Lab-on-a-chip technologies for proteomic analysis from isolated cells

Sedgwick, H.; Caron, F.; Monaghan, P.B.; Kolch, W.; Cooper, J.M.

doi:10.1098/rsif.2008.0169

Cited by 7 publications

(10 citation statements)

References 20 publications

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“…A common set of electrode pattern can be implemented to initially trap and concentrate target cells in regions of interest by dielectrophoretic force and then perform subsequent electroporation while cells are exposed to electric pulsing protocols. 60, 67–69, 72–76, 78–80, 82, 83, 89 Therefore, this technique, adopted in either static or flow-through manner, is particularly suitable for applications combining electrical cell lysis with downstream intracellular content analysis 72–76, 79, 80, 82 .…”

Section: The Various Strategies For Microfluidic Electroporationmentioning

confidence: 99%

“…Techniques other than electrophoresis were also used for analysis of intracellular molecules released by electroporation. 58, 67–70, 79, 80, 104, 123, 124 An integrated device was reported on F 1 -ATPase rotational assay at the single molecule level. 80 In the work, genetically engineered E. coli expressing 6× His-tag fusion F 1 -ATPase was continuously loaded into the chip and initially lysed by interdigitated sawtooth planar microelectrodes in a chamber.…”

Section: The Applications Of Microfluidic Electroporationmentioning

confidence: 99%

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Microfluidic electroporation for cellular analysis and delivery

2013

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Electroporation is a simple yet powerful technique for breaching cell membrane barrier. The applications of electroporation can be generally divided into two categories: the release of intracellular proteins, nucleic acids and other metabolites for analysis and the delivery of exogenous reagents such as genes, drugs and nanoparticles with therapeutic purposes or for cellular manipulation. In this review, we go over the basic physics associated with cell electroporation and highlight recent technological advances on microfluidic platforms for conducting electroporation. Within the context of its working mechanism, we summarize the accumulated knowledge on how the parameters of electroporation affect its performance for various tasks. We discuss various strategies and designs for conducting electroporation at microscale and then focus on analysis of intracellular contents and delivery of exogenous agents as two major applications of the technique. Finally, an outlook for future applications of microfluidic electroporation in increasingly diverse utilities is presented.

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Section: The Various Strategies For Microfluidic Electroporationmentioning

confidence: 99%

Section: The Applications Of Microfluidic Electroporationmentioning

confidence: 99%

Microfluidic electroporation for cellular analysis and delivery

2013

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“…Also, the overall process of protein release can be monitored by confocal fluorescence microscopy. 61 To use relatively low voltages in single-cell electroporation, electrophoresis can be used to enhance delivery of compounds, followed by electroporation. For example, this can be used to assist electroporative uptake of impermanent molecules such as Calcein (MW: 622 Da) and Oregon Green Dextran (MW: 70 000 Da) in microchannels.…”

Section: Recent Advances Of Microscale Electroporationmentioning

confidence: 99%

Microscale electroporation: challenges and perspectives for clinical applications

Lee

Demirci

Khademhosseini

2009

Integrative Biology

140

112

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Microscale engineering plays a significant role in developing tools for biological applications by miniaturizing devices and providing controllable microenvironments for in vitro cell research. Miniaturized devices offer numerous benefits in comparison to their macroscale counterparts, such as lower use of expensive reagents, biomimetic environments, and the ability to manipulate single cells. Microscale electroporation is one of the main beneficiaries of microscale engineering as it provides spatial and temporal control of various electrical parameters. Microscale electroporation devices can be used to reduce limitations associated with the conventional electroporation approaches such as variations in the local pH, electric field distortion, sample contamination, and the difficulties in transfecting and maintaining the viability of desired cell types. Here, we present an overview of recent advances of the microscale electroporation methods and their applications in biology, as well as current challenges for its use for clinical applications. We categorize microscale electroporation into microchannel and microcapillary electroporation. Microchannel-based electroporation can be used for transfecting cells within microchannels under dynamic flow conditions in a controlled and high-throughput fashion. In contrast, microcapillary-based electroporation can be used for transfecting cells within controlled reaction chambers under static flow conditions. Using these categories we examine the use of microscale electroporation for clinical applications related to HIV-1, stem cells, cancer and other diseases and discuss the challenges in further advancing this technology for use in clinical medicine and biology.

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“…Single cell and single molecular analytic methods may bring about breakthrough in metabolic research in the future (Amantonico et al, 2009;Krylov et al, 2000;Andersson and van den Berg, 2004;Sedgwick et al, 2008). Many more burdens have to be overcome before they can be really applied to metabolic analysis of real samples from physiologically defined cultures, especially from processes of biotechnology.…”

Section: Introductionmentioning

confidence: 99%

“…Up to now, the application of microfluidic systems in biotechnology rather focus on the fields of genomic or proteomic research, on-chip cell culturing and the integration of micro analytical techniques (Shendure and Ji, 2008;Andersson and van den Berg, 2003;Sedgwick et al, 2008;Weibel et al, 2007). Usually, the systems are optimized towards minimum sample volume and are designed to meet the requirements for serial production and disposability.…”

Section: Introductionmentioning

confidence: 99%