Lntegration, a new paradigm in analytical chemistry; Integration in science and technology; Integration in analytical chemistry; Partsand components; Supportedreagents; Separation membranes; Systems; Total analysis systems; Miniaturised systems; Networked systems; Sensors; Electrochemical sensors; Optochemical sensors; Arraysystems; Redundant-sensor array systems; Selective-sensor array systems; Cross-selective sensor array systems; Microsystems; Microsensors; Analytical microsystems; Array microsystems; Nanosystems; Conclusions and perspectives; lntegrated separation systems; General principIes ofbi-phase separation; Thermodynamics ofbi-phase equilibrium; Integration concepts in bi-phase separation; Integration of uptake and stripping steps; Multiplication of single separation effect; Frontal íon exchange chromatography; Reverse frontal íon exchange chromatography; Displacement chromatography; Tandem íon exchange fractionation; Combined separation techniques; Solvent extraction-ion exchange. Aqua impregnated resins; Ion exchange-crystallisation. Ion exchange isothermal supersaturation; Ion exchange supersaturation of zwitterlites; Ion exchange supersaturation of electrolytes; Solid-phase spectrometric assays; Integration of processes in solid-phase spectrometric assays; Types of solid-phase spectrometric assays; Features of solid-phase spectrometric assays; Particulated solid-phase spectrometric assays; Fixation process; Operational aspects; Analytical characteristics; Mixtures resolution; Analytical applications; Membrane solid-phase spectrometric assays; Membrane filtration systems; Membrane 'problem' equilibration systems; Membrane 'problem' deposit systems; Continuous flow analytical systems; Reverse flow injection; Integrating effect of conventional flow injection units; Confluencepoints; Exchangedunits; Modifiedunits; Duplicateunits; Derivatisation reactions in flow injection systems; Redox reactions involving solid reagents; Micellar media; Photoinduced reactions; Electrogenerated reagents; Catalytic reactions; External energy sources integrated with flow injection; Conventional heat sources; illtrasound energy sources; Use of electrical energy; Microwave energy assistance; In-line coupling of simple non-chromatographic continuous separation units and flow injection manifolds; Couplings with techniques involving gas-separation: gas-diffusers, pervaporators and others; Couplings with liquid-liquid separators: dialysers and liquid-liquid extractors; Couplingswith liquid-solid separators and solid phase formation; On-line separation equipment and flow injection manifolds; On-line coupling of robotics and flow injection manifolds; Detection in flow injection; Flow injection-detector interfaces; Automatic calibration; Special uses of conventional detectors coupled to FI; Three-dimensional and complex detectors coupled to FI; Screening and flow injection Integration and flow injection; Distributed analytical instrumentation systems; Theremoteconcept; Elements in a measurement system; Distributed systems topologies; Theremoteplace; The benefits of distributed intelligence; The computer-controlling function; Virtual instruments; Smart/intelligent sensors; The link; Industrial networks; Ethernet; Wireless links; The local place; Remote analytical instruments/systems: application examples; Laboratory information management systems; The analytical laboratory; Role of an analytical laboratory; Need to increase productivity; The aims oflaboratory automation; Problems with laboratory automation; Solutions for laboratory automation; What is laboratory automation?; A definition oflaboratory automation; Laboratory automation constituent groups; Instrument automation; Communications; Data to information conversion; Information management; A laboratory automation strategy in practice; Laboratory Information Management Systems; What is a LIMS?; A LIMS has two targets; Construction of the LIMS matrix; LIMS matrix views; Organisational integration and LIMS; LIMS and the system development life cycle; System development life cycle; Project proposal; The LIMS project team; User requirements specification and system selection; Functional specification; Qualification of the system; User training and roll-out strategies; Project close-out; Post-implementation review; Enhancement ofthe system and controlling change; Chemically modified electrodes with integrated biomolecules and molecular wires; Enzyme redox catalysis; Redox hydrogels; Self-assembled polyelectrolyte and protein films; Self-assembled enzyme films; Electrocatalysis; Electronhopping; Different molecular architectures; Structure ofself-assembled enzyme films; Atomic force microscopy; Ellipsometry; Combination of QCM and ellipsometric measurements; Infrared