Evaluation and optimization of PolyJet 3D-printed materials for cell culture studies

Use of 3D printing for microfluidics is a rapidly growing area, with applications involving cell culture in these devices also becoming of interest. 3D printing can be used to create custom-designed devices that have complex features and integrate different material types in one device; however, the...

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Bibliographic Details
Published in:Analytical and bioanalytical chemistry 2022-05, Vol.414 (11), p.3329-3339
Main Authors: Currens, Emily R., Armbruster, Michael R., Castiaux, Andre D., Edwards, James L., Martin, R. Scott
Format: Article
Language:English
Subjects:
3-D printers
3D printing
Analysis
Analytical Chemistry
Animals
Biochemistry
Cattle
Cell culture
Cell Culture Techniques
Cell density
Cell lines
Cell morphology
Characterization and Evaluation of Materials
Chemistry
Chemistry and Materials Science
Chromatography, Liquid
Culture
Cytology
Devices
Dogs
Endothelial Cells
Flasks
Food Science
Laboratory Medicine
Leachates
Methods
Microfluidics
Monitoring/Environmental Analysis
Optimization
Paper in Forefront
Printed materials
Printing
Printing, Three-Dimensional
Pulmonary arteries
Pulmonary artery
Sodium hydroxide
Sodium silicates
Substrates
Tandem Mass Spectrometry
Three dimensional printing
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Summary:Use of 3D printing for microfluidics is a rapidly growing area, with applications involving cell culture in these devices also becoming of interest. 3D printing can be used to create custom-designed devices that have complex features and integrate different material types in one device; however, there are fewer studies studying the ability to culture cells on the various substrates that are available. This work describes the effect of PolyJet 3D-printing technology on cell culture of two cell lines, bovine pulmonary artery endothelial cells (BPAECs) and Madin-Darby Canine Kidney (MDCK) cells, on two different types of printed materials (VeroClear or MED610). It was found that untreated devices, when used for studies of 1 day or more, led to unsuccessful culture. A variety of device treatment methodologies were investigated, with the most success coming from the use of sodium hydroxide/sodium metasilicate solution. Devices treated with this cleaning step resulted in culture of BPAECs and MDCK cells that were more similar to what is obtained in traditional culture flasks (in terms of cell morphology, viability, and cell density). LC–MS/MS analysis (via Orbitrap MS) was used to determine potential leachates from untreated devices. Finally, the use of a fiber scaffold in the devices was utilized to further evaluate the treatment methodology and to also demonstrate the ability to perform 3D culture in such devices. This study will be of use for researchers wanting to utilize these or other cell types in PolyJet-based 3D-printed devices.
ISSN:1618-2642
1618-2650
DOI:10.1007/s00216-022-03991-y