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Despite substantial evidence showing the feasibility of Atomic Force Microscopy (AFM) to identify cells with altered elastic and adhesive properties, the use of this technique as a complementary diagnostic method remains controversial. This book is designed to be a practical textbook that teaches how to assess the mechanical characteristics of living, individual cells by AFM. Following a step-by-step approach, it introduces the methodology of measurements in the case of both determination of elastic properties and quantification of adhesive properties.
Despite substantial evidence showing the feasibility of Atomic Force Microscopy (AFM) to identify cells with altered elastic and adhesive properties, the use of this technique as a complementary diagnostic method remains controversial. This book is designed to be a practical textbook that teaches how to assess the mechanical characteristics of living, individual cells by AFM. Following a step-by-step approach, it introduces the methodology of measurements in the case of both determination of elastic properties and quantification of adhesive properties.
This is the first book to bring together both the basic theory and proven process engineering practice of AFM. It is presented in a way that is accessible and valuable to practising engineers as well as to those who are improving their AFM skills and knowledge, and to researchers who are developing new products and solutions using AFM. The book takes a rigorous and practical approach that ensures it is directly applicable to process engineering problems. Fundamentals and techniques are concisely described, while specific benefits for process engineering are clearly defined and illustrated. Key content includes: particle-particle, and particle-bubble interactions; characterization of membrane surfaces; the development of fouling resistant membranes; nanoscale pharmaceutical analysis; nanoengineering for cellular sensing; polymers on surfaces; micro and nanoscale rheometry. - Atomic force microscopy (AFM) is an important tool for process engineers and scientists as it enables improved processes and products - The only book dealing with the theory and practical applications of atomic force microscopy in process engineering - Provides best-practice guidance and experience on using AFM for process and product improvement
The natural, biological, medical, and related sciences would not be what they are today without the microscope. After the introduction of the optical microscope, a second breakthrough in morphostructural surface analysis occurred in the 1940s with the development of the scanning electron microscope (SEM), which, instead of light (i. e. , photons) and glass lenses, uses electrons and electromagnetic lenses (magnetic coils). Optical and scanning (or transmission) electron microscopes are called “far-field microscopes” because of the long distance between the sample and the point at which the image is obtained in comparison with the wavelengths of the photons or electrons involved. In this case, the image is a diffraction pattern and its resolution is wavelength limited. In 1986, a completely new type of microscopy was proposed, which, without the use of lenses, photons, or electrons, directly explores the sample surface by means of mechanical scanning, thus opening up unexpected possibilities for the morphostructural and mechanical analysis of biological specimens. These new scanning probe microscopes are based on the concept of near-field microscopy, which overcomes the problem of the limited diffraction-related resolution inherent in conventional microscopes. Located in the immediate vicinity of the sample itself (usually within a few nanometers), the probe records the intensity, rather than the interference signal, thus significantly improving resolution. Since the most we- known microscopes of this type operate using atomic forces, they are frequently referred to as atomic force microscopes (AFMs).
Proceeding from basic fundamentals to applications, this volume provides a comprehensive overview of the use of AFM and related scanning probe microscopies for cell surface analysis. It covers all cell types, from viruses and protoplasts to bacteria and animal cells. It also discusses a range of advanced AFM modalities, including high-resolution imaging, nanoindentation measurements, recognition imaging, and single-molecule and single-cell force spectroscopy. The book covers methodologies for preparing and analyzing cells and membranes of all kinds and highlights recent examples to illustrate the power of AFM techniques in life sciences and nanomedicine.
Summarizing the latest trends and the current state of this research field, this up-to-date book discusses in detail techniques to perform localized alterations on surfaces with great flexibility, including microfluidic probes, multifunctional nanopipettes and various surface patterning techniques, such as dip pen nanolithography. These techniques are also put in perspective in terms of applications and how they can be transformative of numerous (bio)chemical processes involving surfaces. The editors are from IBM Zurich, the pioneers and pacesetters in the field at the forefront of research in this new and rapidly expanding area.
