A smart fully integrated micromachined separator with soft magnetic micro-pillar arrays for cell isolation

Dong, Tao; Su, Qianhua; Yang, Zhaochu; Zhang, Yulong; Egeland, Eirik Bentzen; Gu, D.; Calabrese, P.; Kapiris, Matteo J; Karlsen, Frank; Minh, Nhut T; Wang, Kaiying; Jakobsen, Henrik

doi:10.1088/0960-1317/20/11/115021

Cited by 59 publications

(32 citation statements)

References 19 publications

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“…The result indicates that decreasing the heat sink length while increasing the cross-finarray area may lead to a significantly outweighing TEG output power density over the heat sink efficiency. Dong et al [8] found that micro-pillar arrays would amplify and redistribute the electromagnetic field which enables the separation of cells or proteins with common antigens with low current, low heat dissipation and high efficiency. Mei et al [9] reported that micro-pin-fin array with catalyst coating is beneficial for a uniform velocity and temperature distribution in the reactor with a higher methanol conversion rate.…”

Section: Introductionmentioning

confidence: 99%

Entropy generation and optimization of laminar convective heat transfer and fluid flow in a microchannel with staggered arrays of pin fin structure with tip clearance

Shi

Dong

2015

Energy Conversion and Management

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Section: Introductionmentioning

confidence: 99%

Entropy generation and optimization of laminar convective heat transfer and fluid flow in a microchannel with staggered arrays of pin fin structure with tip clearance

Shi

Dong

2015

Energy Conversion and Management

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“…Fortunately, these sampling modules, cell separators and bio-reactors have been extensively studied as our research ground [19,20,21,22]. To simplify the experimental system, we used syringe pumps instead of peristaltic pumps to accurately load the test samples.…”

Section: Methodsmentioning

confidence: 99%

A Microfluidic Device for Continuous Sensing of Systemic Acute Toxicants in Drinking Water

Zhao

Dong

2013

IJERPH

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A bioluminescent-cell-based microfluidic device for sensing toxicants in drinking water was designed and fabricated. The system employed Vibrio fischeri cells as broad-spectrum sensors to monitor potential systemic cell toxicants in water, such as heavy metal ions and phenol. Specifically, the chip was designed for continuous detection. The chip design included two counter-flow micromixers, a T-junction droplet generator and six spiral microchannels. The cell suspension and water sample were introduced into the micromixers and dispersed into droplets in the air flow. This guaranteed sufficient oxygen supply for the cell sensors. Copper (Cu2+), zinc (Zn2+), potassium dichromate and 3,5-dichlorophenol were selected as typical toxicants to validate the sensing system. Preliminary tests verified that the system was an effective screening tool for acute toxicants although it could not recognize or quantify specific toxicants. A distinct non-linear relationship was observed between the zinc ion concentration and the Relative Luminescence Units (RLU) obtained during testing. Thus, the concentration of simple toxic chemicals in water can be roughly estimated by this system. The proposed device shows great promise for an early warning system for water safety.

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“…This may also have been enhanced by the large filtration area of the MPR and the turbine-blade profile for the micro-pillars of the CFR cells. [34][35][36] …”

Section: Mpr Recoverymentioning

confidence: 99%

A cascade-like silicon filter for improved recovery of oocysts from environmental waters

Pires

Dong

2013

Environmental Technology

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Standard filtration methods have been characterized by poor recoveries when processing large-volume samples of environmental water. A method to pre-remove particulates present in turbid waters would be necessary to enhance recovery of protozoan oocysts. Particulate separation can be achieved by the proposed multiplex particle refining (MPR) system. This system employs multiple counter-flow microfiltration units that are arranged into a cascade-like structure. By use of this design, the target oocysts are pre-concentrated from environmental waters. The performance of the MPR system was investigated using 10-L deionized water and surface water spiked with 100 Cryptosporidium parvum oocysts. A recovery rate of around 85% was obtained for spiked river water. The water samples were processed using high flow rate and a simple filtration protocol. Further experiments were conducted using the MPR as a pre-filter for five commercially available filters. The recovery rates were two- to threefold higher employing the pre-filter than using the filters alone. The merit of the refining system to use different numbers of counter-flow units led to superior oocyst recovery rate for the Filta-Max and Envirochek HV filters, which are approved by the US Environmental Protection Agency. This work demonstrates a feasible tool for improved filtration performance in environmental waters.

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A smart fully integrated micromachined separator with soft magnetic micro-pillar arrays for cell isolation

Cited by 59 publications

References 19 publications

Entropy generation and optimization of laminar convective heat transfer and fluid flow in a microchannel with staggered arrays of pin fin structure with tip clearance

Entropy generation and optimization of laminar convective heat transfer and fluid flow in a microchannel with staggered arrays of pin fin structure with tip clearance

A Microfluidic Device for Continuous Sensing of Systemic Acute Toxicants in Drinking Water

A cascade-like silicon filter for improved recovery of oocysts from environmental waters

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