Murat Gel scite author profile

Murat Gel

4Publications

287Citation Statements Received

27Citation Statements Given

How they've been cited

351

284

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Affiliations

CSIRO Manufacturing, The University of Tokyo, Commonwealth Scientific and Industrial Research Organisation

Publications

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Dielectrophoretic cell trapping and parallel one-to-one fusion based on field constriction created by a micro-orifice array

Gel

Kimura

Kurosawa

et al. 2010

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Micro-orifice based cell fusion assures high-yield fusion without compromising the cell viability. This paper examines feasibility of a dielectrophoresis ͑DEP͒ assisted cell trapping method for parallel fusion with a micro-orifice array. The goal is to create viable fusants for studying postfusion cell behavior. We fabricated a microfluidic chip that contained a chamber and partition. The partition divided the chamber into two compartments and it had a number of embedded micro-orifices. The voltage applied to the electrodes located at each compartment generated an electric field distribution concentrating in micro-orifices. Cells introduced into each compartment moved toward the micro-orifice array by manipulation of hydrostatic pressure. DEP assisted trapping was used to keep the cells in micro-orifice and to establish cell to cell contact through orifice. By applying a pulse, cell fusion was initiated to form a neck between cells. The neck passing through the orifice resulted in immobilization of the fused cell pair at micro-orifice. After washing away the unfused cells, the chip was loaded to a microscope with stage top incubator for time lapse imaging of the selected fusants. The viable fusants were successfully generated by fusion of mouse fibroblast cells ͑L929͒. Time lapse observation of the fusants showed that fused cell pairs escaping from micro-orifice became one tetraploid cell. The generated tetraploid cells divided into three daughter cells. The fusants generated with a smaller micro-orifice ͑diameterϳ 2 m͒ were kept immobilized at micro-orifice until cell division phase. After observation of two synchronized cell divisions, the fusant divided into four daughter cells. We conclude that the presented method of cell pairing and fusion is suitable for high-yield generation of viable fusants and furthermore, subsequent study of postfusion phenomena.

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Immobilization of biotinylated bacteriophages on biosensor surfaces

Gervais

Gel

Allain

et al. 2007

Sensors and Actuators B: Chemical

124

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Force sensing submicrometer thick cantilevers with ultra-thin piezoresistors by rapid thermal diffusion

Gel

Shimoyama

2003

J. Micromech. Microeng.

105

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One of the most important requirements for a cantilever-type sensor to obtain high force sensitivity is small thickness. By using current micromachining technology it is possible to produce cantilevers of submicrometer thickness. Where self-sensing piezoresistive cantilevers with submicrometer thickness are concerned, it is necessary to use a technology which can create ultra-thin (<100 nm) piezoresistors on a cantilever surface. This work demonstrates for the first time the application of a relatively simple, rapid thermal diffusion method by using spin-on glass film to fabricate sub-100 nm piezoresistors on an ultra-thin single-crystal silicon cantilever. Compared to other shallow junction fabrication methods, which involve implantation or deposition of a doped layer, this method is advantageous since no damage is created in the crystal structure and no toxic gas or hazardous material is used during the process. Besides, this technique can be applied by using low-cost rapid annealers, which can be readily found in most laboratories. By using this method, piezoresistive cantilevers with stiffness in the range of 0.001 N m−1 with sub-100 nm thick piezoresistors are fabricated, and a complete characterization of the fabricated cantilevers is performed.

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Microorifice-Based High-Yield Cell Fusion on Microfluidic Chip: Electrofusion of Selected Pairs and Fusant Viability

Gel

Suzuki

Kimura

et al. 2009

IEEE Trans.on Nanobioscience

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Microorifice-based fusion makes use of electric field constriction to assure high-yield one-to-one fusion of selected cell pairs. The aim of this paper is to verify feasibility of high-yield cell fusion on a microfluidic chip. This paper also examines viability of the fusant created on the chip. We fabricated a microfluidic chip to fuse selected cell pairs and to study postfusion behavior. We used a self-forming meniscus-based fabrication process to create microorifice with a diameter of 2-10 microm on the vertical walls in a microfluidic channel. When 1 MHz was applied to electrodes located on both sides of the microorifice, dielectrophoretic force attracted the cells toward microorifice to form a cell pair. Once the cells get into contact, fusion pulse was applied. Real time imaging of cells during fusion and cytoplasmic dye transfer between cells indicated success of cell fusion. We found that when high frequency voltage for dielectrophoresis was swept from 1 MHz to 10 kHz in 100 micros, cell fusion was initiated. The effective electric field strength was 0.1-0.2 kV/cm. We analyzed viability by imaging fusant going into cell division phase after 48 h of incubation. We conclude that fabricated microfluidic chip is suitable for high-yield one-to-one fusion and creation of viable fusants. This technology should be a useful tool to study fusion phenomena and viability of fusants, as it allows imaging of the cells during and after the fusion.

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Murat Gel

Dielectrophoretic cell trapping and parallel one-to-one fusion based on field constriction created by a micro-orifice array

Immobilization of biotinylated bacteriophages on biosensor surfaces

Force sensing submicrometer thick cantilevers with ultra-thin piezoresistors by rapid thermal diffusion

Microorifice-Based High-Yield Cell Fusion on Microfluidic Chip: Electrofusion of Selected Pairs and Fusant Viability

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