Sage Journals: Discover world-class research

Abstract

Paper-based microfluidics broadens the use of point-of-care devices to applications and situations wherein cost is an important restriction. This study focuses on the REPRAP PRUSA i3 Printer that can print itself a part that combined with an infusion pump extends the capabilities of this printer, which can now create different types of hydrophobic patterns on an abundant, renewable substrate: paper. Different flow rates of the syringe pump and printing velocities are combined to optimize the resolution of this new manufacturing process. Besides different papers are used to print patterns to either check the influence of the paper type on the printing resolution or to choose the more suitable paper to build blood typing assays. The resolution improves decreasing flow rate and increasing printing velocity to a minimum value ∼10% higher than the needle diameter. The printer working with a G25 needle prints microfluidic patterns that can be used to evaluate the blood type on different types of chromatographic papers. Two blood types (A− and O−) are evaluated with this new approach with results equivalent to traditional methods, validating its feasibility in clinical practice. This novel printing method for paper-based microfluidics manufacturing does not require specialized equipment or skills, it is fast and inexpensive, and thus can help to introduce the advantage of healthcare in areas where access to health systems is not guaranteed.

Get full access to this article

View all access options for this article.

References

Jones

, et al. RepRap—The replicating rapid prototyper. Robotica, 2011; 29:177–191.

RepRapGPLLicence—RepRapWiki. [Online]. Available: http://reprap.org/wiki/RepRapGPLLicence Accessed May 11, 2017.

Martinez

, Phillips

, Butte

, Whitesides

. Patterned paper as a platform for inexpensive, low-volume, portable bioassays. Angew Chemie Int Ed, 2007; 46:1318–1320.

, Tian

, Ballerini

, Li

, Shen

. A study of the transport and immobilisation mechanisms of human red blood cells in a paper-based blood typing device using confocal microscopy. Analyst, 2013; 138:4933.

, Tian

, Al-Tamimi

, Shen

. Paper-based blood typing device that reports patient's blood type ‘in writing’. Angew Chemie Int Ed, 2012; 51:5497–5501.

Martinez

, Phillips

, Wiley

, Gupta

, Whitesides

. FLASH: A rapid method for prototyping paper-based microfluidic devices. Lab Chip, 2008; 8:2146.

Martinez

, Phillips

, Carrilho

, Thomas

, Sindi

, Whitesides

. Simple telemedicine for developing regions: Camera phones and paper-based microfluidic devices for real-time, off-site diagnosis. Anal Chem, 2008; 80:3699–3707.

Nilghaz

, Guan

, Tan

, Shen

. Advances of paper-based microfluidics for diagnostics—The original motivation and current status. ACS Sensors, 2016; 1:1382–1393.

Sharma

, Zapatero-Rodríguez

, Estrela

, O'Kennedy

. Point-of-care diagnostics in low resource settings: Present status and future role of microfluidics. Biosensors, 2015; 5:577–601.

10.

Mohammadi

, Madadi

, Casals-Terré

. Microfluidic point-of-care blood panel based on a novel technique: Reversible electroosmotic flow. Biomicrofluidics, 2015; 9:054106.

11.

Madadi

, Casals-Terré

, Mohammadi

. Self-driven filter-based blood plasma separator microfluidic chip for point-of-care testing. Biofabrication, 2015; 7:25007.

12.

Carrilho

, Martinez

, Whitesides

. Understanding wax printing: A simple micropatterning process for paper-based microfluidics. Anal Chem, 2009; 81:7091–7095.

13.

, Shi

, Jiang

, Qin

, Lin

. Rapid prototyping of paper-based microfluidics with wax for low-cost, portable bioassay. Electrophoresis, 2009; 30:1497–1500.

14.

, Tian

, Nguyen

, Shen

. Paper-based microfluidic devices by plasma treatment. Anal Chem, 2008; 80:9131–9134.

15.

Fenton

, Mascarenas

, López

, Sibbett

. Multiplex lateral-flow test strips fabricated by two-dimensional shaping. ACS Appl Mater Interfaces, 2009; 1:124–129.

16.

, Lutz

, Kauffman

, Yager

. Controlled reagent transport in disposable 2D paper networks. Lab Chip, 2010; 10:918–920.

17.

Olkkonen

, Lehtinen

, Erho

. Flexographically printed fluidic structures in paper. Anal Chem, 2010; 82:10246–10250.

18.

Maejima

, Tomikawa

, Suzuki

, Citterio

, Shen

G-L

, Yu

R-Q

. Inkjet printing: An integrated and green chemical approach to microfluidic paper-based analytical devices. RSC Adv, 2013; 3:9258.

19.

Pearce

, Anzalone

, Heldt

. Open-Source Wax RepRap 3-D Printer for rapid prototyping paper-based microfluidics. J Lab Autom, 2016; 21:510–516.

20.

Lisowski

, Zarzycki

. Microfluidic paper-based analytical devices (μPADs) and micro total analysis systems (μTAS): Development, applications and future trends. Chromatographia, 2013; 76:1201–1214.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

8.62 MB

REPlicating RAPid Microfluidics: Self-Replicating Printer for Hydrophobic Pattern Deposition

Abstract

Abstract

Get full access to this article

References

Supplementary Material