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Photoinhibiting via simultaneous photoabsorption and free-radical reaction for high-fidelity light-based bioprinting

Author

Listed:
  • Ning He

    (National Engineering Research Centre for High Efficiency Grinding, Hunan University
    Hunan University)

  • Xiaonan Wang

    (College of Biology, Hunan University)

  • Liyang Shi

    (College of Biology, Hunan University)

  • Jing Li

    (National Engineering Research Centre for High Efficiency Grinding, Hunan University)

  • Lan Mo

    (Hunan Agricultural University)

  • Feng Chen

    (National Engineering Research Centre for High Efficiency Grinding, Hunan University)

  • Yuting Huang

    (Hunan University)

  • Hairong Liu

    (Hunan University)

  • Xiaolong Zhu

    (National Engineering Research Centre for High Efficiency Grinding, Hunan University)

  • Wei Zhu

    (National Engineering Research Centre for High Efficiency Grinding, Hunan University)

  • Yiqi Mao

    (National Engineering Research Centre for High Efficiency Grinding, Hunan University)

  • Xiaoxiao Han

    (National Engineering Research Centre for High Efficiency Grinding, Hunan University
    Hunan University)

Abstract

Light-based 3D bioprinting is now employed widely to fabricate geometrically complex constructs for various biomedical applications. However, the inherent light scattering defect creates significant challenges in patterning dilute hydrogels to form high-fidelity structures with fine-scale features. Herein, we introduce a photoinhibiting approach that can effectively suppress the light scattering effect via a mechanism of simultaneous photoabsorption and free-radical reaction. This biocompatible approach significantly improves the printing resolution (~1.2 - ~2.1 pixels depending on swelling) and shape fidelity (geometric error less than 5%), while minimising the costly trial-and-error procedures. The capability in patterning 3D complex constructs using different hydrogels is demonstrated by manufacturing various scaffolds featuring intricate multi-sized channels and thin-walled networks. Importantly, cellularised gyroid scaffolds (HepG2) are fabricated successfully, exhibiting high cell proliferation and functionality. The strategy established in this study promotes the printability and operability of light-based 3D bioprinting systems, allowing numerous new applications for tissue engineering.

Suggested Citation

  • Ning He & Xiaonan Wang & Liyang Shi & Jing Li & Lan Mo & Feng Chen & Yuting Huang & Hairong Liu & Xiaolong Zhu & Wei Zhu & Yiqi Mao & Xiaoxiao Han, 2023. "Photoinhibiting via simultaneous photoabsorption and free-radical reaction for high-fidelity light-based bioprinting," Nature Communications, Nature, vol. 14(1), pages 1-15, December.
  • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-38838-2
    DOI: 10.1038/s41467-023-38838-2
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    References listed on IDEAS

    as
    1. Soon Hee Kim & Yeung Kyu Yeon & Jung Min Lee & Janet Ren Chao & Young Jin Lee & Ye Been Seo & Md. Tipu Sultan & Ok Joo Lee & Ji Seung Lee & Sung-il Yoon & In-Sun Hong & Gilson Khang & Sang Jin Lee & J, 2018. "Publisher Correction: Precisely printable and biocompatible silk fibroin bioink for digital light processing 3D printing," Nature Communications, Nature, vol. 9(1), pages 1-2, December.
    2. Soon Hee Kim & Yeung Kyu Yeon & Jung Min Lee & Janet Ren Chao & Young Jin Lee & Ye Been Seo & Md. Tipu Sultan & Ok Joo Lee & Ji Seung Lee & Sung-il Yoon & In-Sun Hong & Gilson Khang & Sang Jin Lee & J, 2018. "Precisely printable and biocompatible silk fibroin bioink for digital light processing 3D printing," Nature Communications, Nature, vol. 9(1), pages 1-14, December.
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