3D printing biocompatible materials with multi jet fusion for bioreactor applications
In the evolving three-dimensional (3D) printing technology, the involvement of different materials in any new 3D printing process necessitates a thorough evaluation of the product's biocompatibility for biomedical application. Here, we examined the ability of Multi Jet Fusion (MJF)-printed PA-1...
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sg-ntu-dr.10356-1646412023-02-07T04:53:35Z 3D printing biocompatible materials with multi jet fusion for bioreactor applications Priyadarshini, Balasankar Meera Kok, Wai Kay Dikshit, Vishwesh Feng, Shilun Li, Holden King Ho Zhang, Yi School of Mechanical and Aerospace Engineering School of Electrical and Electronic Engineering HP-NTU Digital Manufacturing Corporate Lab Engineering::Mechanical engineering Multi Jet Fusion Bacteria Fouling In the evolving three-dimensional (3D) printing technology, the involvement of different materials in any new 3D printing process necessitates a thorough evaluation of the product's biocompatibility for biomedical application. Here, we examined the ability of Multi Jet Fusion (MJF)-printed PA-12 to support cell proliferation and osteogenesis. Our results show that leachate from MJF-printed PA-12 does not inhibit the growth of L929 fibroblast and MC3T3e1 osteoblast. The substrate supports the attachment and proliferation of both cell types, though not at a level comparable to conventional polystyrene culture plate. Neither plasma treatment, poly-D-lysine, nor collagen coatings narrowed the gap substantially, suggesting the possible influence of other limiting factors. The substrate can also support MC3T3e1 osteogenesis. However, MJF-printed PA-12 exhibits varying ability in supporting the proliferation of different cell types, especially in subsequent passages. While L929's proliferation is comparable from passage-to-passage, MC3T3e1's growth ability is noticeably compromised. Interestingly, our results show that L929 subcultured back to polystyrene plate retains the ability to grow as robustly as those on the conventional plate, suggesting that MJF-printed PA-12 does not permanently impair cell proliferation. In addition, we have shown the successful culture of bacterial Escherichia coli on MJF-printed PA-12. Together, our study demonstrated the potential of MJF-printed PA-12 for biological applications. Published version This research was conducted in collaboration with HP Inc. and supported/partially supported by the Singapore Government through the Industry Alignment Fund-Industry Collaboration Projects Grant. 2023-02-07T04:53:35Z 2023-02-07T04:53:35Z 2023 Journal Article Priyadarshini, B. M., Kok, W. K., Dikshit, V., Feng, S., Li, H. K. H. & Zhang, Y. (2023). 3D printing biocompatible materials with multi jet fusion for bioreactor applications. International Journal of Bioprinting, 9(1), 14-35. https://dx.doi.org/10.18063/ijb.v9i1.623 2424-7723 https://hdl.handle.net/10356/164641 10.18063/ijb.v9i1.623 36636131 2-s2.0-85141775556 1 9 14 35 en International Journal of Bioprinting © 2022 Author(s). This is an Open Access article distributed under the terms of the Creative Commons Attribution License, permitting distribution, and reproduction in any medium, provided the original work is properly cited. application/pdf |
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Engineering::Mechanical engineering Multi Jet Fusion Bacteria Fouling Priyadarshini, Balasankar Meera Kok, Wai Kay Dikshit, Vishwesh Feng, Shilun Li, Holden King Ho Zhang, Yi 3D printing biocompatible materials with multi jet fusion for bioreactor applications |
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In the evolving three-dimensional (3D) printing technology, the involvement of different materials in any new 3D printing process necessitates a thorough evaluation of the product's biocompatibility for biomedical application. Here, we examined the ability of Multi Jet Fusion (MJF)-printed PA-12 to support cell proliferation and osteogenesis. Our results show that leachate from MJF-printed PA-12 does not inhibit the growth of L929 fibroblast and MC3T3e1 osteoblast. The substrate supports the attachment and proliferation of both cell types, though not at a level comparable to conventional polystyrene culture plate. Neither plasma treatment, poly-D-lysine, nor collagen coatings narrowed the gap substantially, suggesting the possible influence of other limiting factors. The substrate can also support MC3T3e1 osteogenesis. However, MJF-printed PA-12 exhibits varying ability in supporting the proliferation of different cell types, especially in subsequent passages. While L929's proliferation is comparable from passage-to-passage, MC3T3e1's growth ability is noticeably compromised. Interestingly, our results show that L929 subcultured back to polystyrene plate retains the ability to grow as robustly as those on the conventional plate, suggesting that MJF-printed PA-12 does not permanently impair cell proliferation. In addition, we have shown the successful culture of bacterial Escherichia coli on MJF-printed PA-12. Together, our study demonstrated the potential of MJF-printed PA-12 for biological applications. |
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School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Priyadarshini, Balasankar Meera Kok, Wai Kay Dikshit, Vishwesh Feng, Shilun Li, Holden King Ho Zhang, Yi |
| format |
Article |
| author |
Priyadarshini, Balasankar Meera Kok, Wai Kay Dikshit, Vishwesh Feng, Shilun Li, Holden King Ho Zhang, Yi |
| author_sort |
Priyadarshini, Balasankar Meera |
| title |
3D printing biocompatible materials with multi jet fusion for bioreactor applications |
| title_short |
3D printing biocompatible materials with multi jet fusion for bioreactor applications |
| title_full |
3D printing biocompatible materials with multi jet fusion for bioreactor applications |
| title_fullStr |
3D printing biocompatible materials with multi jet fusion for bioreactor applications |
| title_full_unstemmed |
3D printing biocompatible materials with multi jet fusion for bioreactor applications |
| title_sort |
3d printing biocompatible materials with multi jet fusion for bioreactor applications |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/164641 |
| _version_ |
1759058800931766272 |