Joana Loureiro scite author profile

Since the fundamental discovery of the giant magnetoresistance many spintronic devices have been developed and implemented in our daily life (e.g. information storage and automotive industry). Lately, advances in the sensors technology (higher sensitivity, smaller size) have potentiated other applications, namely in the biological area, leading to the emergence of novel biomedical platforms. In particular the investigation of spintronics and its application to the development of magnetoresistive (MR) biomolecular and biomedical platforms are giving rise to a new class of biomedical diagnostic devices, suitable for bench top bioassays as well as point-of-care and point-of-use devices. Herein, integrated spintronic biochip platforms for diagnostic and cytometric applications, hybrid systems incorporating magnetoresistive sensors applied to neuroelectronic studies and biomedical imaging, namely magneto-encephalography and magneto-cardiography, are reviewed. Also lab-on-a-chip MR-based platforms to perform biological studies at the single molecule level are discussed. Overall the potential and main characteristics of such MR-based biomedical devices, comparing to the existing technologies while giving particular examples of targeted applications, are addressed.

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Magnetoresistive chip cytometer

Loureiro

Andrade

Freitas

et al. 2011

Lab Chip

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Although conventional state-of-the-art flow cytometry systems provide rapid and reliable analytical capacities, they are bulky, expensive and complex. To overcome these drawbacks modern flow cytometers have been developed with enhanced portability for on-site measurements. Unlike external fluorescent/optical detectors, magnetoresistive sensors are micro-fabricated, can be integrated within microfluidic channels, and can detect magnetically labelled cells. This work describes the real-time detection of single magnetically labelled cells with a magnetoresistive based cell cytometer. For Kg1-a cells magnetically labelled with 50 nm CD34 microbeads (Milteny) flowing through a 150 μm wide, 14 μm high microchannel, with speeds around 1 cm s(-1), bipolar signals with an average amplitude of 10-20 μV were observed corresponding to cell events. The number of cells counted by the spin valve cytometer has been compared with that obtained with a hemocytometer. Both methods agree within the respective error bars.

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Challenges and trends in the development of a magnetoresistive biochip portable platform

Martins

Germano

Cardoso

et al. 2010

Journal of Magnetism and Magnetic Materials

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Toward a magnetoresistive chip cytometer: Integrated detection of magnetic beads flowing at cm/s velocities in microfluidic channels

et al. 2009

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Thermoelectric properties of V2O5 thin films deposited by thermal evaporation

Santos

Loureiro

Nogueira

et al. 2013

Applied Surface Science

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Optimization of Cuprous Oxides Thin Films to be used as Thermoelectric Touch Detectors

Figueira

Loureiro

Marques

et al. 2017

ACS Appl. Mater. Interfaces

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The electronic and optical properties of p-type copper oxides (CO) strongly depend on the production technique as it influences the obtained phases: cuprous oxide (CuO) or cupric oxide (CuO), the most common ones. Cu films deposited by thermal evaporation have been annealed in air atmosphere, with temperature between 225 and 375 °C and time between 1 and 4 h. The resultant CO films have been studied to understand the influence of processing parameters in the thermoelectric, electrical, optical, morphological, and structural properties. Films with a CuO single phase are formed when annealing at 225 °C, while CuO single phase films can be obtained at 375 °C. In between, both phases are obtained in proportions that depend on the film thickness and annealing time. The positive sign of the Seebeck coefficient (S), measured at room temperature (RT), confirms the p-type behavior of both oxides, showing values up to 1.2 mV·°C and conductivity up to 2.9 (Ω·m). A simple detector using CuO have been fabricated and tested with fast finger touch events.

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Optimization and Integration of Magnetoresistive Sensors

Freitas

Ferreira

Martins

et al. 2011

SPIN

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This paper addresses challenging issues related to the integration of magnetoresistive (MR) sensors in applications such as magnetic field mapping, magnetic bead detection in microfluidic channels, or biochips. Although sharing the same technological principle for detection (magnetoresistance effect), each application has unique specifications in terms of noise, sensitivity, spatial resolution, electrical robustness or geometric constraints. These differences are of high impact for manufacturing, because some strategies used for sensor optimization compromise the freedom for device architecture. . Downloaded from www.worldscientific.com by FLINDERS UNIVERSITY LIBRARY on 10/05/15. For personal use only. 120 MTJ), opposing the modest 0.5 V measured for a single MTJ sensor. Optimization and Integration of Magnetoresistive Sensors 73 SPIN 2011.01:71-91. Downloaded from www.worldscientific.com by FLINDERS UNIVERSITY LIBRARY on 10/05/15. For personal use only.

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Joana Loureiro

Transparent aluminium zinc oxide thin films with enhanced thermoelectric properties

Spintronic platforms for biomedical applications

Magnetoresistive chip cytometer

Challenges and trends in the development of a magnetoresistive biochip portable platform

Toward a magnetoresistive chip cytometer: Integrated detection of magnetic beads flowing at cm/s velocities in microfluidic channels

Thermoelectric properties of V2O5 thin films deposited by thermal evaporation

Optimization of Cuprous Oxides Thin Films to be used as Thermoelectric Touch Detectors

Optimization and Integration of Magnetoresistive Sensors

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