Literature DB >> 24420386

A microfluidic cell co-culture platform with a liquid fluorocarbon separator.

Bryson M Brewer1, Mingjian Shi, Jon F Edd, Donna J Webb, Deyu Li.   

Abstract

A microfluidic cell co-culture platform that uses a liquid fluorocarbon oil barrier to separate cells into different culture chambers has been developed. Characterization indicates that the oil barrier could be effective for multiple days, and a maximum pressure difference between the oil barrier and aqueous media in the cell culture chamber could be as large as ~3.43 kPa before the oil barrier fails. Biological applications have been demonstrated with the separate transfection of two groups of primary hippocampal neurons with two different fluorescent proteins and subsequent observation of synaptic contacts between the neurons. In addition, the quality of the fluidic seal provided by the oil barrier is shown to be greater than that of an alternative solid-PDMS valve barrier design by testing the ability of each device to block low molecular weight CellTracker dyes used to stain cells in the culture chambers.

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Year:  2014        PMID: 24420386      PMCID: PMC3980022          DOI: 10.1007/s10544-014-9834-8

Source DB:  PubMed          Journal:  Biomed Microdevices        ISSN: 1387-2176            Impact factor:   2.838


  52 in total

1.  Power-free poly(dimethylsiloxane) microfluidic devices for gold nanoparticle-based DNA analysis.

Authors:  Kazuo Hosokawa; Kae Sato; Naoki Ichikawa; Mizuo Maeda
Journal:  Lab Chip       Date:  2004-05-12       Impact factor: 6.799

2.  Multi-step synthesis of nanoparticles performed on millisecond time scale in a microfluidic droplet-based system.

Authors:  Ilya Shestopalov; Joshua D Tice; Rustem F Ismagilov
Journal:  Lab Chip       Date:  2004-07-05       Impact factor: 6.799

3.  Enzymatic degradation of p-chlorophenol in a two-phase flow microchannel system.

Authors:  Tatsuo Maruyama; Jun-ichi Uchida; Tomohiro Ohkawa; Toru Futami; Koji Katayama; Kei-ichiro Nishizawa; Ken-ichiro Sotowa; Fukiko Kubota; Noriho Kamiya; Masahiro Goto
Journal:  Lab Chip       Date:  2003-10-14       Impact factor: 6.799

4.  PDMS absorption of small molecules and consequences in microfluidic applications.

Authors:  Michael W Toepke; David J Beebe
Journal:  Lab Chip       Date:  2006-10-04       Impact factor: 6.799

5.  A microfluidic culture platform for CNS axonal injury, regeneration and transport.

Authors:  Anne M Taylor; Mathew Blurton-Jones; Seog Woo Rhee; David H Cribbs; Carl W Cotman; Noo Li Jeon
Journal:  Nat Methods       Date:  2005-08       Impact factor: 28.547

6.  Analysis of pressure-driven air bubble elimination in a microfluidic device.

Authors:  Joo H Kang; Yu Chang Kim; Je-Kyun Park
Journal:  Lab Chip       Date:  2007-10-25       Impact factor: 6.799

7.  An active bubble trap and debubbler for microfluidic systems.

Authors:  Alison M Skelley; Joel Voldman
Journal:  Lab Chip       Date:  2008-08-28       Impact factor: 6.799

8.  An integrated microfluidic system for long-term perfusion culture and on-line monitoring of intestinal tissue models.

Authors:  Hiroshi Kimura; Takatoki Yamamoto; Hitomi Sakai; Yasuyuki Sakai; Teruo Fujii
Journal:  Lab Chip       Date:  2008-04-04       Impact factor: 6.799

9.  Rapid Prototyping of Microfluidic Systems in Poly(dimethylsiloxane).

Authors:  D C Duffy; J C McDonald; O J Schueller; G M Whitesides
Journal:  Anal Chem       Date:  1998-12-01       Impact factor: 6.986

10.  A simple PDMS-based microfluidic channel design that removes bubbles for long-term on-chip culture of mammalian cells.

Authors:  Wenfu Zheng; Zhuo Wang; Wei Zhang; Xingyu Jiang
Journal:  Lab Chip       Date:  2010-09-15       Impact factor: 6.799
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  8 in total

1.  Ultrasimple Single-Cell Detection of Multiple Cytokines by a Nanowell Chip Integrated with Encoded Microarrays.

Authors:  Mohammed A A Abdullah; Jun Wang
Journal:  ACS Sens       Date:  2019-09-06       Impact factor: 7.711

2.  A microfluidic co-culture system to monitor tumor-stromal interactions on a chip.

Authors:  Nishanth V Menon; Yon Jin Chuah; Bin Cao; Mayasari Lim; Yuejun Kang
Journal:  Biomicrofluidics       Date:  2014-12-05       Impact factor: 2.800

3.  Metabolic consequences of interleukin-6 challenge in developing neurons and astroglia.

Authors:  Jacquelyn A Brown; Stacy D Sherrod; Cody R Goodwin; Bryson Brewer; Lijie Yang; Krassimira A Garbett; Deyu Li; John A McLean; John P Wikswo; Károly Mirnics
Journal:  J Neuroinflammation       Date:  2014-11-06       Impact factor: 8.322

Review 4.  Microdevice Platform for In Vitro Nervous System and Its Disease Model.

Authors:  Jin-Ha Choi; Hyeon-Yeol Cho; Jeong-Woo Choi
Journal:  Bioengineering (Basel)       Date:  2017-09-13

5.  Improving viability of leukemia cells by tailoring shell fluid rheology in constricted microcapillary.

Authors:  Mohammad Nooranidoost; Ranganathan Kumar
Journal:  Sci Rep       Date:  2020-07-14       Impact factor: 4.379

6.  Highly efficient cellular cloning using Ferro-core Micropallet Arrays.

Authors:  Trisha M Westerhof; Wesley A Cox-Muranami; Guann-Pyng Li; Mark Bachman; Hung Fan; Edward L Nelson
Journal:  Sci Rep       Date:  2017-10-12       Impact factor: 4.379

7.  Quantitative Systems Pharmacology for Neuroscience Drug Discovery and Development: Current Status, Opportunities, and Challenges.

Authors:  Hugo Geerts; John Wikswo; Piet H van der Graaf; Jane P F Bai; Chris Gaiteri; David Bennett; Susanne E Swalley; Edgar Schuck; Rima Kaddurah-Daouk; Katya Tsaioun; Mary Pelleymounter
Journal:  CPT Pharmacometrics Syst Pharmacol       Date:  2019-11-24

8.  Deformation of an Encapsulated Leukemia HL60 Cell through Sudden Contractions of a Microfluidic Channel.

Authors:  Mohammad Nooranidoost; Ranganathan Kumar
Journal:  Micromachines (Basel)       Date:  2021-03-25       Impact factor: 2.891
  8 in total

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