The Liberalization of Microfluidics: Form 2 Benchtop 3D Printing as an Affordable Alternative to Established Manufacturing Methods

Benjamin Heidt; Renato Rogosic; Silvio Bonni; Juliette Passariello-Jansen; David Dimech; Joe Lowdon; Rocio Arreguin-Campos; Erik Steen Redeker; Kasper Eersels; Hanne Dilien; Bart van Grinsven; Thomas J. Cleij

doi:10.1002/pssa.201900935

The Liberalization of Microfluidics: Form 2 Benchtop 3D Printing as an Affordable Alternative to Established Manufacturing Methods

Benjamin Heidt, Renato Rogosic^*, Silvio Bonni, Juliette Passariello-Jansen, David Dimech, Joe Lowdon, Rocio Arreguin-Campos, Erik Steen Redeker, Kasper Eersels, Hanne Dilien, Bart van Grinsven, Thomas J. Cleij

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

In laboratory environments, 3D printing is used for fast prototyping of assays and devices. Stereolithographic (SLA) 3D printers are proven to be the best choice for most researchers due to their small feature size, which is achieved by selectively curing liquid resin using a laser with a small focal point and then forming consecutive layers out of cured polymer. However, in microfluidic applications, where the limits of these machines are reached, the final results are influenced by many factors. In this work, the Form 2 SLA printer is tested to show how to achieve the best printing results for the creation of microfluidic channels. Several test structures are designed and printed with embedded and open channels in different orientations, sizes, and resins. Embedded channels significantly under perform when compared with open surface channels in terms of accuracy. Under the best printing conditions, 500 mu m is the limit for embedded channels, whereas the open surface channels show good accuracy up to widths and depths of 250 mu m.

Original language	English
Article number	1900935
Number of pages	7
Journal	Physica Status Solidi A-applications and Materials Science
Volume	217
Issue number	13
DOIs	https://doi.org/10.1002/pssa.201900935
Publication status	Published - Jul 2020

Keywords

Form 2
Formlabs
microfluidics
3D printing

Access to Document

10.1002/pssa.201900935Licence: CC BY-NC-ND

Cite this

Heidt, B., Rogosic, R., Bonni, S., Passariello-Jansen, J., Dimech, D., Lowdon, J., Arreguin-Campos, R., Steen Redeker, E., Eersels, K., Dilien, H., van Grinsven, B., & Cleij, T. J. (2020). The Liberalization of Microfluidics: Form 2 Benchtop 3D Printing as an Affordable Alternative to Established Manufacturing Methods. Physica Status Solidi A-applications and Materials Science, 217(13), Article 1900935. https://doi.org/10.1002/pssa.201900935

@article{1694fd9d73ea4ffeabe03a89f6daebc1,

title = "The Liberalization of Microfluidics: Form 2 Benchtop 3D Printing as an Affordable Alternative to Established Manufacturing Methods",

abstract = "In laboratory environments, 3D printing is used for fast prototyping of assays and devices. Stereolithographic (SLA) 3D printers are proven to be the best choice for most researchers due to their small feature size, which is achieved by selectively curing liquid resin using a laser with a small focal point and then forming consecutive layers out of cured polymer. However, in microfluidic applications, where the limits of these machines are reached, the final results are influenced by many factors. In this work, the Form 2 SLA printer is tested to show how to achieve the best printing results for the creation of microfluidic channels. Several test structures are designed and printed with embedded and open channels in different orientations, sizes, and resins. Embedded channels significantly under perform when compared with open surface channels in terms of accuracy. Under the best printing conditions, 500 mu m is the limit for embedded channels, whereas the open surface channels show good accuracy up to widths and depths of 250 mu m.",

keywords = "Form 2, Formlabs, microfluidics, 3D printing",

author = "Benjamin Heidt and Renato Rogosic and Silvio Bonni and Juliette Passariello-Jansen and David Dimech and Joe Lowdon and Rocio Arreguin-Campos and {Steen Redeker}, Erik and Kasper Eersels and Hanne Dilien and {van Grinsven}, Bart and Cleij, {Thomas J.}",

