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4D force patterning enables spatial control of angiogenesis.

Created on 07 Jul 2026

Authors

Sina Kheiri, Jessica Shah, Peiyuan Chai, Shashaank A Venkatesh, Ryan A Flynn, Roger D Kamm, Ritu Raman

Published in

Proceedings of the National Academy of Sciences of the United States of America. Volume 123. Issue 28. Pages e2532667123. Jul 14, 2026. Epub Jul 06, 2026.

Abstract

Engineering organized microvascular networks remains a critical challenge in tissue engineering and regenerative medicine. While biochemical approaches for patterning angiogenesis via growth factor delivery have shown promise, their inability to pattern sustained growth factors with spatiotemporal control limits effectiveness. Here, we demonstrate that dynamically patterned mechanical forces enable precise spatiotemporal control over angiogenic sprouting. We developed a magnetically actuated human vessel-on-a-chip platform that integrates a perfusable endothelialized microchannel within a collagen matrix and allows noninvasive and tunable mechanical stimulation across three spatial dimensions and time (4D). Using an automated 3-axis actuator, we systematically investigated how strain magnitude, frequency, and direction modulate endothelial cell behavior and vessel morphogenesis. Dynamic mechanical stimulation at physiological strain magnitudes (5 to 15%) enhanced endothelial alignment and barrier function while promoting angiogenesis in a strain magnitude-dependent manner: lower dynamic strain (5%) maximized sprout initiation, whereas higher dynamic strain (15%) promoted elongation of sprouts. Sequential reorientation of strain direction reprogrammed sprouting trajectories along X, Y, and Z directions, generating complex sprout geometries such as L-shaped branches. RNA sequencing revealed mechanically induced transcriptional profiles distinct from unstimulated controls, characterized by upregulation of genes associated with angiogenesis, mechanotransduction, and extracellular matrix remodeling. Functional perturbation of PIEZO1 reduced strain-induced sprouting without altering barrier function, indicating that dynamic mechanical stimulation engages multiple mechanotransduction pathways to regulate angiogenesis. Collectively, these findings establish a strategy for spatiotemporally controlled angiogenesis through 4D force patterning to program vascular morphogenesis while preserving function. This approach provides a foundation for engineering hierarchically organized vascular networks for tissue regeneration.

PMID:
42406945
Bibliographic data and abstract were imported from PubMed on 07 Jul 2026.

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