Hemodynamics-driven magnetoelastic vascular grafts for stenosis diagnosis.

Authors

Guorui Chen
Tzuchun Chung
Zeyang Liu
Yan-Ruide Li
Kamryn Scott
Xun Zhao
Jarod Carol
Soomin Park
Yihao Zhou
Wi Jin Kim
Xinyang Ge
Geoffrey P Colby
Song Li
Jun Chen

Publication/Presentation Date

2-10-2026

Abstract

Conventional approaches for vascular graft stenosis diagnostics, including X-ray angiography, magnetic resonance imaging and Doppler ultrasound, although highly accurate, are cumbersome, used intermittently and often do not detect stenosis early enough, leading to diagnosis only after substantial narrowing. Here we report a magnetoelastic vascular graft (MVG) for post-implantation stenosis diagnosis that is hemodynamics-driven, biocompatible and waterproof. It enables wireless, real-time and continuous diagnosis of stenosis by converting arterial hemodynamics into high-fidelity electrical signals. The MVGs were scalably manufactured with customizable diameters and tested in vivo in the femoral arteries of rats and swine through microsurgical anastomosis. The anastomosed MVGs restored blood flow and identified the location and severity of induced stenosis through artificial intelligence-assisted analysis. Furthermore, a 4-month in vivo study in rats verified the stability and biocompatibility of the MVGs in the host, with no evident signs of an adverse immune response. The MVG is expected to advance existing vascular graft solutions and improve vascular disease management.

ISSN

1546-1696

Published In/Presented At

Chen, G., Chung, T., Liu, Z., Li, Y. R., Scott, K., Zhao, X., Carol, J., Park, S., Zhou, Y., Kim, W. J., Ge, X., Colby, G. P., Li, S., & Chen, J. (2026). Hemodynamics-driven magnetoelastic vascular grafts for stenosis diagnosis. Nature biotechnology, 10.1038/s41587-025-02619-7. Advance online publication. https://doi.org/10.1038/s41587-025-02619-7

Disciplines

Medicine and Health Sciences

PubMedID

41667708

Department(s)

Department of Surgery

Document Type

Article