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200 12$aA collection of technical studies completed for the Computer-aided Acquisition and Logistic Support (CALS) program $efiscal year 1987 Volume 1 of 4 /$fSharon J. Kemmerer
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200 10$aNanotechnologies and Nanomaterials Applied to Chemical Sensors and Biosensors $eApplications to the Environment, Medicine and Health
205   $a1st ed.
210  1$aNewark :$cJohn Wiley & Sons, Incorporated,$d2024.
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327   $aCover -- Title Page -- Copyright Page -- Contents -- Introduction -- Part 1. Nanomaterials, Amplification, Separation, Recognition and Transduction -- Chapter 1. Nanomaterials -- 1.1. Carbon nanomaterials -- 1.1.1. Fullerenes -- 1.1.2. Carbon nanodiamonds (NDs) -- 1.1.3. Carbon quantum dots -- 1.1.4. Carbon nanotubes -- 1.1.5. Graphene -- 1.1.6. Graphene quantum dots -- 1.2. Inorganic nanomaterials -- 1.2.1. Metal nanoparticles -- 1.2.2. Metal nanoclusters (MNCs) -- 1.2.3. Semiconductor QDs -- 1.2.4. Two-dimensional inorganic lamellar nanosheets -- 1.2.5. Metal organic frameworks (MOFs) -- 1.2.6. Methods for manufacturing MOFs -- 1.3. Conclusions -- Chapter 2. Separation and Amplification Techniques -- 2.1. Principle of the PCR technique applied to the concentration amplification of DNA traces -- 2.2. Sequencing techniques -- 2.3. Separation techniques for product mixtures -- 2.3.1. Chromatography techniques -- 2.3.2. Electrophoresis techniques -- 2.4. Conclusions -- Chapter 3. Recognition Principles -- 3.1. The different molecular or chemical identification techniques -- 3.1.1. Ion detection using synthetic ligands -- 3.1.2. Immunological recognition: antibodies, nanobodies and peptides -- 3.1.3. Identification using nucleic acids: aptamers -- 3.1.4. Recognition by molecularly imprinted polymers -- 3.1.5. Recognition followed by transformation: enzymes and catalysts -- 3.1.6. Recognition of gaseous species -- 3.2. Sensor networks and artificial intelligence -- 3.2.1. Basic principles -- 3.2.2. Application to chemical sensors -- 3.3. Conclusions -- Chapter 4. Physico-chemical Transduction Techniques -- 4.1. Electrochemical methods -- 4.1.1. Potentiometric analysis -- 4.1.2. Voltametric analysis -- 4.1.3. Impedancemetry -- 4.2. Piezoelectricity for gravimetric analysis -- 4.2.1. Quartz crystal microbalance -- 4.2.2. Surface acoustic wave sensors.
327   $a4.3. Field effect transistors -- 4.3.1. Operating principle of an FET -- 4.3.2. Main FET devices applied to chemical analysis -- 4.4. Optical and optoelectrochemical detection methods -- 4.4.1. Luminescence of molecules -- 4.4.2. Electrochemiluminescence -- 4.4.3. Photoelectrochemistry -- 4.4.4. Raman scattering spectroscopy -- 4.4.5. Surface- and plasmon-enhanced resonance scattering -- 4.5. Conclusions -- Part 2. Environmental and Biological Sensors -- Chapter 5. Ion and Gas Sensors -- 5.1. Membrane electrodes for potentiometric pH measurement -- 5.2. Ion selective electrodes (ISE) -- 5.2.1. Toward ISEs with very low detection limits -- 5.2.2. Solid contact ISEs -- 5.2.3. Conclusions on ISE electrodes -- 5.3. Gas sensors -- 5.3.1. Gas sensors based on nanostructured metal oxides -- 5.3.2. Gas sensors based on conductive polymers -- 5.3.3. Gas sensors based on two-dimensional thin-film materials -- 5.3.4. Sensor networks and their use in artificial noses -- 5.4. Conclusions -- Chapter 6. Biosensors for Health -- 6.1. Blood sugar, uremia and cholesterol -- 6.1.1. Blood sugar -- 6.1.2. Uremia -- 6.1.3. Cholesterol -- 6.2. Biomarkers -- 6.2.1. Cancer biomarkers -- 6.2.2. Cardiac disease biomarkers -- 6.2.3. Stress biomarkers -- 6.3. Pathogens -- 6.3.1. Virus detection -- 6.3.2. Toxin detection -- 6.4. Conclusions -- Conclusion -- References -- Index -- Other titles from ISTE in Nanoscience and Nanotechnology -- EULA.
330   $aThis comprehensive book explores the application of nanomaterials in chemical sensors and biosensors, highlighting their importance in environmental, medical, and health-related fields. It delves into various types of nanomaterials, including carbon-based and inorganic varieties, and their roles in enhancing sensor technology. The book also covers amplification, separation, recognition, and transduction techniques essential for sensor functionality. Targeted at researchers and professionals in nanotechnology, chemistry, and sensor development, the book aims to provide a detailed understanding of how nanomaterials can improve the sensitivity and specificity of chemical sensors and biosensors.$7Generated by AI.
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700   $aLacaze$b Pierre-Camille$01645716
701   $aPiro$b Benoît$01842233
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