LEADER 03980nam  2200877z- 450 
001 9910557787803321
005 20231214132843.0
035   $a(CKB)5400000000045510
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/68830
035   $a(EXLCZ)995400000000045510
100   $a20202105d2020      |y             0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aBiosensors with Magnetic Nanocomponents
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 electronic resource (170 p.)
311   $a3-03936-680-7 
311   $a3-03936-681-5 
330   $aThe 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.
606   $aHistory of engineering & technology$2bicssc
610   $amagnetic multilayers
610   $amagnetoimpedance
610   $amodeling
610   $amagnetic sensors
610   $amagnetic biosensors
610   $aMagnetoimpedance effect
610   $aamorphous ribbons
610   $apatterned ribbons
610   $ameander sensitive element
610   $amagnetic field sensor
610   $amagnetic nanoparticles
610   $acontrast agent
610   $arelaxation
610   $arelaxation rate
610   $aLangevin model
610   $amagnetic field inhomogeneity
610   $aferrogels
610   $amedical ultrasound
610   $asonography
610   $abiomedical applications
610   $amagnetic polymersomes
610   $amagnetic vesicles
610   $amagnetoactive composites
610   $ananocapsules
610   $acoarse-grained molecular dynamics
610   $acomputer simulation
610   $aspintronics
610   $aCFA
610   $athermoelectric effect
610   $aspin seebeck effect
610   $amagneto-impedance
610   $abiosensor
610   $afinite-element method
610   $amagnetic hyperthermia
610   $aspecific loss power
610   $amagnetic mixed ferrites
610   $ahysteresis losses
610   $athermometric measurements
610   $ananobiotechnology
610   $ananomedicine
610   $atherapeutics
610   $abiosensing
610   $amagnetoelasticity
610   $aprecipitation
610   $amass measurement
610   $achemical sensor
615  7$aHistory of engineering & technology
700   $aKurlyandskaya$b Galina V$4edt$01302783
702   $aKurlyandskaya$b Galina V$4oth
906   $aBOOK
912   $a9910557787803321
996   $aBiosensors with Magnetic Nanocomponents$93026563
997   $aUNINA