Chemical analysis using 3D printed glass microfluidics

Research output: Contribution to journalArticleScientificpeer-review

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Chemical analysis using 3D printed glass microfluidics. / Gal-Or, Eran; Gershoni, Yaniv; Scotti, Gianmario; Nilsson, Sofia M.E.; Saarinen, Jukka; Jokinen, Ville; Strachan, Clare J.; Boije Af Gennäs, Gustav; Yli-Kauhaluoma, Jari; Kotiaho, Tapio.

In: ANALYTICAL METHODS, Vol. 11, No. 13, 07.04.2019, p. 1802-1810.

Research output: Contribution to journalArticleScientificpeer-review

Harvard

Gal-Or, E, Gershoni, Y, Scotti, G, Nilsson, SME, Saarinen, J, Jokinen, V, Strachan, CJ, Boije Af Gennäs, G, Yli-Kauhaluoma, J & Kotiaho, T 2019, 'Chemical analysis using 3D printed glass microfluidics' ANALYTICAL METHODS, vol. 11, no. 13, pp. 1802-1810. https://doi.org/10.1039/c8ay01934g

APA

Gal-Or, E., Gershoni, Y., Scotti, G., Nilsson, S. M. E., Saarinen, J., Jokinen, V., ... Kotiaho, T. (2019). Chemical analysis using 3D printed glass microfluidics. ANALYTICAL METHODS, 11(13), 1802-1810. https://doi.org/10.1039/c8ay01934g

Vancouver

Gal-Or E, Gershoni Y, Scotti G, Nilsson SME, Saarinen J, Jokinen V et al. Chemical analysis using 3D printed glass microfluidics. ANALYTICAL METHODS. 2019 Apr 7;11(13):1802-1810. https://doi.org/10.1039/c8ay01934g

Author

Gal-Or, Eran ; Gershoni, Yaniv ; Scotti, Gianmario ; Nilsson, Sofia M.E. ; Saarinen, Jukka ; Jokinen, Ville ; Strachan, Clare J. ; Boije Af Gennäs, Gustav ; Yli-Kauhaluoma, Jari ; Kotiaho, Tapio. / Chemical analysis using 3D printed glass microfluidics. In: ANALYTICAL METHODS. 2019 ; Vol. 11, No. 13. pp. 1802-1810.

Bibtex - Download

@article{1f6ab540393f459791f55c10a88e5ebd,
title = "Chemical analysis using 3D printed glass microfluidics",
abstract = "Additive manufacturing (3D printing) is a disruptive technology that is changing production systems globally. In addition, microfluidic devices are increasingly being used for chemical analysis and continuous production of chemicals. Printing of materials such as polymers and metals is already a reality, but additive manufacturing of glass for microfluidic systems has received minor attention. We characterize microfluidic devices (channel cross-section dimensions down to a scale of 100 μm) that have been produced by additive manufacturing of molten soda-lime glass in tens of minutes and report their mass spectrometric and Raman spectroscopic analysis examples. The functionality of a microfluidic glass microreactor is shown with online mass spectrometric analysis of linezolid synthesis. Additionally, the performance of a direct infusion device is demonstrated by mass spectrometric analysis of drugs. Finally, the excellent optical quality of the glass structures is demonstrated with in-line Raman spectroscopic measurements. Our results promise a bright future for additively manufactured glass microdevices in diverse fields of science.",
author = "Eran Gal-Or and Yaniv Gershoni and Gianmario Scotti and Nilsson, {Sofia M.E.} and Jukka Saarinen and Ville Jokinen and Strachan, {Clare J.} and {Boije Af Genn{\"a}s}, Gustav and Jari Yli-Kauhaluoma and Tapio Kotiaho",
year = "2019",
month = "4",
day = "7",
doi = "10.1039/c8ay01934g",
language = "English",
volume = "11",
pages = "1802--1810",
journal = "ANALYTICAL METHODS",
issn = "1759-9660",
publisher = "Royal Society of Chemistry",
number = "13",

}

RIS - Download

TY - JOUR

T1 - Chemical analysis using 3D printed glass microfluidics

AU - Gal-Or, Eran

AU - Gershoni, Yaniv

AU - Scotti, Gianmario

AU - Nilsson, Sofia M.E.

AU - Saarinen, Jukka

AU - Jokinen, Ville

AU - Strachan, Clare J.

AU - Boije Af Gennäs, Gustav

AU - Yli-Kauhaluoma, Jari

AU - Kotiaho, Tapio

PY - 2019/4/7

Y1 - 2019/4/7

N2 - Additive manufacturing (3D printing) is a disruptive technology that is changing production systems globally. In addition, microfluidic devices are increasingly being used for chemical analysis and continuous production of chemicals. Printing of materials such as polymers and metals is already a reality, but additive manufacturing of glass for microfluidic systems has received minor attention. We characterize microfluidic devices (channel cross-section dimensions down to a scale of 100 μm) that have been produced by additive manufacturing of molten soda-lime glass in tens of minutes and report their mass spectrometric and Raman spectroscopic analysis examples. The functionality of a microfluidic glass microreactor is shown with online mass spectrometric analysis of linezolid synthesis. Additionally, the performance of a direct infusion device is demonstrated by mass spectrometric analysis of drugs. Finally, the excellent optical quality of the glass structures is demonstrated with in-line Raman spectroscopic measurements. Our results promise a bright future for additively manufactured glass microdevices in diverse fields of science.

AB - Additive manufacturing (3D printing) is a disruptive technology that is changing production systems globally. In addition, microfluidic devices are increasingly being used for chemical analysis and continuous production of chemicals. Printing of materials such as polymers and metals is already a reality, but additive manufacturing of glass for microfluidic systems has received minor attention. We characterize microfluidic devices (channel cross-section dimensions down to a scale of 100 μm) that have been produced by additive manufacturing of molten soda-lime glass in tens of minutes and report their mass spectrometric and Raman spectroscopic analysis examples. The functionality of a microfluidic glass microreactor is shown with online mass spectrometric analysis of linezolid synthesis. Additionally, the performance of a direct infusion device is demonstrated by mass spectrometric analysis of drugs. Finally, the excellent optical quality of the glass structures is demonstrated with in-line Raman spectroscopic measurements. Our results promise a bright future for additively manufactured glass microdevices in diverse fields of science.

UR - http://www.scopus.com/inward/record.url?scp=85063593506&partnerID=8YFLogxK

U2 - 10.1039/c8ay01934g

DO - 10.1039/c8ay01934g

M3 - Article

VL - 11

SP - 1802

EP - 1810

JO - ANALYTICAL METHODS

JF - ANALYTICAL METHODS

SN - 1759-9660

IS - 13

ER -

ID: 32965167