Journal Article10.1109/TIM.2016.2619000
Inductive Integrated Biosensor With Extended Operative Range for Detection of Magnetic Beads for Magnetic Immunoassay
Angela Beninato,Valentina Sinatra,Giuseppe Tosto,Maria Eloisa Castagna,Salvatore Petralia,Sabrina Conoci,Salvatore Baglio +6 more
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TL;DR: An improved sensing architecture is proposed here, which allows one to expand the microsensor operative field toward very low bead concentrations, and confirms the suitability of the devices developed for magnetic immunoassay applications.
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Abstract: Biosensors are prominent in several areas, such as medical diagnosis, food preparation, pharmaceutical industries, and clinical analysis; high performances are required in spite of attaining accuracy, sensitivity, low cost, easy handling, and portability, but the major parameter that is always representing a challenge for biosensors is specificity. High sensitivity and specificity can be obtained by combining appropriate transduction methods together with immunoassay techniques. In this paper, integrated inductive biosensors for the magnetic immunoassay process, which use magnetic beads as markers for biomolecules, are presented with potential applications to proteins and DNA measurements. The working principle and a dedicated fabrication technology, which also embeds thermal actuation and control, are described; in particular, an improved sensing architecture is proposed here, which allows one to expand the microsensor operative field toward very low bead concentrations. The sensor characterization results are presented together with the analytical model of the transduction principle; a detection limit of approximately 300 beads has been demonstrated. The microsensor is also capable of operating by measuring up to 450 000 beads with a good linearity. Therefore, the sensor architecture proposed here has been demonstrated for wide operating field with high resolution and good linearity; the results proposed confirm the suitability of the devices developed for magnetic immunoassay applications.
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Citations
Development of magnetic sensor technologies for point-of-care testing: Fundamentals, methodologies and applications
TL;DR: In this review, two kinds of magnetic sensor technologies including magnetoresistance (MR) sensor technology and magnetic induction (MI) sensortechnology are discussed and their fundamentals as well as the applications of lateral flow immunoassay test (LFIT) strips or microfluidic biochips are summarized.
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A giant magnetoimpedance-based separable-type method for supersensitive detection of 10 magnetic beads at high frequency
Tao Wang,Yuyi Chen,Bicong Wang,Yi He,Hengyu Li,Mei Liu,Jinjun Rao,Zhizheng Wu,Shaorong Xie,Jun Luo +9 more
TL;DR: In this paper, a microcavity with a basement thickness of 0.3mm was fabricated by Micro-nano carving technology, and was immobilized on the meander-shaped sensing elements for loading Dynabeads.
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Improved magnetic lateral flow assays with optimized nanotags for point-of-use inductive biosensing
María Salvador,Alvaro Gallo-Cordova,Amanda Moyano,J Carlos Martínez-García,M. Carmen Blanco-López,M. Puerto Morales,Montserrat Rivas +6 more
TL;DR: A strategy is reported that combines nanomagnetic tagging of the analyte of interest with radiofrequency inductive sensing, easy to achieve in friendly and portable format and the optimal nanotag core size is the critical threshold for superparamagnetic behavior.
Highly Enhanced Inductance Sensing Performance of Dual-Quartz Crystal Converter.
Vojko Matko,Miro Milanovič +1 more
TL;DR: The converter can be applied where low inductance measurement, nondestructive testing, impedance change measurement, and magnetic material properties measurement are important and shows improved sensitivity and well-compensated dynamic temperature influence on the converter’s output frequency.
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