Microfluidic Large-Scale Integration

Thorsen, Todd; Maerkl, Sebastian J.; Quake, Stephen R.

doi:10.1126/science.1076996

Cited by 2,143 publications

(1,814 citation statements)

References 15 publications

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“…The addition of on-chip enzymatic electrodes for metabolic monitoring (Cosnier, 2003) and microfluidic valves for fluidic control (Thorsen et al, 2002) could also further enhance the device functionalities. While the focus of this article was on a cell culture array for cell-based assays, this device could potentially benefit many areas of cell-based biomedical research.…”

Section: Discussionmentioning

confidence: 99%

Continuous perfusion microfluidic cell culture array for high-throughput cell-based assays

Hung

Lee

Sabounchi

et al. 2004

Biotechnol. Bioeng.

475

341

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Section: Discussionmentioning

confidence: 99%

Continuous perfusion microfluidic cell culture array for high-throughput cell-based assays

Hung

Lee

Sabounchi

et al. 2004

Biotechnol. Bioeng.

475

341

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“…Such control has been demonstrated utilizing mechanical, electrical, thermal and optical force methods. [3][4][5][6][7][8][9][10] Electrical methods require the integration of electrodes to the microfluidic chip. If an electric field is applied between two electrodes on the same plane, a nonuniform electric field distribution is formed within the channel and the directionality and adaptability of the field is limited.…”

Section: Introductionmentioning

confidence: 99%

3-dimensional electrode patterning within a microfluidic channel using metal ion implantation

et al. 2010

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The application of electrical fields within a microfluidic channel enables many forms of manipulation necessary for lab-on-a-chip devices. Patterning electrodes inside the microfluidic channel generally requires multi-step optical lithography. Here, we utilize an ion-implantation process to pattern 3D electrodes within a fluidic channel made of polydimethylsiloxane (PDMS). Electrode structuring within the channel is achieved by ion implantation at a 40 angle with a metal shadow mask. The advantages of three-dimensional structuring of electrodes within a fluidic channel over traditional planar electrode designs are discussed. Two possible applications are presented: asymmetric particles can be aligned in any of the three axial dimensions with electro-orientation; colloidal focusing and concentration within a fluidic channel can be achieved through dielectrophoresis. Demonstrations are shown with E. coli, a rod shaped bacteria, and indicate the potential that ion-implanted microfluidic channels have for manipulations in the context of lab-on-a-chip devices.

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“…It is also possible to modify the array design such that each individual chamber has a separate outlet, allowing the collection of fluidic samples for biochemical analysis (e.g., PCR, ELISA, HPLC, mass spectroscopy). Automation of array operation and data collection can be achieved by integrating previously developed microfluidic technology, allowing massively multiplexed cell level analysis of individual cells (Hong et al, 2004;Thorsen et al, 2002). By enabling biologists with a robust method to control the fluidic environments of an array of cell culture units, the precision and accuracy of quantitative cell experiments will be greatly improved.…”

Section: Discussionmentioning

confidence: 99%

Nanoliter scale microbioreactor array for quantitative cell biology

Lee

Hung

Rao

et al. 2005

Biotech & Bioengineering

203

183

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A nanoliter scale microbioreactor array was designed for multiplexed quantitative cell biology. An addressable 8 Â 8 array of three nanoliter chambers was demonstrated for observing the serum response of HeLa human cancer cells in 64 parallel cultures. The individual culture unit was designed with a ''C'' shaped ring that effectively decoupled the central cell growth regions from the outer fluid transport channels. The chamber layout mimics physiological tissue conditions by implementing an outer channel for convective ''blood'' flow that feeds cells through diffusion into the low shear ''interstitial'' space. The 2 mm opening at the base of the ''C'' ring established a differential fluidic resistance up to 3 orders of magnitude greater than the fluid transport channel within a single mold microfluidic device. Three-dimensional (3D) finite element simulation were used to predict fluid transport properties based on chamber dimensions and verified experimentally. The microbioreactor array provided a continuous flow culture environment with a Peclet number (0.02) and shear stress (0.01 Pa) that approximated in vivo tissue conditions without limiting mass transport (10 s nutrient turnover). This microfluidic design overcomes the major problems encountered in multiplexing nanoliter culture environments by enabling uniform cell loading, eliminating shear, and pressure stresses on cultured cells, providing stable control of fluidic addressing, and permitting continuous on-chip optical monitoring. ß 2005 Wiley Periodicals, Inc.

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Microfluidic Large-Scale Integration

Cited by 2,143 publications

References 15 publications

Continuous perfusion microfluidic cell culture array for high-throughput cell-based assays

Continuous perfusion microfluidic cell culture array for high-throughput cell-based assays

3-dimensional electrode patterning within a microfluidic channel using metal ion implantation

Nanoliter scale microbioreactor array for quantitative cell biology

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