Issue 19, 2024

Achieving biocompatibility and tailoring mechanical properties of SLA 3D printed devices for microfluidic and cell culture applications

Abstract

Stereolithography (SLA) and other photopolymerization-based additive manufacturing approaches are becoming popular for the fabrication of microfluidic devices and cell-infused platforms, but many of the resins employed in these techniques are cytotoxic to cells or do not have the appropriate mechanical properties for microfluidic components. Here, using a commercially available resin, we demonstrate that biocompatibility and a range of mechanical properties can be achieved through post-print optimization involving baking, soaking, network swelling, and UV exposure. We show that UV-vis spectrophotometry can be used to detect methacrylate monomer/oligomer, and utilizing this method, we found that baking at 120 °C for 24 hours was the optimal method for removing cytotoxic chemical species and creating nontoxic cell culture platforms, though UV exposure and soaking in 100% ethanol also can substantially reduce cytotoxicity. Furthermore, we show that the mechanical properties can be modified, including up to 50% for the Young's modulus and an order of magnitude for the flexural modulus, through the post-processing approach employed. Based on the study results, users can choose post-processing approaches to achieve needed cytotoxicity and mechanical profiles, simultaneously.

Graphical abstract: Achieving biocompatibility and tailoring mechanical properties of SLA 3D printed devices for microfluidic and cell culture applications

Article information

Article type
Paper
Submitted
24 Apr 2024
Accepted
22 Aug 2024
First published
27 Aug 2024

Lab Chip, 2024,24, 4632-4638

Achieving biocompatibility and tailoring mechanical properties of SLA 3D printed devices for microfluidic and cell culture applications

M. D. Nelson, P. A. Tresco, C. C. Yost and B. K. Gale, Lab Chip, 2024, 24, 4632 DOI: 10.1039/D4LC00354C

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