Electroporation through a micro-fabricated orifice and its application to the measurement of cell response to external stimuli

Kurosawa, Osamu; Oana, Hidehiro; Matsuoka, Satoshi; Noma, Akinori; Kotera, Hidetoshi; Washizu, Masao

doi:10.1088/0957-0233/17/12/s02

Cited by 44 publications

(41 citation statements)

References 26 publications

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“…Besides two common characteristics of low amplitude voltage source and high heat dissipation rate, each microdevice has its own characteristics of single cell EP (Huang and Rubinsky 2003;Khine et al 2005;Khine et al 2007), electrophoresis assisted EP (Huang et al 2007), focused electric field by geometrical constriction (Kurosawa et al 2006;Wang and Lu 2006;Fei et al 2007;Kim et al 2007b), and parallelized EP process (Kim et al 2007a). However, the applications have been confined in the gene transfection and cell lysis areas.…”

Section: Introductionmentioning

confidence: 99%

On-chip testing device for electrochemotherapeutic effects on human breast cells

Choi

Kim²,

Kwon

et al. 2008

Biomed Microdevices

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A microfabricated cell-based testing device for electrochemotherapy (ECT) has been developed by miniaturizing the widely used clinical electroporator with a two-needle array into two-dimensional planar electrodes while keeping the similarity of the electric field strength distribution. In this device, all the biological processes from cell culture to electroporation and final cell-based assays were carried out on a chip using a conventional 2D cell culture method, and the multiple electrochemotherapeutic assays could be realized by exploiting the six electroporation sites in a single device. With the proposed platform, the electroporation rate was evaluated with propidium iodide and cell proliferation after 48 h of electrochemotherapy with bleomycin was determined with T47D human breast ductal carcinoma cell line in various electric field strengths and drug concentrations. This microsystem has several advantages over conventional cuvette type electroporation assay, such as multiple assays on a chip, on-chip based operation from cell culture to final assay, and having similar electric field distribution as that of the clinical electroporator. As the clinical trials of electrochemotherapy are being carried out, this new platform is expected to have valuable applications in basic in vitro ECT studies, drug discovery, and development of clinical ECT equipment.

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Section: Introductionmentioning

confidence: 99%

On-chip testing device for electrochemotherapeutic effects on human breast cells

Choi

Kim²,

Kwon

et al. 2008

Biomed Microdevices

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“…1, those micro-devices usually consist of a large flow channel for cells to freely pass and one or an array of embedded constrictions (e.g., orifices or side microchannels with the key dimensions about half of the cell size or smaller to help trap cells at desired locations). [42][43][44][45][46][47][48][49] Electrodes were generally closely spaced and patterned so that a low potential difference is enough for electroporation and/or measurements of other electrical signal (e.g., electric conductivity or impedance) at the presence of electrolysis disturbance. To firmly hold cells, a gentle vacuum was sometimes used to pull a small portion of cells inside the microscale constrictions.…”

Section: Recent Progress In Micro-/nanofluidics Based Electroporamentioning

confidence: 99%

“…To firmly hold cells, a gentle vacuum was sometimes used to pull a small portion of cells inside the microscale constrictions. [46][47][48][49][55][56][57][58] If cell lysis is necessary, more efficient lysis electrode designs such as interdigitated electrodes with a saw-tooth structure could be used. Besides trapping cells with physical contact, optical tweezers technology (a technology that creates radiation pressure with an intensified laser beam to facilitate non-contact optical trapping to colloids) was also introduced to help grab and relocate cells remotely in electroporation micro-devices ( Fig.…”

Section: Recent Progress In Micro-/nanofluidics Based Electroporamentioning

confidence: 99%

“…The recent emerging of micro-/nanotechnologies opened new routes to create better electrode designs, improved operation platforms, and more advanced regulations and controls on the electric pulses, cells, and pH and/or temperature variations. [25][26][27] A number of new electroporation systems with micro-/nanoscale features, including microfluidicelectroporation (MEP) and nanofluidic-electroporation (NEP), have been introduced, which offer various advantages over available commercial systems towards improved performance (i.e., high transfection efficiency and high cell viability) from the following aspects: (1) in situ monitoring of intracellular content transport in the electroporation process and dynamics at the single cell level, [28][29][30][31][32][33][34][35][36][37][38][39] (2) very low potential differences (can be as low as 1 V/cm) while sufficient to upset the cell membrane to avoid unwanted electrochemical reactions, pH variations, Joule heating, and gas bubble formation, [35][36][37][38][39][40][41][42][43][44][45][46][47][48][49] (3) better accuracy and flexibility on cell handling and manipulation to achieve dosage control and specific treatment for different sizes of cell population. These new approaches have been applied to cell lysis, cell fusion, and cell electroporation with focuses varying from single cell analysis to large scale process towards clinic use.…”