note = "Funding Information: B.H. and R.R. contributed equally to this work. The authors are grateful for the financial support received from Universiteitsfonds Limburg,SWOL and Province of Limburg, LiMe. Publisher Copyright: {\textcopyright} 2020 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim",

year = "2020",

month = jul,

doi = "10.1002/pssa.201900935",

language = "English",

volume = "217",

journal = "Physica Status Solidi A-applications and Materials Science",

issn = "1862-6300",

publisher = "Wiley-VCH Verlag",

number = "13",

}

Heidt, B, Rogosic, R, Bonni, S, Passariello-Jansen, J, Dimech, D, Lowdon, J , Arreguin-Campos, R , Steen Redeker, E , Eersels, K , Dilien, H , van Grinsven, B & Cleij, TJ 2020, 'The Liberalization of Microfluidics: Form 2 Benchtop 3D Printing as an Affordable Alternative to Established Manufacturing Methods', Physica Status Solidi A-applications and Materials Science, vol. 217, no. 13, 1900935. https://doi.org/10.1002/pssa.201900935

TY - JOUR

T1 - The Liberalization of Microfluidics

T2 - Form 2 Benchtop 3D Printing as an Affordable Alternative to Established Manufacturing Methods

AU - Heidt, Benjamin

AU - Rogosic, Renato

AU - Bonni, Silvio

AU - Passariello-Jansen, Juliette

AU - Dimech, David

AU - Lowdon, Joe

AU - Arreguin-Campos, Rocio

AU - Steen Redeker, Erik

AU - Eersels, Kasper

AU - Dilien, Hanne

AU - van Grinsven, Bart

AU - Cleij, Thomas J.

N1 - Funding Information: B.H. and R.R. contributed equally to this work. The authors are grateful for the financial support received from Universiteitsfonds Limburg,SWOL and Province of Limburg, LiMe. Publisher Copyright: © 2020 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

PY - 2020/7

Y1 - 2020/7

N2 - In laboratory environments, 3D printing is used for fast prototyping of assays and devices. Stereolithographic (SLA) 3D printers are proven to be the best choice for most researchers due to their small feature size, which is achieved by selectively curing liquid resin using a laser with a small focal point and then forming consecutive layers out of cured polymer. However, in microfluidic applications, where the limits of these machines are reached, the final results are influenced by many factors. In this work, the Form 2 SLA printer is tested to show how to achieve the best printing results for the creation of microfluidic channels. Several test structures are designed and printed with embedded and open channels in different orientations, sizes, and resins. Embedded channels significantly under perform when compared with open surface channels in terms of accuracy. Under the best printing conditions, 500 mu m is the limit for embedded channels, whereas the open surface channels show good accuracy up to widths and depths of 250 mu m.

AB - In laboratory environments, 3D printing is used for fast prototyping of assays and devices. Stereolithographic (SLA) 3D printers are proven to be the best choice for most researchers due to their small feature size, which is achieved by selectively curing liquid resin using a laser with a small focal point and then forming consecutive layers out of cured polymer. However, in microfluidic applications, where the limits of these machines are reached, the final results are influenced by many factors. In this work, the Form 2 SLA printer is tested to show how to achieve the best printing results for the creation of microfluidic channels. Several test structures are designed and printed with embedded and open channels in different orientations, sizes, and resins. Embedded channels significantly under perform when compared with open surface channels in terms of accuracy. Under the best printing conditions, 500 mu m is the limit for embedded channels, whereas the open surface channels show good accuracy up to widths and depths of 250 mu m.

KW - Form 2

KW - Formlabs

KW - microfluidics

KW - 3D printing

U2 - 10.1002/pssa.201900935

DO - 10.1002/pssa.201900935

M3 - Article

SN - 1862-6300

VL - 217

JO - Physica Status Solidi A-applications and Materials Science

JF - Physica Status Solidi A-applications and Materials Science

IS - 13

M1 - 1900935

ER -