acib - Austrian Centre of Industrial Biotechnology, Muthgasse 11, Vienna 1190, Austria; Institute of Bioprocess Science and Engineering, Department of Biotechnology, University of Natural Resources and Life Sciences, Vienna (BOKU), Muthgasse 18, Vienna 1190, Austria.
Institute of Bioprocess Science and Engineering, Department of Biotechnology, University of Natural Resources and Life Sciences, Vienna (BOKU), Muthgasse 18, Vienna 1190, Austria.
J Biotechnol. 2024 Aug 10;391:33-39. doi: 10.1016/j.jbiotec.2024.06.001. Epub 2024 Jun 4.
3D printing has become widespread for the manufacture of parts in various industries and enabled radically new designs. This trend has not spread to bioprocess development yet, due to a lack of material suitable for the current workflow, including sterilization by autoclaving. This work demonstrates that commercially available heat temperature stable poly-lactic acid (PLA) can be used to easily manufacture novel bioreactor vessels with included features like harvest tubes and 3D printed spargers. Temperature responsiveness was tested for PLA, temperature stable PLA (PLA-HP) and glass for temperatures relevant for insect and mammalian cell culture, including temperature shifts within the process. Stability at 27 °C and 37 °C as well as temperature shifts to 22 °C and 32 °C showed acceptable performance with slightly higher temperature overshoot for 3D printed vessels. A stable temperature is reached after 2 h for PLA, 3 h for PLA-HP and 1 h for glass reactors. Temperature can be maintained with a fluctuation of 0.1 °C for all materials. A 3D printed sparger design directly integrated into the vessel wall and bottom was tested under three different conditions (0.3 SLPH and 27 °C, 3 SLPH and 37 °C and 13 SLPH and 37 °C). The 3D printed sparger showed a better ka than the L-Sparger with more pronounced differences for higher flowrates. An insect cell culture run in the novel vessel exhibited the same growth behavior as that in standard glass vessels, reaching the same maximum cell concentration. Being 3D printed from biodegradable materials, these bioreactors offer design flexibility for novel bioreactor formats. Additionally, their autoclavability allows seamless integration into standard workflows.
3D 打印已广泛用于制造各个行业的零件,并实现了全新的设计。由于缺乏适用于当前工作流程的材料,包括高压灭菌的灭菌方法,这种趋势尚未在生物工艺开发中得到普及。本工作证明,商业上可获得的热稳定性聚乳酸(PLA)可用于轻松制造具有包括收获管和 3D 打印曝气器等特色的新型生物反应器容器。测试了 PLA、温度稳定 PLA(PLA-HP)和玻璃在与昆虫和哺乳动物细胞培养相关的温度下的温度响应性,包括过程中的温度变化。在 27°C 和 37°C 下的稳定性以及在 22°C 和 32°C 的温度变化显示,3D 打印容器的温度超调略高,但性能可接受。PLA 达到稳定温度需要 2 小时,PLA-HP 需要 3 小时,玻璃反应器需要 1 小时。所有材料的温度都可以在波动 0.1°C 的情况下维持。直接集成在容器壁和底部的 3D 打印曝气器设计在三种不同条件下进行了测试(0.3 SLPH 和 27°C、3 SLPH 和 37°C 以及 13 SLPH 和 37°C)。3D 打印曝气器的 ka 值优于 L-曝气器,在较高流速下差异更为明显。在新型容器中进行的昆虫细胞培养表现出与标准玻璃容器相同的生长行为,达到相同的最大细胞浓度。由于这些生物反应器是用可生物降解的材料 3D 打印而成,因此为新型生物反应器格式提供了设计灵活性。此外,它们的可高压灭菌性允许无缝集成到标准工作流程中。
