Electrochemical monitoring the effect of drug intervention on PC12 cell damage model cultured on paper-PLA 3D printed device

Abstract

Three-dimensional (3D) cell culture system, as an alternative approach for traditional cell culture, attracts great attention because of physiological relevance and great microenvironment similarity to human conditions. Herein, a facile paper-polylactic (PLA) platform that was fabricated by wax printing and 3D printing, coupled with electrochemical sensor, was designed for the construction and intervention of 3D cell damage model. Pheochromocytoma cells (PC12) and bone marrow mesenchymal stem cells (BMSCs) were seeded on the paper-PLA 3D platforms and displayed the features of uniform distribution, good adhesion and perfect proliferation, as well as decreased circularity when compared to those grown on the two-dimensional (2D) interfaces. The electrochemical sensors revealed cell viability by monitoring dopamine released by cell models, ascertaining the applicability of the paper-PLA platform to a long-term 3D cell culture and drug assessment. Additionally, the results revealed that donepezil and BMSCs-secreted active molecules exhibited stronger cytoprotective effect against amyloid-beta oligomers-induced cell damage on the paper-PLA 3D printed platforms, indicating the cell damage model and the cell intervention model were achieved successfully in the simulated in vivo physiological microenvironment. Thus, the proposed paper-PLA platform may serve as a promising candidate for efficient drug screening and toxicity evaluation due to its simple structure, low cost, and convenient integration of 3D cell culture and activity evaluation.