Over the last two decades, Atomic Force Microscopy (AFM) has undoubtedly had a considerable impact in unraveling the structures and dynamics of microbial surfaces with nanometer resolution, and under physiological conditions. Moreover, the continuous innovations in AFM-based modalities as well as the combination of AFM with modern optical techniques, such as confocal fluorescence microscopy or Raman spectroscopy, increased the diversity and volume of data that can be acquired in an experiment. It is evident that these combinations provide new ways to investigate a broad spectrum of microbiological processes at the level of single cells. In this book, I have endeavored to highlight the wealth of AFM-based modalities that have been implemented over the recent years leading to the multiparametric and multifunctional characterization of, specifically, bacterial surfaces. Examples include the real-time imaging of the nanoscale organization of cell walls, the quantification of subcellular chemical heterogeneities, the mapping and functional analysis of individual cell wall constituents, and the probing of the nanomechanical properties of living bacteria. It is expected that in the near future more AFM-based modalities and complementary techniques will be combined into single experiments to address pertinent problems and challenges in microbial research. Such improvements may make it possible to address the dynamic nature of many more microbial cell surfaces and their constituents, including the restructuring of cellular membranes, pores and transporters, signaling of cell membrane receptors, and formation of cell-adhesion complexes. Ultimately, manifold discoveries and engineering possibilities will materialize as multiparametric tools allow systems of increasing complexity to be probed and manipulated.
As analytical chemistry and biology move closer together, biologists are performing increasingly sophisticated analytical techniques on cells. Chemists are also turning to cells as a relevant and important sample to study newly developed methods. Practical Cell Analysis provides techniques, hints, and time-saving tips explaining what may be “common knowledge” to one field but are often hidden or unknown to another. Within this practical guide: The procedures and protocols for cell separation, handling cells on a microscope and for using cells in microfluidic devices are presented. Elements of cell culture are taken and combined with the practical advice necessary to maintain a cell lab and to handle cells properly during an analysis The main chapters deal with the fundamentals and applied aspects of each technique, with one complete chapter focusing on statistical considerations of analyzing cells Many diagram-based protocols for some of the more common cell processes are included Chapter summaries and extensive tables are included so that key information can be looked up easily in the lab setting Much like a good manual or cookbook this book is a useful, practical guide and a handy reference for all students, researchers and practitioners involved in cellular analysis.
Fundamentals and Application of Atomic Force Microscopy for Food Research explains how to get reliable AFM data and current application progress of AFM in different food substances. Sections focus on an Introduction to AFM for food research and Applications of AFM for different types of food substances. Edited by 3 experts in the field of nanotechnology and food science, this book reduces the difficulty of AFM application and shortens the learning time for new hands. Until now, no such book has systematically described the application of Atomic Force Microscopy (AFM) for food research. Many scientists in the field of food science and engineering need to evaluate their developed foods and food contact surfaces at nanoscale. However, there is a steep learning curve for new hands, hence the need for this comprehensive resource. - Describes the application of AFM for food research - Covers applications of AFM for different types of food substances - Addresses future uses and perspectives of AFM for the development of food nanotechnology
This book aims to provide examples of applications of atomic force microscopy (AFM) using biological samples, showing different methods for AFM sample preparation, data acquisition and processing, and avoiding technical problems. Divided into two sections, chapters guide readers through image artifacts, process and quantitatively analyze AFM images, lipid bilayers, image DNA-protein complexes, AFM cell topography, single-molecule force spectroscopy, single-molecule dynamic force spectroscopy, fluorescence methodologies, molecular recognition force spectroscopy, biomechanical characterization, AFM-based biosensor setup, and detail how to implement such an in vitro system, which can monitor cardiac electrophysiology, intracellular calcium dynamics, and single cell mechanics. Written in the highly successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Authoritative and cutting-edge, Atomic Force Microscopy: Methods and Protocols is useful for researchers at different stages, from newcomers to experienced users, interested in new AFM applications.