton, F., Xu, L., Weiss, R., & Kamm, R. (2026). ETV2 Mediated Differentiation of Human Pluripotent Stem Cells Results in Functional Endothelial Cells for Engineering Advanced Vascularized Microphysiological Models. Advanced Healthcare Materials. http://doi.org/10.1002/adhm.202504849
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p2/2455

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

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