Literature DB >> 18432341

Automated cell culture in high density tubeless microfluidic device arrays.

Ivar Meyvantsson1, Jay W Warrick, Steven Hayes, Allyson Skoien, David J Beebe.   

Abstract

Microfluidics is poised to have an impact on life sciences research. However, current microfluidic methods are not compatible with existing laboratory liquid dispensing and detection infrastructure. This incompatibility is a barrier to adoption of microfluidic systems and calls for improved approaches that will enhance performance and promote acceptance of microfluidic systems in the life sciences. Ease of use, standardized interfaces and automation remain critical challenges. We present a platform based on surface tension effects, where the difference in pressure inside drops of unequal volume drives flow in passive structures. We show integration with existing laboratory infrastructure, microfluidic operations such as pumping, routing and compartmentalization without discrete micro-components as well as cell patterning in both monolayer and three-dimensional cell culture.

Entities:  

Mesh:

Year:  2008        PMID: 18432341     DOI: 10.1039/b715375a

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


  58 in total

1.  Solving medical problems with BioMEMS.

Authors:  Erkin Seker; Jong Hwan Sung; Michael L Shuler; Martin L Yarmush
Journal:  IEEE Pulse       Date:  2011-11       Impact factor: 0.924

2.  Gravity-oriented microfluidic device for uniform and massive cell spheroid formation.

Authors:  Kangsun Lee; Choong Kim; Jae Young Yang; Hun Lee; Byungwook Ahn; Linfeng Xu; Ji Yoon Kang; Kwang W Oh
Journal:  Biomicrofluidics       Date:  2012-03-07       Impact factor: 2.800

3.  Expanding the available assays: adapting and validating In-Cell Westerns in microfluidic devices for cell-based assays.

Authors:  Amy L Paguirigan; John P Puccinelli; Xiaojing Su; David J Beebe
Journal:  Assay Drug Dev Technol       Date:  2010-07-26       Impact factor: 1.738

4.  A pump-free membrane-controlled perfusion microfluidic platform.

Authors:  Vasiliy N Goral; Elizabeth Tran; Po Ki Yuen
Journal:  Biomicrofluidics       Date:  2015-09-02       Impact factor: 2.800

Review 5.  Fundamentals of microfluidic cell culture in controlled microenvironments.

Authors:  Edmond W K Young; David J Beebe
Journal:  Chem Soc Rev       Date:  2010-02-01       Impact factor: 54.564

Review 6.  Managing evaporation for more robust microscale assays. Part 2. Characterization of convection and diffusion for cell biology.

Authors:  Erwin Berthier; Jay Warrick; Hongmeiy Yu; David J Beebe
Journal:  Lab Chip       Date:  2008-04-08       Impact factor: 6.799

Review 7.  Managing evaporation for more robust microscale assays. Part 1. Volume loss in high throughput assays.

Authors:  Erwin Berthier; Jay Warrick; Hongmeiy Yu; David J Beebe
Journal:  Lab Chip       Date:  2008-04-08       Impact factor: 6.799

8.  Cellular observations enabled by microculture: paracrine signaling and population demographics.

Authors:  Maribella Domenech; Hongmei Yu; Jay Warrick; Nisha M Badders; Ivar Meyvantsson; Caroline M Alexander; David J Beebe
Journal:  Integr Biol (Camb)       Date:  2009-03       Impact factor: 2.192

9.  A Plug-and-Play, Drug-on-Pillar Platform for Combination Drug Screening Implemented by Microfluidic Adaptive Printing.

Authors:  Jiannan Li; Wen Tan; Wenwu Xiao; Randy P Carney; Yongfan Men; Yuanpei Li; Gerald Quon; Yousif Ajena; Kit S Lam; Tingrui Pan
Journal:  Anal Chem       Date:  2018-11-13       Impact factor: 6.986

10.  High-content adhesion assay to address limited cell samples.

Authors:  Jay W Warrick; Edmond W K Young; Eric G Schmuck; Kurt W Saupe; David J Beebe
Journal:  Integr Biol (Camb)       Date:  2013-02-21       Impact factor: 2.192
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