Quantification of protein interactions and solution transport using high-density GMR sensor arrays

Gaster, Richard S.; Xu, Li; Han, Shu‐Jen; Wilson, Robert; Hall, Drew A.; Osterfeld, Sebastian J.; Heng, Yu; Wang, Shan X.

doi:10.1038/nnano.2011.45

Cited by 253 publications

(192 citation statements)

References 53 publications

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“…For more than a decade, several research groups worldwide are focusing on the design and development of MR biosensing platforms for biomolecular recognition as well as detection and quantification of biological entities. [69][70][71][72][73][74][75][76] These applications are based on the giant magnetoresistance (GMR) [GMR multilayers and spin valves (SVs)] and the tunneling magnetoresistance (TMR) effects.…”

Section: -3mentioning

confidence: 99%

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Perspective: Magnetoresistive sensors for biomedicine

Giouroudi

Hristoforou

2018

Journal of Applied Physics

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Currently, there is a plethora of sensors (e.g., electrochemical, optical, and piezoelectric) used in life sciences for either analyte detection or diagnostic purposes, but in the last decade, magnetic biosensors have received extended interest as a promising candidate for the development of next-generation, highly sensitive biomedical platforms. This approach is based on magnetic labeling, replacing the otherwise classic fluorescence labeling, combined with magnetic sensors that detect the stray field of the superparamagnetic markers (e.g., magnetic micro-nanoparticles or magnetic nanostructures). Apart from the increased sensitivity, magnetic biosensors exhibit the unique ability of controlling and modulating the superparamagnetic markers by an externally applied magnetic force as well as the capability of compact integration of their electronics on a single chip. The magnetic field sensing mechanism most widely investigated for applications in life sciences is based on the magnetoresistance (MR) effect that was first discovered in 1856 by Lord Kelvin. However, it is the giant magnetoresistance effect, discovered by Grünberg and Fert in 1988, that actually exhibits the greatest potential as a biosensing principle. This perspective will shortly explain the magnetic labeling method and will provide a brief overview of the different MR sensor technologies (giant magnetoresistive, spin valves, and tunnel magnetoresistive) mostly used in biosensing applications as well as a compact assessment of the state of the art. Newly implemented innovations and their broad-ranging implications will be discussed, challenges that need to be addressed will be identified, and new hypotheses will be proposed.

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Section: -3mentioning

confidence: 99%

“…There, the electrons tunnel across the insulating barrier as a result of a spin dependent tunneling probability that causes an electron flow perpendicular to the plane (CPP). 65,67,71,72 An MTJ can operate as a switch between a low state and a high state of electrical resistance as explained in Ref. 61.…”

Section: -3mentioning

confidence: 99%

Perspective: Magnetoresistive sensors for biomedicine

Giouroudi

Hristoforou

2018

Journal of Applied Physics

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“…The high sensitivity of magnetoresistive sensors to very weak magnetic fields at room temperature is utilised in biomolecular recognition [1][2][3][4][5][6]. Proteins, antibodies or nucleic acids are attached to magnetic nanoparticles or microbeads and employed in detecting a target molecule with the help of conjugating probes immobilised on the surface of the magnetic sensor.…”

Section: Introductionmentioning

confidence: 99%

Magnetic Sensor-Based Detection of Picoliter Volumes of Magnetic Nanoparticle Droplets in a Microfluidic Chip

Jeong¹,

Eu²,

Kim³

et al. 2012

Journal of Magnetics

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We have designed, fabricated and tested an integrated microfluidic chip with a Planar Hall Effect (PHE) sensor. The sensor was constructed by sequentially sputtering Ta/NiFe/Cu/NiFe/IrMn/Ta onto glass. The microfluidic channel was fabricated with poly(dimethylsiloxane) (PDMS) using soft lithography. Magnetic nanoparticles suspended in hexadecane were used as ferrofluid, of which the saturation magnetisation was 3.4 emu/cc. Droplets of ferrofluid were generated in a T-junction of a microfluidic channel after hydrophilic modification of the PDMS. The size and interval of the droplets were regulated by pressure on the ferrofluid channel inlet. The PHE sensor detected the flowing droplets of ferrofluid, as expected from simulation results. The shape of the signal was dependent on both the distance of the magnetic droplet from the sensor and the droplet length. The sensor was able to detect a magnetic moment of 2 × 10 −10 emu at a distance of 10 µm. This study provides an enhanced understanding of the magnetic parameters of ferrofluid in a microfluidic channel using a PHE sensor and will be used for a sample inlet module inside of integrated magnetic lab-on-a-chip systems for the analysis of biomolecules.

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“…Необратимое связывание белка и перевод концентрации белка из 3D-в 2D-измерение с учетом убыли количества белка в растворе за счёт его связывания с поверхностью было описано в [26] следующим соотношением:…”

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“…Адекватной кинетической модели, описывающей вылавливание белка на поверхность при концентрациях ниже 10 -12 M, в доступной литературе нам найти не удалось. В то же время, если оценить время t, необходимое для необратимого вылавливания белков по модели, предложенной в [26], в случае начальной концентрации белка С 0 =10 -16 М для условий эксперимента, описанных в этой работе (объём V=50 мкл, размер активированной площади S=5400 мкм 2 ), то это расчётное время должно составлять t~10 8 с. При этом будет выловлено 90% молекул, изначально находившихся в растворе. Таким образом, согласно этой модели при анализе раствора белков с концентрацией ~10 -16 М практически невозможно зарегистрировать белки за реальное время эксперимента, которое обычно составляет t~3 ч ~10 4 с. Однако, экспериментально показано, что время необратимого АСМ-фишинга HCVcoreAg из объёма V=50 мл при концентрации 10 -16 М составляет на несколько порядков меньше, порядка t=4000 с [28].…”

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Irreversible chemical afm-fishing for the detection of low-copied proteins

IuD

et al. 2014

BIOMED KHIM

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The atomic-force microscopy-based method of irreversible chemical AFM-fishing (AFM-IF ) has been developed for the detection of proteins at ultra-low concentrations in solution. Using this method, a very low concentration of horseradish peroxidase (HRP) protein (10 17 M) was detected in solution. A theoretical model that allows the description of obtained experimental data, is proposed. This model takes into consideration both the transport of the protein from the bulk solution onto the AFM-chip surface and its irreversible binding to the activated area.

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Quantification of protein interactions and solution transport using high-density GMR sensor arrays

Cited by 253 publications

References 53 publications

Perspective: Magnetoresistive sensors for biomedicine

Perspective: Magnetoresistive sensors for biomedicine

Magnetic Sensor-Based Detection of Picoliter Volumes of Magnetic Nanoparticle Droplets in a Microfluidic Chip

Irreversible chemical afm-fishing for the detection of low-copied proteins

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