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Biosensors with Magnetic Nanocomponents

The selective and quantitative detection of biocomponents is greatly requested in biomedical applications and clinical diagnostics. Many traditional magnetic materials are not suitable for the ever-increasing demands of these processes. The push for a new generation of microscale sensors for bioappl...

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Guardat en:
Format: Online
Idioma:anglès
Publicat: MDPI - Multidisciplinary Digital Publishing Institute 2021
Matèries:
magnetic multilayers
magnetoimpedance
modeling
magnetic sensors
magnetic biosensors
Magnetoimpedance effect
amorphous ribbons
patterned ribbons
meander sensitive element
magnetic field sensor
magnetic nanoparticles
contrast agent
relaxation
relaxation rate
Langevin model
magnetic field inhomogeneity
ferrogels
medical ultrasound
sonography
biomedical applications
magnetic polymersomes
magnetic vesicles
magnetoactive composites
nanocapsules
coarse-grained molecular dynamics
computer simulation
spintronics
CFA
thermoelectric effect
spin seebeck effect
magneto-impedance
biosensor
finite-element method
magnetic hyperthermia
specific loss power
magnetic mixed ferrites
hysteresis losses
thermometric measurements
nanobiotechnology
nanomedicine
therapeutics
biosensing
magnetoelasticity
precipitation
mass measurement
chemical sensor
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
Accés en línia:ONIX_20210501_9783039366804_576
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Sumari:The selective and quantitative detection of biocomponents is greatly requested in biomedical applications and clinical diagnostics. Many traditional magnetic materials are not suitable for the ever-increasing demands of these processes. The push for a new generation of microscale sensors for bioapplications continues to challenge the materials science community to develop novel nanostructures that are suitable for such purposes. The principal requirements of a new generation of nanomaterials for sensor applications are based on well-known demands: high sensitivity, small size, low power consumption, stability, quick response, resistance to aggressive media, low price, and easy operation by nonskilled personnel. There are different types of magnetic effects capable of creating sensors for biology, medicine, and drug delivery, including magnetoresistance, spin valves, Hall and inductive effects, and giant magnetoimpedance. The present goal is to design nanomaterials both for magnetic markers and sensitive elements as synergetic pairs working in one device with adjusted characteristics of both materials. Synthetic approaches using the advantages of simulation methods and synthetic materials mimicking natural tissue properties can be useful, as can the further development of modeling strategies for magnetic nanostructures.

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