Switchable Cell Trapping Using Superparamagnetic Beads

Bryan, Matthew T.; Smith, Katherine; Real, Maria E; Bashir, Muhammad; Fry, P. W.; Fischer, Peter; Im, Mi‐Young; Schrefl, T.; Allwood, D. A.; Haycock, John W.

doi:10.1109/lmag.2010.2046143

Cited by 29 publications

(25 citation statements)

References 17 publications

(23 reference statements)

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“…Recent work has shown that, owing to their highly localized stray fields, magnetic domain walls (DWs) in magnetic nanotracks can be used to shuttle individual SPM microbeads and magnetically tagged entities across the surface of a substrate. [17][18][19][20][21][22][23]26 By integrating a single-bead detection mechanism into such DW-based transport structures, microscale sorting and sensing of single cells or biomolecules could be simultaneously achieved in magnetic lab-on-a-chip devices. Magnetoresistive sensors, which exhibit a perturbed response to applied excitation fields due to the presence of beads at the sensor surface, [1][2][3][13][14][15][16][17] form the basis for most SPM bead sensing platforms.…”

Section: Introductionmentioning

confidence: 99%

“…However, sensitivity at the level of individual microbeads has not yet been demonstrated using such a mechanism. Domain walls in nanotracks can be used to reversibly capture and transport SPM microbeads, [17][18][19][20][21][22][23]26 and it was recently shown that DWs can also be used to sense the presence of individual beads. 13,17,26 Llandro et al 13 demonstrated the detection of individual beads by measuring the effect of their stray field on DW-mediated magnetization switching in pseudo-spin-valves.…”

Section: Introductionmentioning

confidence: 99%

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Integrated capture, transport, and magneto-mechanical resonant sensing of superparamagnetic microbeads using magnetic domain walls

2012

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An integrated platform for the capture, transport, and detection of individual superparamagnetic microbeads is described for lab-on-a-chip biomedical applications. Magnetic domain walls in magnetic tracks have previously been shown to be capable of capturing and transporting individual beads through a fluid at high speeds. Here it is shown that the strong magnetostatic interaction between a bead and a domain wall leads to a distinct magneto-mechanical resonance that reflects the susceptibility and hydrodynamic size of the trapped bead. Numerical and analytical modeling is used to quantitatively explain this resonance, and the magneto-mechanical resonant response under sinusoidal drive is experimentally characterized both optically and electrically. The observed bead resonance presents a new mechanism for microbead sensing and metrology. The dual functionality of domain walls as both bead carriers and sensors is a promising platform for the development of labon-a-bead technologies.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Integrated capture, transport, and magneto-mechanical resonant sensing of superparamagnetic microbeads using magnetic domain walls

2012

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“…Superparamagnetic beads are widely used within bioscience to separate, organize and manipulate biomolecules and cells, [1][2][3][4][5][6] and have promising clinical applications as they can be used as MRI contrast agents and in magnetic hyperthermia for the treatment of cancer. 7,8 Typically, they consist of iron oxide (Fe 2 O 3 or Fe 3 O 4 ) nanoparticles embedded in a polymer matrix, which may have an outer coating functionalized for a particular biological application.…”

mentioning

confidence: 99%

“…This has recently been exploited by devices that manipulate beads using stray fields from localized field sources such as closure domains of patterned elements 4,10,11 or domain walls in nanowires. 5,6,12,13 If the beads are attached to cells, the use of nanostructures enables the alignment or pattering of cells, 6 providing a fundamental control over cellular organization, which could generate future tissue engineering applications. In addition, domain walls may be propagated using applied magnetic fields or spin-polarized currents, so biological material attached to the beads can be translated over a pre-defined path.…”

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confidence: 99%

The effect of trapping superparamagnetic beads on domain wall motion

Bryan

Dean

Schrefl

et al. 2010

Applied Physics Letters

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Domain walls may act as localized field sources to trap and move superparamagnetic beads for manipulating biological cells and DNA. The interaction between beads of various diameters and a wall is investigated using a combination of micromagnetic and analytical models. Domain walls can transport beads under applied magnetic fields, but the mutual attraction between the bead and wall causes drag forces affecting the bead to couple into the wall motion. Therefore, the interaction with the bead causes a fundamental change in the domain wall dynamics, reducing the wall mobility by five orders of magnitude.

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“…Recently, the use of domain walls (DWs) in magnetic conduits patterned on a chip has been proven viable to achieve highly controllable motion of single micro and nanoparticles. 125 DWs in magnetic nanostructures provide localized sources of a strong magnetic field gradient used to trap and externally manipulate individual cells. 126 (Fig.…”

Section: B Magnetic Trapsmentioning

confidence: 99%

Microfluidics cell sample preparation for analysis: Advances in efficient cell enrichment and precise single cell capture

et al. 2017

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Single cell analysis has received increasing attention recently in both academia and clinics, and there is an urgent need for effective upstream cell sample preparation. Two extremely challenging tasks in cell sample preparation-highefficiency cell enrichment and precise single cell capture-have now entered into an era full of exciting technological advances, which are mostly enabled by microfluidics. In this review, we summarize the category of technologies that provide new solutions and creative insights into the two tasks of cell manipulation, with a focus on the latest development in the recent five years by highlighting the representative works. By doing so, we aim both to outline the framework and to showcase example applications of each task. In most cases for cell enrichment, we take circulating tumor cells (CTCs) as the target cells because of their research and clinical importance in cancer. For single cell capture, we review related technologies for many kinds of target cells because the technologies are supposed to be more universal to all cells rather than CTCs. Most of the mentioned technologies can be used for both cell enrichment and precise single cell capture. Each technology has its own advantages and specific challenges, which provide opportunities for researchers in their own area. Overall, these technologies have shown great promise and now evolve into real clinical applications. Published by AIP Publishing. [http://dx

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Switchable Cell Trapping Using Superparamagnetic Beads

Cited by 29 publications

References 17 publications

Integrated capture, transport, and magneto-mechanical resonant sensing of superparamagnetic microbeads using magnetic domain walls

Integrated capture, transport, and magneto-mechanical resonant sensing of superparamagnetic microbeads using magnetic domain walls

The effect of trapping superparamagnetic beads on domain wall motion

Microfluidics cell sample preparation for analysis: Advances in efficient cell enrichment and precise single cell capture

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