spectroscopy (FTIR); Composite and biocomposite materiais forelectrochemicalsensing; Composite electrode materiaIs; Conducting composite; Conducting biocomposites; Composite- and biocomposite-based electrochemical sensors; Conductometric sensors; Potentiometric sensors; Amperometric sensors; Thick-film sensors; Sensors for voltammetric stripping techniques; Optical chemical sensors and biosensor; Sensor structure; Optical fibers; Optoelectronic instrumentation; Molecular recognition element; Sensor designs; Modes of optical signal measurements; Absorbance measurement; Reflectance measurement; Fluorescence measurement; Chemiluminescence measurement; Electronic tongues: new analytical perspective of chemical sensors; General approach to the application of sensor arrays; Why use sensor systems?; Inspirations from chemometrics and biology; Advantages of sensor systems in comparlson with discrete sensors; Specific features of the sensors for the electronictongue; Electronic tongue systems; Sensors; System designs; Hybrid systems; Data processing; Selected applications ofthe electronic tongue; Application areas and analytes; Quantitative analysis; Qualitative analysis, recognition, identification andclassification; Comparison with human perception offlavours; Taste quantification; Application ofhybrid systems; Problems and perspective; A Taste sensor; Structure of the taste sensor; Response characteristics; Aminoacids; Classification oftaste ofamino acids; Discrimination of D-amino acids from L-aminoacids; Quantification ofthe taste of foods; Interaction between taste qualities; Suppression ofbitterness due to phospholipids; Scale ofbitterness; Suppression of bitterness due to taste substances; Detection of wine flavor using taste sensor and electronic nose; Perspective; Application of electronic nose technology for monitoring water and wastewater; Electronic nose technology; Sensor types; Analysis ofelectronic nose data; Electronic nose instrumentation; Sensor array components; Commercial systems; Application to water and wastewater monitoring; Laboratory-based systems; On-line monitoring systems; lntegrated optical transducers for (bio)chemical sensing; Basic concepts; Fundamentals of optical waveguides; Detection principIes: Types of devices; Technologies for integrated optical transducer fabrication; Substrate materiaIs and specific processes; Basic technological processes; Integrated optical sensors; Absorbancesensor; Gratingcoupler; Resonantmirror; Mach-Zehnder interferometer; Towards a total integrated system; High arder hybrid FET module for (bio)chemical andphysicalsensing; Design concepts of(bio)chemical sensor arrays; High arder sensor module based on an identical transducer principIe; Hybrid module design; ISFET fabrication; Measuring system and sensor configurations; Multi-parameter detection of both (bio)chemical and physical quantities using the same transducer principIe; ISFET-based pH sensor; ISFET-based penicillin sensor; ISFET-based temperature sensor; ISFET-based flow-velocity sensor; ISFET-based flow-direction sensor;ISFET-based diffusion-coefficient sensor; ISFET-based bioelectronic sensor; Applications of the hybrid sensor module; pH determination in human urine; pH measurement in rain droplets; Summary and conclusion; Microdialysis based lab-on-a-chip, applying a generic MEM Stechnology; The need for in vivo monitoring; Microdialysis; The microdialysis lab-on-a-chip; The micromachined double lumen microdialysis probe connector; The conventional microdialysis probe; Experimental; Results and discussion; The passive and the active calibration system; Passive contraI of a calibration plug; Active contraI of a calibration plug; Closed-loop controlled electrochemically actuated microdosing system; The flow-through potentiometric and amperometric sensor array; The flow-through potentiometric sensorarray; The flow-through reference electrode; The flow-through amperometric sensor; The integrated microdialysis-based lab-on-a-chip; The complete integrated microdialysis lab-on-a-chip; Measurements; Design methodology for a lab-on-a-chip for chemical analysis: the MAFIAS chip; The design path; The design; Chemistry; System schematics; Channel geometry; Specifications for the components; Thecomponents; Nanosensor and nanoprobe systems for in vivo bioanalysis; Background on biosensors and bioreceptors; Biosensing systems; Bioreceptor probes; Fiberoptics nanosensor system; Fabrication of the fiberoptic nanoprobe; Immobilization of receptors onto fiber nanoprobes; Experimental system and protocol for nanoprobe investigation of single cells; Optical measurement system; Applications in bioanalysis; Optical nanofiber probes for fluorescence measurements; Single-cell measurements using antibody-based nanoprobes.

