On-chip microfluidic biosensor using superparamagnetic microparticles

Keplinger, Franz; Giouroudi, Ioanna

doi:10.1063/1.4826546

Cited by 19 publications

(18 citation statements)

References 26 publications

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“…12 The magnetic elements can be either passive or active; passive elements are usually softferromagnetic structures, [13][14][15][16][17][18] while active elements are microelectromagnets. [19][20][21][22][23][24][25] Soft-ferromagnetic structures can be magnetized by applying an external magnetic field and demagnetized by removing the field. They usually provide stronger magnetic fields than micro-electromagnets and are employed to spatially concentrate magnetic fields.…”

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confidence: 99%

Isolation of cells for selective treatment and analysis using a magnetic microfluidic chip

et al. 2014

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This study describes the development and testing of a magnetic microfluidic chip (MMC) for trapping and isolating cells tagged with superparamagnetic beads (SPBs) in a microfluidic environment for selective treatment and analysis. The trapping and isolation are done in two separate steps; first, the trapping of the tagged cells in a main channel is achieved by soft ferromagnetic disks and second, the transportation of the cells into side chambers for isolation is executed by tapered conductive paths made of Gold (Au). Numerical simulations were performed to analyze the magnetic flux and force distributions of the disks and conducting paths, for trapping and transporting SPBs. The MMC was fabricated using standard microfabrication processes. Experiments were performed with E. coli (K12 strand) tagged with 2.8 μm SPBs. The results showed that E. coli can be separated from a sample solution by trapping them at the disk sites, and then isolated into chambers by transporting them along the tapered conducting paths. Once the E. coli was trapped inside the side chambers, two selective treatments were performed. In one chamber, a solution with minimal nutrition content was added and, in another chamber, a solution with essential nutrition was added. The results showed that the growth of bacteria cultured in the second chamber containing nutrient was significantly higher, demonstrating that the E. coli was not affected by the magnetically driven transportation and the feasibility of performing different treatments on selectively isolated cells on a single microfluidic platform.

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Isolation of cells for selective treatment and analysis using a magnetic microfluidic chip

et al. 2014

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“…The reason for the decrease in velocity of the BLMPs has been sufficiently analyzed in ref. 28 and is based on the overall volumetric increase while the magnetic volume remains constant; the same does not apply for the ALMPs.…”

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confidence: 99%

A microfluidic, dual-purpose sensor for in vitro detection of Enterobacteriaceae and biotinylated antibodies

et al. 2016

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In this paper, we present a versatile, dual-purpose sensor for in vitro detection of Enterobacteriaceae (e.g. Escherichia coli) and biotinylated antibodies (e.g. IgG rabbit polyclonal antibodies), based on different detection principles for each bioanalyte. These bioanalytes are tagged individually with functionalized magnetic microparticles, suspended into a static fluid and injected into a microfluidic channel. Without the need for bulk or complicated pumping systems, the functionalized microparticles are set in motion by a magnetic force exerted on them by integrated microconductors. The fundamental detection principle is the decrease in the velocity of the microparticles that are loaded with the respective bioanalyte, due to factors inhibiting their motion. The velocity of the unloaded, bare microparticles is used as a reference. We discovered a novel mechanism on which the constrained particle motion is based; in the case of E. coli, the inhibiting factor is the enhanced Stokes' drag force due to the greater volume and altered hydrodynamic shape, whereas in the case of biotinylated antibodies, it is the increased friction force at the interface between the modified microparticle and the biosensor's surface. Friction force is for the first time employed in a scheme for resolving biomolecules. Integrated magnetic microsensors are used for the velocity measurements by detecting the microparticles' stray field. Moreover, we developed a biocompatible, easy to implement and reliable surface modification that practically diminishes the problem of bioadhesion on the sensor's surface.

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“…In fact, magnetic nanoparticles have become an attractive tool for on-chip cell separation and detection techniques (Gijs et al, 2010, Laurent et al, 2008, Pankhurst et al, 2003 because they can selectively bind to biological entities of interest, including nucleic acids, proteins, viruses, bacteria and cells, and can be used to detect and separate with high efficiency and purity. For instance, an integrated magnetic biosensor system combined with biofunctionalized, superparamagnetic nanoparticles has recently been used to identify biological species and pathogens within microfluidic devices (Kokkinis et al, 2013). Magnetic cell separation systems are commercially available products that use magnetic nanoparticles to capture and purify rare cell types out of complex samples (Miltenyi et al, 1990).…”

Section: Sensing Strategies For Microfluidic Cell Analysis Systemsmentioning

confidence: 99%

Recent advances and future applications of microfluidic live-cell microarrays

Rothbauer

Wartmann

Charwat

et al. 2015

Biotechnology Advances

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On-chip microfluidic biosensor using superparamagnetic microparticles

Cited by 19 publications

References 26 publications

Isolation of cells for selective treatment and analysis using a magnetic microfluidic chip

Isolation of cells for selective treatment and analysis using a magnetic microfluidic chip

A microfluidic, dual-purpose sensor for in vitro detection of Enterobacteriaceae and biotinylated antibodies

Recent advances and future applications of microfluidic live-cell microarrays

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