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by G. MILAZZO and M. BLANK This book contains the lectures of the fourth advanced course Bioelectrochemislry W Neroe-Muscle Function: Bioelectrochemistry, Mechanisms, Energetics and Contro~ which took place at the Majorana Center in Erice, Italy, October 20th to November 1, 1991. The scope of the course was international in terms of both sponsorship and partici pation. Sponsors included the Bioelectrochemical Society, NATO, International Union of Pure and Applied Biophysics (lUPAB), the World Federation of Scientists and the Italian National Research Council. One-third of the sixty participants were from Italy, but the majority came from eighteen other nations. Since the course was part of the International School of Biophysics, the biophysi cal point of view was emphasized in integrating the biology with the electrochemistry. Lecturers were asked to use a quantitative approach with accepted standards and proper units, since this is absolutely essential for developing an effective common language for communication across disciplines. Participants were also urged not to forget that biological systems could also be considered as physical systems. Ion channels are proteins and their properties as polyelectrolytes contribute to the specific biological properties. The existence of families of channels, with very similar structures but different selectivities, suggests that the specificities arise from slight variations of a general basic design. These perspectives on nerve-muscle function helped to make the school course a unique treatment of the subject.
This book presents a collection of chapters on modern bioelectrochemistry, showing different aspects of electron transfer reactions in biological systems and techniques. The chapters cover computer simulation, biomolecules on surfaces, direct and mediated electron transfer, electron transfer kinetics, surface-confined biomolecules, field-effect transistor effects, supramolecular electrochemistry, in situ and operando techniques in bioelectrochemistry. They provide relevant bibliographic information for researchers and students interested in computer simulation involving biomolecules on surfaces, processes of direct and mediated electron transfer kinetics of cytochrome c, surface-confined biomolecules for application in bioelectronics, sensitive devices based on field-effect transistors, insights on supramolecular electrochemistry with recent trends and perspectives and technological innovation on instrumentation applied in operando techniques field.
1.1. Definition of Terms-Thrombosis, Thromboembolic Disease, Atherosclerosis, and Blood Clotting The terms heart attack or myocardial infarction are more commonly used than thrombosis. The infarct-muscle destruction is simply the end result and thrombosis is the real cause of the heart attack. Thrombosis may be defined as the process of formation of a coalescent or agglutinated solid mass of blood components in the blood stream. Thrombi formed in either arteries or veins often cause occlusion in the vascular system and prevent blood flow. Obstruc to the blood vessel usually occurs at the site where the thrombi deposit. tion Furthermore, thrombi may break loose, travel through the circulating blood stream, and cause obstruction at some distal point of narrowing elsewhere. The mass or thrombus that moves is referred to as an "embolus." The two phenomena are lumped together under the term thromboembolic disease. Thrombosis that reduces blood supply to the heart is the primary factor in heart attacks.
This book reviews the latest advances in the bioelectrochemical degradation of recalcitrant environmental contaminants. The first part introduces readers to the basic principles and methodologies of bioelectrochemical systems, electron-respiring microorganisms, the electron transfer mechanism and functional electrode materials. In turn, the second part addresses the bioelectrochemical remediation/treatment of various environmental pollutants (including highly toxic refractory organics, heavy metals, and nitrates) in wastewater, sediment and wetlands. Reactor configuration optimization, hybrid technology amplification and enhanced removal principles and techniques are also discussed. The book offers a valuable resource for all researchers and professionals working in environmental science and engineering, bioelectrochemistry, environmental microbiology and biotechnology.
Bioelectrochemistry: Fundamentals, Experimental Techniques and Application, covers the fundamental aspects of the chemistry, physics and biology which underlie this subject area. It describes some of the different experimental techniques that can be used to study bioelectrochemical problems and it describes various applications of biolelectrochemisty including amperometric biosensors, immunoassays, electrochemistry of DNA, biofuel cells, whole cell biosensors, in vivo applications and bioelectrosynthesis. By bringing together these different aspects, this work provides a unique source of information in this area, approaching the subject from a cross-disciplinary viewpoint.
This book presents a collection of chapters on modern bioelectrochemistry, showing different aspects of materials and electrode processes. The chapters cover biomimetics, bioelectrocatalysis, large-scale biodevices manufacturing, organic semiconductors for biorecognition, biofunctionalization, conducting polymers, carbon-based materials and 3D printed bioelectrochemical devices. They provide relevant bibliographic information for researchers and students interested in biomimetics applied in electrochemistry with impact in bioelectrocatalysis, large-scale deposition techniques applied to biodevices manufacturing and organic semiconductors as support material for electrochemical biorecognition. This book also presents insights on advantages and properties of biofunctionalization, conducting polymers with carbon-based materials in biosensors applications and progress on 3D printed electrochemical devices for sensing and biosensing of biomarkers.
This book presents a collection of chapters on modern bioelectrochemistry, showing different aspects of biodevices. The chapters cover biomedical applications, virus and antigens detection, miniaturized and wearable devices, screen-printed biosensors, hybrids surfaces, point-of-care and molecular diagnoses. They provide relevant bibliographic information for researchers and students interested in field effect transistors for biomedical applications, virus and antigens detection in immuno technologies and biosensors in point-of-care for molecular analysis, with strategies and perspectives to healthcare. This book also presents insights on advantages and properties of materials aiming biosensors applications.
A reflection of the intense study of the effects of electromagnetic fields on living tissues that has taken place during the last decades, Advanced Electroporation Techniques in Biology and Medicine summarizes most recent experimental findings and theories related to permeabilization of biomembranes by pulsed electric fields. Edited by experts and
Volume 1 of this Series is intended to give the reader a fundamental understanding of the key areas deemed essential to the study of bioelec trochemistry. A thorough grasp of the theory and methodology of these basic topics is vital to cope successfully with the complex phenomena that currently face investigators in most bioelectrochemical laboratories. Chapter 1 outlines the nonequilibrium thermodynamics and kinetics of the processes involved, stressing the connection between the two ap proaches. Particular emphasis is placed on the enzymes catalyzing cytosolic reactions and membrane transport. The techniques discussed are sufficient for the study of systems in the steady state, but systems that are evolving towards the steady state, or show some other time-depen dent behavior, require in addition the techniques of mathematical modelling. These are dealt with in some detail in Chapter 2, where network representation of the system is treated at length as the method of choice in carrying out appropriate simulations. In Chapter 3 attention is directed to the twin problems of water structure and ionic hydration.