Literature DB >> 35890735

Development of a Custom-Made 3D Printing Protocol with Commercial Resins for Manufacturing Microfluidic Devices.

Francesc Subirada1, Roberto Paoli1, Jessica Sierra-Agudelo1, Anna Lagunas1,2, Romen Rodriguez-Trujillo1,3, Josep Samitier1,2,3.   

Abstract

The combination of microfluidics and photo-polymerization techniques such as stereolithography (SLA) has emerged as a new field which has a lot of potential to influence in such important areas as biological analysis, and chemical detection among others. However, the integration between them is still at an early stage of development. In this article, after analyzing the resolution of a custom SLA 3D printer with commercial resins, microfluidic devices were manufactured using three different approaches. First, printing a mold with the objective of creating a Polydimethylsiloxane (PDMS) replica with the microfluidic channels; secondly, open channels have been printed and then assembled with a flat cover of the same resin material. Finally, a closed microfluidic device has also been produced in a single process of printing. Important results for 3D printing with commercial resins have been achieved by only printing one layer on top of the channel. All microfluidic devices have been tested successfully for pressure-driven fluid flow.

Entities:  

Keywords:  3D printing; additive manufacturing; microfluidics; photo-curable polymers; stereolithography

Year:  2022        PMID: 35890735      PMCID: PMC9322100          DOI: 10.3390/polym14142955

Source DB:  PubMed          Journal:  Polymers (Basel)        ISSN: 2073-4360            Impact factor:   4.967


  14 in total

Review 1.  The origins and the future of microfluidics.

Authors:  George M Whitesides
Journal:  Nature       Date:  2006-07-27       Impact factor: 49.962

Review 2.  Inertial microfluidics.

Authors:  Dino Di Carlo
Journal:  Lab Chip       Date:  2009-09-22       Impact factor: 6.799

3.  3D Printed Microfluidic Mixers-A Comparative Study on Mixing Unit Performances.

Authors:  Anton Enders; Ina G Siller; Katharina Urmann; Michael R Hoffmann; Janina Bahnemann
Journal:  Small       Date:  2018-12-10       Impact factor: 13.281

Review 4.  Increasing the functionalities of 3D printed microchemical devices by single material, multimaterial, and print-pause-print 3D printing.

Authors:  Feng Li; Niall P Macdonald; Rosanne M Guijt; Michael C Breadmore
Journal:  Lab Chip       Date:  2018-12-18       Impact factor: 6.799

5.  High-Precision Stereolithography of Biomicrofluidic Devices.

Authors:  Alexandra P Kuo; Nirveek Bhattacharjee; Yuan-Sheng Lee; Kurt Castro; Yong Tae Kim; Albert Folch
Journal:  Adv Mater Technol       Date:  2019-01-03

Review 6.  3D printed microfluidic devices: enablers and barriers.

Authors:  Sidra Waheed; Joan M Cabot; Niall P Macdonald; Trevor Lewis; Rosanne M Guijt; Brett Paull; Michael C Breadmore
Journal:  Lab Chip       Date:  2016-05-24       Impact factor: 6.799

7.  Comparing Microfluidic Performance of Three-Dimensional (3D) Printing Platforms.

Authors:  Niall P Macdonald; Joan M Cabot; Petr Smejkal; Rosanne M Guijt; Brett Paull; Michael C Breadmore
Journal:  Anal Chem       Date:  2017-03-24       Impact factor: 6.986

Review 8.  3D-Printed Microfluidics.

Authors:  Anthony K Au; Wilson Huynh; Lisa F Horowitz; Albert Folch
Journal:  Angew Chem Int Ed Engl       Date:  2016-02-08       Impact factor: 15.336

9.  Mail-order microfluidics: evaluation of stereolithography for the production of microfluidic devices.

Authors:  Anthony K Au; Wonjae Lee; Albert Folch
Journal:  Lab Chip       Date:  2014-04-07       Impact factor: 6.799

10.  Isolation and retrieval of circulating tumor cells using centrifugal forces.

Authors:  Han Wei Hou; Majid Ebrahimi Warkiani; Bee Luan Khoo; Zi Rui Li; Ross A Soo; Daniel Shao-Weng Tan; Wan-Teck Lim; Jongyoon Han; Ali Asgar S Bhagat; Chwee Teck Lim
Journal:  Sci Rep       Date:  2013-02-12       Impact factor: 4.379
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