3D bioprinted multilayered cerebrovascular conduits to study cancer extravasation mechanism related with vascular geometry

Cerebral vessels are composed of highly complex structures that facilitate blood perfusion necessary for meeting the high energy demands of the brain. Their geometrical complexities alter the biophysical behavior of circulating tumor cells in the brain, thereby influencing brain metastasis. However,...

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Bibliographic Details
Published in:Nature communications 2023-11, Vol.14 (1), p.7696-7696, Article 7696
Main Authors: Park, Wonbin, Lee, Jae-Seong, Gao, Ge, Kim, Byoung Soo, Cho, Dong-Woo
Format: Article
Language:English
Subjects:
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Blood circulation
Blood vessels
Blood-brain barrier
Brain
Brain tumors
Cancer
Extravasation
Geometry
Humanities and Social Sciences
Hydrogels
Inflammation
Inflammatory response
Medical research
Metastases
Metastasis
Microenvironments
Molecular modelling
multidisciplinary
Prolongation
Science
Science (multidisciplinary)
Shear stress
Three dimensional printing
Tumor cells
Tumorigenesis
Tumors
Wall shear stresses
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Summary:Cerebral vessels are composed of highly complex structures that facilitate blood perfusion necessary for meeting the high energy demands of the brain. Their geometrical complexities alter the biophysical behavior of circulating tumor cells in the brain, thereby influencing brain metastasis. However, recapitulation of the native cerebrovascular microenvironment that shows continuities between vascular geometry and metastatic cancer development has not been accomplished. Here, we apply an in-bath 3D triaxial bioprinting technique and a brain-specific hybrid bioink containing an ionically crosslinkable hydrogel to generate a mature three-layered cerebrovascular conduit with varying curvatures to investigate the physical and molecular mechanisms of cancer extravasation in vitro. We show that more tumor cells adhere at larger vascular curvature regions, suggesting that prolongation of tumor residence time under low velocity and wall shear stress accelerates the molecular signatures of metastatic potential, including endothelial barrier disruption, epithelial–mesenchymal transition, inflammatory response, and tumorigenesis. These findings provide insights into the underlying mechanisms driving brain metastases and facilitate future advances in pharmaceutical and medical research. Geometrical complexities of blood vessels alter biophysical behaviors of circulating tumor cells, influencing cancer metastasis. Here, the authors develop a 3D bioprinted in vitro brain blood vessel-on-a-chip to investigate continuities between vascular geometry and metastatic cancer development.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-023-43586-4