Multidirectional Filamented Light Biofabrication Creates Aligned and Contractile Cardiac Tissues

Multidirectional Filamented Light Biofabrication Creates Aligned and Contractile Cardiac Tissues

Abstract Biofabricating 3D cardiac tissues that mimic the native myocardial tissue is a pivotal challenge in tissue engineering. In this study, we fabricate 3D cardiac tissues with controlled, multidirectional cellular alignment and directed or twisting contractility. We show that multidirectional f...

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Bibliographic Details
Main Authors: Lewis S. Jones, Miriam Filippi, Mike Yan Michelis, Aiste Balciunaite, Oncay Yasa, Gal Aviel, Maria Narciso, Susanne Freedrich, Melanie Generali, Eldad Tzahor, Robert K. Katzschmann
Format: Article
Language:English
Published: Wiley 2024-12-01
Series:Advanced Science
Subjects:
cardiac tissue engineering
cardiomyocytes
cell alignment
contractile tissues
volumetric bioprinting
Online Access:https://doi.org/10.1002/advs.202404509
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Summary:Abstract Biofabricating 3D cardiac tissues that mimic the native myocardial tissue is a pivotal challenge in tissue engineering. In this study, we fabricate 3D cardiac tissues with controlled, multidirectional cellular alignment and directed or twisting contractility. We show that multidirectional filamented light can be used to biofabricate high‐density (up to 60 × 106 cells mL−1) tissues, with directed uniaxial contractility (3.8x) and improved cell‐to‐cell connectivity (1.6x gap junction expression). Furthermore, by using multidirectional light projection, we can partially overcome cell‐induced light attenuation, and fabricate larger tissues with multidirectional cellular alignment. For example, we fabricate a tri‐layered myocardium‐like tissue and a bi‐layered tissue with torsional contractility. The approach provides a new strategy to rapidly fabricate aligned cardiac tissues relevant to regenerative medicine and biohybrid robotics.
ISSN:2198-3844

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