Magnetic Cell Separation


Book Description

Cell separation is at the core of current methods in experimental biology and medicine. Its importance is illustrated by the large number of physical and biochemical principles that have been evaluated for application to cell separation. The development of cell separation methods is driven by the needs of biological and medical research, and the ever-increasing demands for sensitivity, selectivity, yield, timeliness and economy of the process. The interdisciplinary nature of research in this area and the volume of information available in research publications and conferences necessitates a basic description of the fundamental processes involved in magnetic cell separation that may help the user in navigating this wealth of information available online and in scientific publications. This book will appeal to researchers in many areas utilizing this technique, including those working in cell biology, clinical research, inorganic chemistry, biochemistry, chemical engineering, materials science, physics and electrical engineering. - Provides examples of how to calculate the volume magnetic susceptibility, a fundamental quantity for calculating the magnetic force acting on a cell, from various types of magnetic susceptibilities available in literature - Introduces the elements of magnetostatics as they apply to cell magnetization and the magnetization of magnetic micro- and nano- particles used for cell separation - Describes the parameters used to determine cell magnetophoresis




Biochemistry and Cell Culture


Book Description

Cell biology spans among the widest diversity of methods in the biological sciences. From physical chemistry to microscopy, cells have given up with secrets only when the questions are asked in the right way! This new volume of Methods in Cell Biology covers laboratory methods in cell biology, and includes methods that are among the most important and elucidating in the discipline, such as transfection, cell enrichment and magnetic batch separation. Covers the most important laboratory methods in cell biology Chapters written by experts in their fields.







Laboratory Methods in Cell Biology: Imaging


Book Description

Cell biology spans among the widest diversity of methods in the biological sciences. From physical chemistry to microscopy, cells have given up with secrets only when the questions are asked in the right way! This new volume of Methods in Cell Biology covers laboratory methods in cell biology, and includes methods that are among the most important and elucidating in the discipline, such as bioluminescent imaging of gene expressions, confocal imaging, and electron microscopy of bone. - Covers the most important laboratory methods in cell biology - Chapters written by experts in their fields




Computational Methods in Cell Biology


Book Description

Computational methods are playing an ever increasing role in cell biology. This volume of Methods in Cell Biology focuses on Computational Methods in Cell Biology and consists of two parts: (1) data extraction and analysis to distill models and mechanisms, and (2) developing and simulating models to make predictions and testable hypotheses. Focuses on computational methods in cell biology Split into 2 parts--data extraction and analysis to distill models and mechanisms, and developing and simulating models to make predictions and testable hypotheses Emphasizes the intimate and necessary connection with interpreting experimental data and proposing the next hypothesis and experiment




Methods in Cell Biology


Book Description

Methods in Cell Biology




Quantitative Imaging in Cell Biology


Book Description

This new volume, number 123, of Methods in Cell Biology looks at methods for quantitative imaging in cell biology. It covers both theoretical and practical aspects of using optical fluorescence microscopy and image analysis techniques for quantitative applications. The introductory chapters cover fundamental concepts and techniques important for obtaining accurate and precise quantitative data from imaging systems. These chapters address how choice of microscope, fluorophores, and digital detector impact the quality of quantitative data, and include step-by-step protocols for capturing and analyzing quantitative images. Common quantitative applications, including co-localization, ratiometric imaging, and counting molecules, are covered in detail. Practical chapters cover topics critical to getting the most out of your imaging system, from microscope maintenance to creating standardized samples for measuring resolution. Later chapters cover recent advances in quantitative imaging techniques, including super-resolution and light sheet microscopy. With cutting-edge material, this comprehensive collection is intended to guide researchers for years to come. Covers sections on model systems and functional studies, imaging-based approaches and emerging studies Chapters are written by experts in the field Cutting-edge material




Cancer Cell Culture


Book Description

The culture of cancer cells is routinely practiced in many academic research centers, biotechnology companies, and hospital laboratories. Cancer Cell Culture: Methods and Protocols describes easy-to-follow methods to guide both novice and more experienced researchers seeking to use new techniques in their laboratories. Our present understanding of the cell and molecular biology of cancer has been derived mainly from the use of cultured cancer cells and we cover a number of the most widely used assays to study function in current use. Part I introduces the basic concept of cancer cell culture and this is followed by a description of the general techniques used in many cell culture facilities. The importance of cell line characterization is now widely recognized and methods to characterize and authenticate cell lines are described in Part II. Part III covers the isolation and development of specific cancer cell types and provides valuable tips for those wishing to derive new cell line models. A wide range of procedures encompassing many of the key functional features of cancer cells are described in Part IV including assays to evaluate clonogenicity, cell proliferation, apoptosis, adhesion, migration, invasion, senescence, angiogenesis, and cell cycle parameters. Methods to modify cancer cells are described in Part V, including protocols for transfection, development of drug-resistance, immortalization, and transfer in vivo. In Part VI methods of coculture of different cell types and contamination of cell lines are covered.




Cell Biology


Book Description

Cell Biology: A Laboratory Handbook, Volume 3 is a handbook on cell biology and covers topics ranging from transfer of macromolecules and small molecules to cloning of embryos, transgenics, and gene targeting. Cell-free extracts, permeabilized cell systems, and expression systems are also discussed, along with proteins. Comprised of 58 chapters, this volume begins with a detailed account of microinjection of RNA, DNA, and proteins into somatic cells, followed by an analysis of computer-automated capillary microinjection of macromolecules into living cells. The reader is then introduced to syringe loading as a method for inserting macromolecules into cells in suspension; electroporation of cells; and the use of liposomes in drug targeting. Subsequent chapters focus on the cloning of rabbit embryos by nuclear transplantation; gene targeting by homologous recombination in embryonic stem cells; production and isolation of recombinant viruses; and gel electrophoresis. This book will be of interest to geneticists and molecular biologists.




Mammalian Cell Viability


Book Description

Whether the question is one of basic cell survival, or whether it is being used to correlate cell number to some other factor such as matrix synthesis, an estimate of cell viability is universally required. In Mammalian Cell Viability: Methods and Protocols, experts in the field describe methods from the most basic which can be performed in any laboratory, to some which require specific pieces of equipment. Initially focusing on methods for monolayer and suspension cells, later chapters describe methods for determining viability within tissue sections and 3 dimensional culture systems. Finally, methods requiring highly specialized equipment are described in order to explain what is possible. Written in the highly successful Methods in Molecular BiologyTM series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and vital tips on troubleshooting and avoiding known pitfalls. Practical and adaptable, Mammalian Cell Viability: Methods and Protocols serves as a self-contained laboratory manual useful to both experienced researchers and those new to this incredibly important and influential field.