06151nam 2201645z- 450 991036756850332120231214133545.03-03921-320-2(CKB)4100000010106061(oapen)https://directory.doabooks.org/handle/20.500.12854/54479(EXLCZ)99410000001010606120202102d2019 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierNeural Microelectrodes: Design and ApplicationsMDPI - Multidisciplinary Digital Publishing Institute20191 electronic resource (378 p.)3-03921-319-9 Neural electrodes enable the recording and stimulation of bioelectrical activity in the nervous system. This technology provides neuroscientists with the means to probe the functionality of neural circuitry in both health and disease. In addition, neural electrodes can deliver therapeutic stimulation for the relief of debilitating symptoms associated with neurological disorders such as Parkinson’s disease and may serve as the basis for the restoration of sensory perception through peripheral nerve and brain regions after disease or injury. Lastly, microscale neural electrodes recording signals associated with volitional movement in paralyzed individuals can be decoded for controlling external devices and prosthetic limbs or driving the stimulation of paralyzed muscles for functional movements. In spite of the promise of neural electrodes for a range of applications, chronic performance remains a goal for long-term basic science studies, as well as clinical applications. New perspectives and opportunities from fields including tissue biomechanics, materials science, and biological mechanisms of inflammation and neurodegeneration are critical to advances in neural electrode technology. This Special Issue will address the state-of-the-art knowledge and emerging opportunities for the development and demonstration of advanced neural electrodes.Neural Microelectrodesclosed-loopin vivo imagingeducationthermoresistanceneural probeelectroless platingneural stimulation and recordingperipheral nerve stimulationshape-memory-polymerartifactsensor interfacemagnetic couplingneuroprostheticsintracortical implantµECoGneural interfacesimplantableelectrochemistryshape memory polymerneurosciencemicromachinemicroelectromechanical systemsstiffnessParylene Cintracranial electrodeschronic implantationneural interfacingmicroelectrodesmultiplexingmicrostimulatorsfreely-behavingwindowed integration samplingsystem-on-chipbrain-machine interfacesinsertion forcemicroelectrode arrayvagus nervediversitymicro-electromechanical systems (MEMS) technologiesmixed-signal feedbacktemperature monitoringforeign body reactionperipheral nervesbrain-computer interfacemulti-disciplinaryneurotechnologyphotolithographymicro-electrocorticographyrobust microelectrodeconscious recordingelectrode arraydopaminesofteningsciatic nervebio-inspiredneural prosthesesneuroscientific researchbidirectionalLED chipmicrofluidic deviceelectrode-tissue interfaceimpedanceintracorticalsilicon carbidethree-dimensionalbiasmicro-electromechanical systems (MEMS)silicon neural probeselectrode degradationchronicmicroelectrodebiocompatibilityoptogeneticsfast-scan cyclic voltammetry (FSCV)glial encapsulationdeep brain stimulationelectrocorticographyelectrophysiologyfast scan cyclic voltammetryprecision medicinemicrofabricationBRAIN Initiativepolymermagnetic resonance imagingpolymer nanocompositeliquid crystal elastomersilicon probetrainingtissue responsegrapheneelectrodeglassy carbon electrodeimmune responseelectrode implantationdextranimmunohistochemistryneural interface responseamorphous silicon carbideUtah electrode arraysneural amplifierneural electrode arrayneuromodulationin vivo electrophysiologyneuronal recordingsneural recordingECoGgene modificationneural interfacewirelessenteric nervous systemcellulose nanocrystalsPancrazio Josephauth1329494Cogan StuartauthBOOK9910367568503321Neural Microelectrodes: Design and Applications3039512UNINA