Electric‐Field‐Driven Printed 3D Highly Ordered Microstructure with Cell Feature Size Promotes the Maturation of Engineered Cardiac Tissues

Engineered cardiac tissues (ECTs) derived from human induced pluripotent stem cells (hiPSCs) are viable alternatives for cardiac repair, patient‐specific disease modeling, and drug discovery. However, the immature state of ECTs limits their clinical utility. The microenvironment fabricated using 3D...

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Bibliographic Details
Published in:Advanced science 2023-04, Vol.10 (11), p.e2206264-n/a
Main Authors: Zhang, Guangming, Li, Wenhai, Yu, Miao, Huang, Hui, Wang, Yaning, Han, Zhifeng, Shi, Kai, Ma, Lingxuan, Yu, Zhihao, Zhu, Xiaoyang, Peng, Zilong, Xu, Yue, Li, Xiaoyun, Hu, Shijun, He, Jiankang, Li, Dichen, Xi, Yongming, Lan, Hongbo, Xu, Lin, Tang, Mingliang, Xiao, Miao
Format: Article
Language:English
Subjects:
3-D printers
3D highly ordered microstructure
Cardiomyocytes
Cardiovascular disease
Cell Differentiation
cell feature size
Electric fields
electric‐field‐driven
Electrodes
engineered cardiac tissues
Glass substrates
Humans
Induced Pluripotent Stem Cells
Microstructure
Morphology
Myocytes, Cardiac
Printing, Three-Dimensional
small fiber spacing
Tissue engineering
Tissue Engineering - methods
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Summary:Engineered cardiac tissues (ECTs) derived from human induced pluripotent stem cells (hiPSCs) are viable alternatives for cardiac repair, patient‐specific disease modeling, and drug discovery. However, the immature state of ECTs limits their clinical utility. The microenvironment fabricated using 3D scaffolds can affect cell fate, and is crucial for the maturation of ECTs. Herein, the authors demonstrate an electric‐field‐driven (EFD) printed 3D highly ordered microstructure with cell feature size to promote the maturation of ECTs. The simulation and experimental results demonstrate that the EFD jet microscale 3D printing overcomes the jet repulsion without any prior requirements for both conductive and insulating substrates. Furthermore, the 3D highly ordered microstructures with a fiber diameter of 10–20 µm and spacing of 60–80 µm have been fabricated by maintaining a vertical jet, achieving the largest ratio of fiber diameter/spacing of 0.29. The hiPSCs‐derived cardiomyocytes formed ordered ECTs with their sarcomere growth along the fiber and developed synchronous functional ECTs inside the 3D‐printed scaffold with matured calcium handling compared to the 2D coverslip. Therefore, the EFD jet 3D microscale printing process facilitates the fabrication of scaffolds providing a suitable microenvironment to promote the maturation of ECTs, thereby showing great potential for cardiac tissue engineering. A simple, and efficient strategy using electric‐field‐driven jet microscale 3D printing to fabricate 3D highly ordered microstructures with both the fiber width and fiber spacing that match myocardial feature sizes is first developed to build engineered cardiac tissues (ECTs) with hiPSC‐CMs. The myocardial feature‐sized structure promoted the maturation of ECTs, thereby showing great potential for cardiac tissue engineering.
ISSN:2198-3844
2198-3844
DOI:10.1002/advs.202206264