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200 00$aImplantable bioelectronics /$fedited by Evgeny Katz
210  1$aWeinheim, Germany :$cWiley-VCH,$d[2014]
210  4$dİ2014
215   $a1 online resource (473 p.)
300   $aDescription based upon print version of record.
311   $a3-527-33525-0 
320   $aIncludes bibliographical references and index.
327   $aImplantable Bioelectronics; Contents; Preface; List of Contributors; Chapter 1 Implantable Bioelectronics - Editorial Introduction; References; Chapter 2 Magnetically Functionalized Cells: Fabrication, Characterization, and Biomedical Applications; 2.1 Introduction; 2.2 Magnetic Microbial Cells; 2.2.1 Direct Deposition of MNPs onto Microbial Cells; 2.2.2 Polymer-Mediated Deposition of MNPs onto Microbial Cells; 2.2.2.1 Layer-by-Layer Magnetic Functionalization of Microbial Cells; 2.2.2.2 Single-step Polymer-mediated Magnetic Functionalization of Microbial Cells
327   $a2.2.3 Applications of Magnetically Modified Microbial Cells2.2.3.1 Biosorbents and Biocatalysts; 2.2.3.2 Whole-Cell Biosensors and Microfluidic Devices; 2.2.3.3 Remotely Controlled Organisms; 2.3 Magnetic Labeling of Mammal (Human) Cells; 2.3.1 Intracellular Labeling of Cells; 2.3.1.1 Labeling with Anionic Magnetic Nanoparticles; 2.3.1.2 Labeling with Cationic Magnetic Nanoparticles; 2.3.2 Extracellular Labeling of Cells; 2.3.3 Applications of Magnetically Labeled Cells in Biomedicine; 2.3.3.1 MRI Imaging of MNPs-Labeled Cells; 2.3.3.2 MNPs-Mediated Cell Delivery and Tissue Engineering
327   $a2.4 ConclusionAcknowledgment; References; Chapter 3 Untethered Insect Interfaces; 3.1 Introduction; 3.2 Systems for Tetherless Insect Flight Control; 3.2.1 Various Approaches to Tetherless Flight Control; 3.2.2 Neurostimulation for Initiation of Wing Oscillations; 3.2.3 Extracellular Stimulation of the Muscles to Elicit Turns; 3.3 Implantable Bioelectronics in Insects; 3.3.1 Example: Insertion of Flexible Substrates into the Developing Eye; 3.4 Conclusions; References; Chapter 4 Miniaturized Biomedical Implantable Devices; 4.1 Introduction
327   $a4.2 Energy Harvesting as a Pathway to Miniaturization4.3 Implementation of Implantable Devices; 4.3.1 RF Power Harvesting; 4.3.1.1 Matching Network; 4.3.1.2 Rectifier; 4.3.1.3 Regulator and Bandgap Reference; 4.3.1.4 Low-Power Controller and Auxiliary Circuits in the Implant Functional Block; 4.3.2 Wireless Communication Link; 4.3.2.1 Forward Data Link; 4.3.2.2 Reverse Data Link; 4.3.3 Payload and Applications: Locomotive Implant and Implantable Cardiac Probe; 4.3.3.1 Actuation for Therapeutics: Millimeter-Sized Wirelessly Powered and Remotely Controlled Locomotive Implant
327   $a4.3.3.2 Low-Power Sensing for Diagnostics: Implantable Intracardiac Probe4.4 Conclusion; References; Chapter 5 Cross-Hierarchy Design Exploration for Implantable Electronics; 5.1 Introduction; 5.2 System Overview of a Generic Bioelectronic Implant; 5.3 Circuit Design for Low-Power Signal Processing; 5.3.1 Design Challenges for Low-Power Bioelectronic Sensor Interface; 5.3.2 Analog Signal Processing Using Subthreshold Circuits; 5.3.3 Analog-to-Digital Conversion; 5.3.4 Low-Power Digital Signal Processing; 5.3.4.1 VDD Scaling and Parallel Processing
327   $a5.3.4.2 Dynamic Voltage and Frequency Scaling
330   $aHere the renowned editor Evgeny Katz has chosen contributions that cover a wide range of examples and issues in implantable bioelectronics, resulting in an excellent overview of the topic. The various implants covered include biosensoric and prosthetic devices, as well as neural and brain implants, while ethical issues, suitable materials, biocompatibility, and energy-harvesting devices are also discussed.A must-have for both newcomers and established researchers in this interdisciplinary field that connects scientists from chemistry, material science, biology, medicine, and electrical eng
606   $aBioelectronics
606   $aMedical electronics
615  0$aBioelectronics.
615  0$aMedical electronics.
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