Multiscale Embedded Printing of Engineered Human Tissue and Organ Equivalents

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2024 Feb 12

PMID 38346211

Authors

Cheng Zhang

Weijian Hua

Kellen Mitchell

Lily Raymond

Fatemeh Delzendehrooy

Lai Wen

Changwoo Do

Jihua Chen

Ying Yang

Gabe Linke

Zhengyi Zhang

Mena Asha Krishnan

Mitchell Kuss

Ryan Coulter

Erick Bandala

Yiliang Liao

Bin Duan

Danyang Zhao

Guangrui Chai

Yifei Jin

Affiliations

Soon will be listed here.

Abstract

Creating tissue and organ equivalents with intricate architectures and multiscale functional feature sizes is the first step toward the reconstruction of transplantable human tissues and organs. Existing embedded ink writing approaches are limited by achievable feature sizes ranging from hundreds of microns to tens of millimeters, which hinders their ability to accurately duplicate structures found in various human tissues and organs. In this study, a multiscale embedded printing (MSEP) strategy is developed, in which a stimuli-responsive yield-stress fluid is applied to facilitate the printing process. A dynamic layer height control method is developed to print the cornea with a smooth surface on the order of microns, which can effectively overcome the layered morphology in conventional extrusion-based three-dimensional bioprinting methods. Since the support bath is sensitive to temperature change, it can be easily removed after printing by tuning the ambient temperature, which facilitates the fabrication of human eyeballs with optic nerves and aortic heart valves with overhanging leaflets on the order of a few millimeters. The thermosensitivity of the support bath also enables the reconstruction of the full-scale human heart on the order of tens of centimeters by on-demand adding support bath materials during printing. The proposed MSEP demonstrates broader printable functional feature sizes ranging from microns to centimeters, providing a viable and reliable technical solution for tissue and organ printing in the future.

Citing Articles

Engineering cardiology with miniature hearts.

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