Imaging‐Guided Microscale Photothermal Stereolithography Bioprinting

Imaging‐Guided Microscale Photothermal Stereolithography Bioprinting

Abstract Stereolithography bioprinting relies heavily on costly photoinitiators for polymerization, limiting its potential for further technical advancement to meet growing needs in tissue engineering and regenerative medicine. Thermal initiators, in contrast, are low cost, and rapid growth of the p...

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Bibliographic Details
Main Authors: Jingyu Sun, Tianqi Fang, Yuze Zhang, Jue Wang, Huan Han, Tsengming Chou, Junfeng Liang, Dilhan M. Kalyon, Hongjun Wang, Shang Wang
Format: Article
Language:English
Published: Wiley 2025-05-01
Series:Advanced Science
Subjects:
bioprinting
imaging‐guided printing
optical coherence tomography
NIR‐II photothermal initiator
stereolithography
Online Access:https://doi.org/10.1002/advs.202500640
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Summary:Abstract Stereolithography bioprinting relies heavily on costly photoinitiators for polymerization, limiting its potential for further technical advancement to meet growing needs in tissue engineering and regenerative medicine. Thermal initiators, in contrast, are low cost, and rapid growth of the photothermal conversion field offers a wide range of materials and tools to convert light into heat. However, high‐resolution photothermal stereolithography bioprinting remains unattainable due to the difficulty of confining heat in an aqueous environment. Here, this challenge has been fully addressed by establishing imaging‐guided microscale photothermal stereolithography bioprinting (ImPSB). This technique is achieved through building a novel imaging‐guided stereolithography system that provides depth‐resolved visualization of the printing dynamics, creating a unique photothermal initiator in the second near‐infrared window, and developing a new bioink by seeing and controlling the photothermal gelation process. ImPSB achieves a printing resolution of ≈47 µm and generates smooth lines of arbitrarily designed shapes with a cross‐sectional diameter as small as ≈104 µm, representing an unprecedented scale from photothermal aqueous stereolithography. Its cellular biocompatibility in printing both bioscaffold and cell‐laden hydrogel is demonstrated, and its feasibility of transdermal printing is also shown. This work sets a new path for high‐resolution stereolithography bioprinting where the vast photothermal resources can be utilized.
ISSN:2198-3844

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