Section: Introductionmentioning

confidence: 99%

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Micro-/nanofluidics based cell electroporation

Wang

Lee

2013

Biomicrofluidics

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Non-viral gene delivery has been extensively explored as the replacement for viral systems. Among various non-viral approaches, electroporation has gained increasing attention because of its easy operation and no restrictions on probe or cell type. Several effective systems are now available on the market with reasonably good gene delivery performance. To facilitate broader biological and medical applications, micro-/nanofluidics based technologies were introduced in cell electroporation during the past two decades and their advances are summarized in this perspective. Compared to the commercially available bulk electroporation systems, they offer several advantages, namely, (1) sufficiently high pulse strength generated by a very low potential difference, (2) conveniently concentrating, trapping, and regulating the position and concentration of cells and probes, (3) real-time monitoring the intracellular trafficking at single cell level, and (4) flexibility on cells to be transfected (from single cell to large scale cell population). Some of the micro-devices focus on cell lysis or fusion as well as the analysis of cellular properties or intracellular contents, while others are designed for gene transfection. The uptake of small molecules (e.g., dyes), DNA plasmids, interfering RNAs, and nanoparticles has been broadly examined on different types of mammalian cells, yeast, and bacteria. A great deal of progress has been made with a variety of new micro-/nanofluidic designs to address challenges such as electrochemical reactions including water electrolysis, gas bubble formation, waste of expensive reagents, poor cell viability, low transfection efficacy, higher throughput, and control of transfection dosage and uniformity. Future research needs required to advance micro-/nanofluidics based cell electroporation for broad life science and medical applications are discussed.

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“…Rectangular orifices within such channels are commonly encountered in microfluidics systems in the form of microvalves and micro-pumps (Au et al 2011), micro-coolers (Jin et al 2011), emulsifiers (Skurtys & Aguilera 2008), cell filters (Bhagat et al 2010), flow cytometers (Lee et al 2011), and cell analysers (Kurosawa et al 2006;Li et al 2007;Gel et al 2009). We have also recently suggested use of an orifice as a distributor for micro-fluidized beds (Zivkovic et al 2010), which we are currently developing as a means of increasing mixing, heat and mass transfer in micro-reactor systems and, additionally, sensitivity in analytical applications (Zivkovic et al 2012).…”

mentioning

confidence: 99%

A pressure drop correlation for low Reynolds number Newtonian flows through a rectangular orifice in a similarly shaped micro-channel

Živković

Zerna

Alwahabi

et al. 2013

Chemical Engineering Research and Design

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Elsevier believes that individual authors should be able to distribute their AAMs for their personal voluntary needs and interests, e.g. posting to their websites or their institution's repository, e-mailing to colleagues. However, our policies differ regarding the systematic aggregation or distribution of AAMs to ensure the sustainability of the journals to which AAMs are submitted. Therefore, deposit in, or posting to, subjectoriented or centralized repositories (such as PubMed Central), or institutional repositories with systematic posting mandates is permitted only under specific agreements between Elsevier and the repository, agency or institution, and only consistent with the publisher's policies concerning such repositories. Abstract: Current microfabrication methods mean that rectangular orifices in similarly shaped micro-channels are often found in microfluidic devices. The power required to overcome the pressure drop across such orifices is often of importance. In the contribution reported here, numerical results for low Reynolds number incompressible Newtonian fluid flow through rectangular orifice in similarly shaped micro-channel have been used to develop a correlation for pressure drop arising from the orifice. The correlation, which was motivated by theoretical developments, indicates that the pressure drop is proportional to the average velocity through the orifice, and a function of the orifice contraction ratio, length-to-width ratio and, most particularly, aspect ratio.

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Electroporation through a micro-fabricated orifice and its application to the measurement of cell response to external stimuli

Cited by 44 publications

References 26 publications

On-chip testing device for electrochemotherapeutic effects on human breast cells

On-chip testing device for electrochemotherapeutic effects on human breast cells

Micro-/nanofluidics based cell electroporation

A pressure drop correlation for low Reynolds number Newtonian flows through a rectangular orifice in a similarly shaped micro-channel

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