Literature DB >> 32829631

3D Printed Microfluidic Devices for Solid-Phase Extraction and On-Chip Fluorescent Labeling of Preterm Birth Risk Biomarkers.

Anna V Bickham1, Chao Pang1, Benjamin Q George1, David J Topham1, Jacob B Nielsen1, Gregory P Nordin2, Adam T Woolley1.   

Abstract

Solid-phase extraction (SPE) is a general preconcentration method for sample preparation that can be performed on a variety of specimens. The miniaturization of SPE within a 3D printed microfluidic device further allows for fast and simple extraction of analytes while also enabling integration of SPE with other sample preparation and separation methods. Here, we present the development and application of a reversed-phase lauryl methacrylate-based monolith, formed in 3D printed microfluidic devices, which can selectively retain peptides and proteins. The effectiveness of these SPE monoliths and 3D printed microfluidic devices was tested using a panel of nine preterm birth biomarkers of varying hydrophobicities and ranging in mass from 2 to 470 kDa. The biomarkers were selectively retained, fluorescently labeled, and eluted separately from the excess fluorescent label in 3D printed microfluidic systems. These are the first results demonstrating microfluidic analysis processes on a complete panel of preterm birth biomarkers, an important step toward developing a miniaturized, fully integrated analysis system.

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Year:  2020        PMID: 32829631      PMCID: PMC7494619          DOI: 10.1021/acs.analchem.0c01970

Source DB:  PubMed          Journal:  Anal Chem        ISSN: 0003-2700            Impact factor:   6.986


  36 in total

Review 1.  Microfluidic sensing: state of the art fabrication and detection techniques.

Authors:  Jing Wu; Min Gu
Journal:  J Biomed Opt       Date:  2011-08       Impact factor: 3.170

2.  Extraction of nucleic acids from blood: unveiling the potential of active pneumatic pumping in centrifugal microfluidics for integration and automation of sample preparation processes.

Authors:  Daniel Brassard; Matthias Geissler; Marianne Descarreaux; Dominic Tremblay; Jamal Daoud; Liviu Clime; Maxence Mounier; Denis Charlebois; Teodor Veres
Journal:  Lab Chip       Date:  2019-04-18       Impact factor: 6.799

Review 3.  Polymerase chain reaction in microfluidic devices.

Authors:  Christian D Ahrberg; Andreas Manz; Bong Geun Chung
Journal:  Lab Chip       Date:  2016-10-05       Impact factor: 6.799

Review 4.  Recent advances in microfluidic technologies for cell-to-cell interaction studies.

Authors:  Mario Rothbauer; Helene Zirath; Peter Ertl
Journal:  Lab Chip       Date:  2018-01-16       Impact factor: 6.799

Review 5.  Organ/body-on-a-chip based on microfluidic technology for drug discovery.

Authors:  Hiroshi Kimura; Yasuyuki Sakai; Teruo Fujii
Journal:  Drug Metab Pharmacokinet       Date:  2017-11-13       Impact factor: 3.614

6.  An integrated microfluidic device with solid-phase extraction and graphene oxide quantum dot array for highly sensitive and multiplex detection of trace metal ions.

Authors:  Minsu Park; Tae Seok Seo
Journal:  Biosens Bioelectron       Date:  2018-11-15       Impact factor: 10.618

7.  Thiol-ene Microfluidic Chip for Performing Hydrogen/Deuterium Exchange of Proteins at Subsecond Time Scales.

Authors:  Rasmus R Svejdal; Eleanor R Dickinson; Drago Sticker; Jörg P Kutter; Kasper D Rand
Journal:  Anal Chem       Date:  2018-12-21       Impact factor: 6.986

8.  On chip preconcentration and fluorescence labeling of model proteins by use of monolithic columns: device fabrication, optimization, and automation.

Authors:  Rui Yang; Jayson V Pagaduan; Ming Yu; Adam T Woolley
Journal:  Anal Bioanal Chem       Date:  2014-07-11       Impact factor: 4.142

Review 9.  Simple Approaches to Minimally-Instrumented, Microfluidic-Based Point-of-Care Nucleic Acid Amplification Tests.

Authors:  Michael G Mauk; Jinzhao Song; Changchun Liu; Haim H Bau
Journal:  Biosensors (Basel)       Date:  2018-02-26

10.  3D Printed Microfluidic Features Using Dose Control in X, Y, and Z Dimensions.

Authors:  Michael J Beauchamp; Hua Gong; Adam T Woolley; Gregory P Nordin
Journal:  Micromachines (Basel)       Date:  2018-06-28       Impact factor: 2.891
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  4 in total

1.  High-Resolution 3D Printing Fabrication of a Microfluidic Platform for Blood Plasma Separation.

Authors:  Sandra Garcia-Rey; Jacob B Nielsen; Gregory P Nordin; Adam T Woolley; Lourdes Basabe-Desmonts; Fernando Benito-Lopez
Journal:  Polymers (Basel)       Date:  2022-06-22       Impact factor: 4.967

Review 2.  Low-cost and open-source strategies for chemical separations.

Authors:  Joshua J Davis; Samuel W Foster; James P Grinias
Journal:  J Chromatogr A       Date:  2020-12-24       Impact factor: 4.759

3.  Immunoaffinity monoliths for multiplexed extraction of preterm birth biomarkers from human blood serum in 3D printed microfluidic devices.

Authors:  Haifa M Almughamsi; Makella K Howell; Samuel R Parry; Joule E Esene; Jacob B Nielsen; Gregory P Nordin; Adam T Woolley
Journal:  Analyst       Date:  2022-02-14       Impact factor: 4.616

Review 4.  Emerging Lab-on-a-Chip Approaches for Liquid Biopsy in Lung Cancer: Status in CTCs and ctDNA Research and Clinical Validation.

Authors:  Ângela Carvalho; Gabriela Ferreira; Duarte Seixas; Catarina Guimarães-Teixeira; Rui Henrique; Fernando J Monteiro; Carmen Jerónimo
Journal:  Cancers (Basel)       Date:  2021-04-27       Impact factor: 6.639
  4 in total

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