Functionality integration in stereolithography 3D printed microfluidics using a "print-pause-print" strategy.

Matthieu Sagot Timothée Derkenne Perrine Giunchi Yohan Davit Jean-Philippe Nougayrède Corentin Tregouet Vincent Raimbault Laurent Malaquin Bastien Venzac

Lab Chip

LAAS-CNRS, CNRS, 7 Avenue du Colonel Roche, 31400 Toulouse, France.

Published: July 2024

Stereolithography 3D printing is commonly used for creating microfluidic chips, but it usually only allows for a single-material construction.
By implementing a "print-pause-print" strategy, various materials can be incorporated during the printing process.
This innovative method enables the integration of diverse microfluidic functionalities, such as valves, filters, and imaging windows, enhancing the capabilities of the chips.

Stereolithography 3D printing, although an increasingly used fabrication method for microfluidic chips, has the main disadvantage of producing monolithic chips in a single material. We propose to incorporate during printing various objects using a "print-pause-print" strategy. Here, we demonstrate that this novel approach can be used to incorporate glass slides, hydrosoluble films, paper pads, steel balls, elastic or nanoporous membranes and silicon-based microdevices, in order to add microfluidic functionalities as diverse as valves, fluidic diodes, shallow chambers, imaging windows for bacteria tracking, storage of reagents, blue energy harvesting or filters for cell capture and culture.

Download full-text PDF	Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11235415	PMC
http://dx.doi.org/10.1039/d4lc00147h	DOI Listing

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Functionality integration in stereolithography 3D printed microfluidics using a "print-pause-print" strategy.

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Article Synopsis

Stereolithography 3D printing is commonly used for creating microfluidic chips, but it usually only allows for a single-material construction.
By implementing a "print-pause-print" strategy, various materials can be incorporated during the printing process.
This innovative method enables the integration of diverse microfluidic functionalities, such as valves, filters, and imaging windows, enhancing the capabilities of the chips.

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