3D printed biosensor for continuous glucose measurement in cell cultures

Q3 Medicine

Annals of 3D printed medicine Pub Date : 2023-05-01 DOI:10.1016/j.stlm.2023.100111

Nenad Krstić , Jens Jüttner , Lars Giegerich , Margot Mayer , Monika Knuth , Achim Müller , Christiane Thielemann

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引用次数: 1

Abstract

A novel 3D-printed glucose sensor is presented for cell culture application. Glucose sensing was performed using a fluorescence resonance energy transfer (FRET)-based assay principle based on ConA and dextran. Both molecules are encapsulated in alginate microspheres and embedded in the UV-curable, stable hydrogel polyvinyl alcohol (PVA). The rheology of the formulation was adapted to obtain good properties for an extrusion-based printing process. The printed sensor structures were tested for their ability to detect glucose in vitro. A proportional increase in fluorescence intensity was observed in a concentration range of 0 - 2 g/L glucose. Tests with HEK cell cultures also showed good cell compatibility and excellent adhesion properties on plasma-treated Petri dishes. The printed sensors were able to detect the glucose decay associated with the metabolic activities of the fast-growing HEK cells in the cell culture medium over ten days. The proof-of-principle study shows that metabolic processes in cell cultures can be monitored with the new printed sensor using a standard fluorescence wide-field microscope.

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用于细胞培养中连续葡萄糖测量的3D打印生物传感器

提出了一种用于细胞培养的新型3d打印葡萄糖传感器。葡萄糖检测采用基于ConA和葡聚糖的荧光共振能量转移(FRET)检测原理。这两种分子都被封装在海藻酸盐微球中，并嵌入在可紫外光固化、稳定的水凝胶聚乙烯醇(PVA)中。该配方的流变学适应于获得良好的性能，挤出为基础的印刷工艺。对打印的传感器结构进行了体外检测葡萄糖的能力测试。在0 - 2 g/L葡萄糖浓度范围内，荧光强度呈比例增加。用HEK细胞培养物进行的测试也显示出良好的细胞相容性和在等离子处理的培养皿上的优异粘附性能。打印的传感器能够检测快速生长的HEK细胞在细胞培养基中10天以上与代谢活动相关的葡萄糖衰变。原理验证研究表明，细胞培养中的代谢过程可以用新的印刷传感器使用标准荧光宽视场显微镜进行监测。

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