Microdroplet technology has recently emerged to provide new and diverse applications via microfluidic functionality, especially in various areas of biology and chemistry. This book, then, gives an overview of the principle components and wide-ranging applications for state-of-the-art of droplet-based microfluidics. Chapter authors are internationally-leading researchers from chemistry, biology, physics and engineering that present various key aspects of micrdroplet technology -- fundamental flow physics, methodology and components for flow control, applications in biology and chemistry, and a discussion of future perspectives. This book acts as a reference for academics, post-graduate students, and researcher wishing to deepen their understand of microfluidics and introduce optimal design and operation of new droplet-based microfluidic devices for more comprehensive analyte assessments.

Micro- and Nanotechnology Enabled Applications for Portable Miniaturized Analytical Systems outlines the basic principles of miniaturized analytical devices, such as spectrometric, separation, imaging and electrochemical miniaturized instruments. Concepts such as smartphone-enabled miniaturized detection systems and micro/nanomachines are also reviewed. Subsequent chapters explore the emerging application of these mobile devices for miniaturized analysis in various fields, including medicine and biomedicine, environmental chemistry, food chemistry, and forensic chemistry. This is an important reference source for materials scientists and engineers wanting to understand how miniaturization techniques are being used to create a range of efficient, sustainable electronic and optical devices. Miniaturization describes the concept of manufacturing increasingly smaller mechanical, optical, and electronic products and devices. These smaller instruments can be used to produce micro- and nanoscale components required for analytical procedures. A variety of micro/nanoscale materials have been synthesized and used in analytical procedures, such as sensing materials, sorbents, adsorbents, catalysts, and reactors. The miniaturization of analytical instruments can be applied to the different steps of analytical procedures, such as sample preparation, analytical separation, and detection, reducing the total cost of manufacturing the instruments and the needed reagents and organic solvents. - Outlines how miniaturization techniques can be used to create new optical and electronic micro- and nanodevices - Explores major application areas, including biomedicine, environmental science and security - Assesses the major challenges of using miniaturization techniques

This book covers all the steps in order to fabricate a lab-on-a-chip device starting from the idea, the design, simulation, fabrication and final evaluation. Additionally, it includes basic theory on microfluidics essential to understand how fluids behave at such reduced scale. Examples of successful histories of lab-on-a-chip systems that made an impact in fields like biomedicine and life sciences are also provided. This book also: · Provides readers with a unique approach and toolset for lab-on-a-chip development in terms of materials, fabrication techniques, and components · Discusses novel materials and techniques, such as paper-based devices and synthesis of chemical compounds on-chip · Covers the four key aspects of development: basic theory, design, fabrication, and testing · Provides readers with a comprehensive list of the most important journals, blogs, forums, and conferences where microfluidics and lab-on-a-chip news, methods, techniques and challenges are presented and discussed, as well as a list of companies providing design and simulation support, components, and/or developing lab-on-a-chip and microfluidic devices.

The Fifth International Conference on Micro Total Analysis Systems, also known as JlTAS 2001, will highlight the latest exciting events in the world ofminiaturized devices and systems for performing chemical and biochemical experimentation This conference has become mandatory for those of us working in this field as it is indeed helping to define our discipline. We are grateful to the people of the MESA Research Institute of the University of Twente, particularly Piet Bergveld and Albert van den Berg, for starting this meeting in 1994. Their original intention was for the JlTAS meeting to be a small informal workshop. This workshop flavor was sustained through the second meeting held in Basel in 1996, but already in 1998 at the third meeting in Banff it was clear that the "workshop" had become a conference with 420 attendees. It was due to this clearly growing interest in microchemical systems that it was decided we should consider gradually moving toward an annual format and prepare for the possibility that the meeting would increase in popularity. Albert van den Berg was still yearning for a workshop at the JlTAS 2000 meeting and planned a single session format. Again there was a large increase in submitted abstracts (more than 230 total) and a further increase in attendance. The JlTAS steering committee again agreed that we would have to prepare to address the demand the meeting was receiving.

Integrated Analytical Approaches for Pesticide Management provides proven laboratory practices/examples and methods necessary to control pesticides in food and water in various environments. The book presents insights into good laboratory practices and examples of methods used in individual specialist laboratories, thus enabling stakeholders in the agri-food industry to appreciate the importance of proven, reliable data and the associated quality assurance approaches for end product testing for toxic levels of contaminant residues in food. The book is written in a rigorous, but simple, way to make sure that a broad range of readers can appreciate its technical content. The book's practical nature and generic guidelines distinguish it from others in the marketplace. - Provides coverage of risk assessment and effective testing technologies - Covers generic guidelines on pesticide analysis on different environmental matrices for use in the developed and developing world - Presents the most up-to-date information in research sample testing preparation and method validation to detect pesticide residues in food - Includes examples of each method for practical application - Demonstrates proven, reliable research data and the associated quality assurance approaches for end product testing for food, water and soil sediment - Describes the concept of integrated analytical approaches for pesticide management practices