A Novel 3D‐Bioprinting Technology of Orderly Extruded Multi‐Materials via Photopolymerization

As a 3D bioprinting technique, digital light processing (DLP) has become popular due to its capability to provide high‐throughput and high‐resolution constructs with precise chemical and biological factor distributions. However, despite the advancements in DLP technology, several hurdles remain, inc...

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Bibliographic Details
Published in:Advanced materials technologies 2023-06, Vol.8 (12), p.n/a
Main Authors: Tavares‐Negrete, Jorge Alfonso, Babayigit, Ceren, Najafikoshnoo, Sahar, Lee, Sang Won, Boyraz, Ozdal, Esfandyarpour, Rahim
Format: Article
Language:English
Subjects:
3D‐bioprinting
biomaterials
digital light processing
multi‐material
photopolymerization
photopolymerization of orderly extruded multi‐materials
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Summary:As a 3D bioprinting technique, digital light processing (DLP) has become popular due to its capability to provide high‐throughput and high‐resolution constructs with precise chemical and biological factor distributions. However, despite the advancements in DLP technology, several hurdles remain, including phototoxicity, extensive printing time, and the limited portfolio of biocompatible/photo‐cross‐linkable materials. Recently, few works have attended to resolve some of these issues. However, state‐of‐the‐art techniques bear on complex imaging processing, require highly skilled personnel, and operate with non‐biocompatible/photo‐cross‐linkable materials. Additionally, they are not yet capable of multi‐layer and multi‐material printing of biocompatible/photo‐cross‐linkable materials to fabricate physiologically relevant cell‐laden structures. Herein, a novel DLP‐based 3D‐bioprinting technology called photopolymerization of orderly extruded multi‐materials (POEM), is proposed, developed, and fully characterized. The utility of the POEM technique for rapid and high‐resolution 3D‐printing of multi‐material, multi‐layer, and cell‐laden structures is demonstrated. The printed configurations show high cell viability (≈80%) and metabolic activity for more than 5 days. As a study model, a 3D‐structure representing the esophagus is also successfully printed and characterized. It is envisioned that the reported light‐based POEM technique here enables the fabrication of 3D‐cell‐laden structures in a multi‐material and multi‐layer printing manner in biocompatible/photo‐cross‐linkable materials essential to construct complex heterogeneous tissues/organs. This study introduces a novel light‐based 3D bioprinting approach named POEM (photopolymerization of orderly extruded multi‐materials). We demonstrate that POEM is capable of rapidly and precisely 3D printing complex structures with multiple materials and layers, high‐resolution, and live cells having a cell viability rate >80%. POEM holds great promise for creating diverse tissues and organs consisting of varied cell types.
ISSN:2365-709X
2365-709X
DOI:10.1002/admt.202201926