Literature DB >> 23931456

Hollow-channel paper analytical devices.

Christophe Renault1, Xiang Li, Stephen E Fosdick, Richard M Crooks.   

Abstract

We present a microfluidic paper analytical device (μPAD) that relies on flow in hollow channels, rather than through a cellulose network, to transport fluids. The flow rate in hollow channels is 7 times higher than in regular paper channels and can be conveniently controlled from 0 to several mm/s by balancing capillary and pressure forces. More importantly, the pressure of a single drop of liquid (~0.2 mbar) is sufficient to induce fast pressure-driven flow, making hollow channels suitable for point of care diagnostics. We demonstrate their utility for simple colorimetric glucose and BSA assays in which the time for liquid transport is reduced by a factor of 4 compared to normal cellulose channels.

Entities:  

Year:  2013        PMID: 23931456     DOI: 10.1021/ac401786h

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


  15 in total

1.  Rapid flow in multilayer microfluidic paper-based analytical devices.

Authors:  Robert B Channon; Michael P Nguyen; Alexis G Scorzelli; Elijah M Henry; John Volckens; David S Dandy; Charles S Henry
Journal:  Lab Chip       Date:  2018-02-27       Impact factor: 6.799

2.  Principles of long-term fluids handling in paper-based wearables with capillary-evaporative transport.

Authors:  Timothy Shay; Tamoghna Saha; Michael D Dickey; Orlin D Velev
Journal:  Biomicrofluidics       Date:  2020-06-09       Impact factor: 2.800

3.  Multilayered Microfluidic Paper-Based Devices: Characterization, Modeling, and Perspectives.

Authors:  Robert B Channon; Michael P Nguyen; Charles S Henry; David S Dandy
Journal:  Anal Chem       Date:  2019-07-05       Impact factor: 6.986

4.  Faradaic Ion Concentration Polarization on a Paper Fluidic Platform.

Authors:  Xiang Li; Long Luo; Richard M Crooks
Journal:  Anal Chem       Date:  2017-03-17       Impact factor: 6.986

5.  Rapid evaporation-driven chemical pre-concentration and separation on paper.

Authors:  Richard Syms
Journal:  Biomicrofluidics       Date:  2017-08-24       Impact factor: 2.800

6.  Managing Heart Failure at Home With Point-of-Care Diagnostics.

Authors:  Paul R Degregory; Jansen Tapia; Tammy Wong; Jo Villa; Ian Richards; Richard M Crooks
Journal:  IEEE J Transl Eng Health Med       Date:  2017-09-04       Impact factor: 3.316

Review 7.  Micro total analysis systems: fundamental advances and biological applications.

Authors:  Christopher T Culbertson; Tom G Mickleburgh; Samantha A Stewart-James; Kathleen A Sellens; Melissa Pressnall
Journal:  Anal Chem       Date:  2013-12-13       Impact factor: 6.986

8.  Scalable low-cost fabrication of disposable paper sensors for DNA detection.

Authors:  Ram P Gandhiraman; Dennis Nordlund; Vivek Jayan; M Meyyappan; Jessica E Koehne
Journal:  ACS Appl Mater Interfaces       Date:  2014-12-05       Impact factor: 9.229

Review 9.  Increasing the packing density of assays in paper-based microfluidic devices.

Authors:  Sajjad Rahmani Dabbagh; Elaina Becher; Fariba Ghaderinezhad; Hayati Havlucu; Oguzhan Ozcan; Mehmed Ozkan; Ali Kemal Yetisen; Savas Tasoglu
Journal:  Biomicrofluidics       Date:  2021-02-04       Impact factor: 2.800

10.  Controlling Capillary Flow Rate on Lateral Flow Test Substrates by Tape.

Authors:  Zhiqing Xiao; Yuqian Yang; Xingwei Zhang; Weijin Guo
Journal:  Micromachines (Basel)       Date:  2021-05-16       Impact factor: 2.891
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