Literature DB >> 19789757

Multi-channel peristaltic pump for microfluidic applications featuring monolithic PDMS inlay.

Peder Skafte-Pedersen1, David Sabourin, Martin Dufva, Detlef Snakenborg.   

Abstract

The design, fabrication and characterization of a miniaturized, mechanically-actuated 12-channel peristaltic pump for microfluidic applications and built from simple, low-cost materials and fabrication methods is presented. Two pump configurations are tested, including one which reduces pulsating flow. Both use a monolithic PDMS pumping inlay featuring three-dimensional geometries favourable to pumping applications and 12 wholly integrated circular channels. Flow rates in the sub-microL min(-1) to microL min(-1) range were obtained. Channel-to-channel flow rate variability was comparable to a commercial pumping system at lower flow rates. The small footprint, 40 mm by 80 mm, of the micropump renders it portable, and allows its use on microscope stages adjacent to microfluidic devices, thus reducing system dead volumes. The micropump's design allows potential use in remote and resource-limited locations.

Entities:  

Year:  2009        PMID: 19789757     DOI: 10.1039/b906156h

Source DB:  PubMed          Journal:  Lab Chip        ISSN: 1473-0189            Impact factor:   6.799


  16 in total

1.  Aris-Taylor dispersion with drift and diffusion of particles on the tube wall.

Authors:  Alexander M Berezhkovskii; Alexei T Skvortsov
Journal:  J Chem Phys       Date:  2013-08-28       Impact factor: 3.488

2.  A valve-less microfluidic peristaltic pumping method.

Authors:  Xiannian Zhang; Zitian Chen; Yanyi Huang
Journal:  Biomicrofluidics       Date:  2015-02-11       Impact factor: 2.800

3.  A microfluidic gas damper for stabilizing gas pressure in portable microfluidic systems.

Authors:  Xinjie Zhang; Zhixian Zhu; Nan Xiang; Zhonghua Ni
Journal:  Biomicrofluidics       Date:  2016-10-28       Impact factor: 2.800

4.  Three-dimensional Printing of Thermoplastic Materials to Create Automated Syringe Pumps with Feedback Control for Microfluidic Applications.

Authors:  Ming-Cheng Chen; John R Lake; Keith C Heyde; Warren C Ruder
Journal:  J Vis Exp       Date:  2018-08-30       Impact factor: 1.355

5.  Modular microfluidic system as a model of cystic fibrosis airways.

Authors:  M Skolimowski; M Weiss Nielsen; F Abeille; P Skafte-Pedersen; D Sabourin; A Fercher; D Papkovsky; S Molin; R Taboryski; C Sternberg; M Dufva; O Geschke; J Emnéus
Journal:  Biomicrofluidics       Date:  2012-08-02       Impact factor: 2.800

6.  Highly-customizable 3D-printed peristaltic pump kit.

Authors:  Terry Ching; Jyothsna Vasudevan; Hsih Yin Tan; Chwee Teck Lim; Javier Fernandez; Yi-Chin Toh; Michinao Hashimoto
Journal:  HardwareX       Date:  2021-05-17

7.  A Magnetorheological Duckbill Valve Micropump for Drug Delivery Applications.

Authors:  Rubayet Hassan; Sevki Cesmeci; Mahmoud Baniasadi; Anthony Palacio; Austin Robbins
Journal:  Micromachines (Basel)       Date:  2022-04-30       Impact factor: 3.523

8.  Utility of low-cost, miniaturized peristaltic and Venturi pumps in droplet microfluidics.

Authors:  Joshua J Davis; Melanie Padalino; Alexander S Kaplitz; Greggory Murray; Samuel W Foster; Jonathan Maturano; James P Grinias
Journal:  Anal Chim Acta       Date:  2021-01-26       Impact factor: 6.558

9.  Direct immobilization of DNA probes on non-modified plastics by UV irradiation and integration in microfluidic devices for rapid bioassay.

Authors:  Yi Sun; Ivan Perch-Nielsen; Martin Dufva; David Sabourin; Dang Duong Bang; Jonas Høgberg; Anders Wolff
Journal:  Anal Bioanal Chem       Date:  2011-10-26       Impact factor: 4.142

10.  Poly(dimethylsiloxane) (PDMS) affects gene expression in PC12 cells differentiating into neuronal-like cells.

Authors:  Joanna M Łopacińska; Jenny Emnéus; Martin Dufva
Journal:  PLoS One       Date:  2013-01-03       Impact factor: 3.240
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