Based on a popular course at Cold Spring Harbor Laboratory, this new manual assembles cutting-edge protocols, helpful hints, and lecture notes to teach researchers from a wide variety of disciplines the essential methods of proteomics using state-of-the-art instrumentation. Detailed protocols involving protein microarrays, liquid chromatography, high-throughput cloning of expression constructs, IMAC, mass spectrometry, MALDI–TOF, and MudPIT are provided, along with well-illustrated descriptions of experimental procedures and lists of recommended Web sites and reading material. Proteomics: A Cold Spring Harbor Laboratory Course Manualcan be used both as the basis for a course and as a detailed bench manual for those performing indispensable proteomic experiments. It is authored by Andrew J. Link and Joshua LaBaer, both leaders in their fields, who bring complementary expertise to the manual.
Proteomic and Metabolomic Approaches to Biomarker Discovery demonstrates how to leverage biomarkers to improve accuracy and reduce errors in research. Disease biomarker discovery is one of the most vibrant and important areas of research today, as the identification of reliable biomarkers has an enormous impact on disease diagnosis, selection of treatment regimens, and therapeutic monitoring. Various techniques are used in the biomarker discovery process, including techniques used in proteomics, the study of the proteins that make up an organism, and metabolomics, the study of chemical fingerprints created from cellular processes. Proteomic and Metabolomic Approaches to Biomarker Discovery is the only publication that covers techniques from both proteomics and metabolomics and includes all steps involved in biomarker discovery, from study design to study execution. The book describes methods, and presents a standard operating procedure for sample selection, preparation, and storage, as well as data analysis and modeling. This new standard effectively eliminates the differing methodologies used in studies and creates a unified approach. Readers will learn the advantages and disadvantages of the various techniques discussed, as well as potential difficulties inherent to all steps in the biomarker discovery process. A vital resource for biochemists, biologists, analytical chemists, bioanalytical chemists, clinical and medical technicians, researchers in pharmaceuticals, and graduate students, Proteomic and Metabolomic Approaches to Biomarker Discovery provides the information needed to reduce clinical error in the execution of research. - Describes the use of biomarkers to reduce clinical errors in research - Includes techniques from a range of biomarker discoveries - Covers all steps involved in biomarker discovery, from study design to study execution
Written by recognized experts in the study of proteins, Proteomics for Biological Discovery begins by discussing the emergence of proteomics from genome sequencing projects and a summary of potential answers to be gained from proteome-level research. The tools of proteomics, from conventional to novel techniques, are then dealt with in terms of underlying concepts, limitations and future directions. An invaluable source of information, this title also provides a thorough overview of the current developments in post-translational modification studies, structural proteomics, biochemical proteomics, microfabrication, applied proteomics, and bioinformatics relevant to proteomics. Presents a comprehensive and coherent review of the major issues faced in terms of technology development, bioinformatics, strategic approaches, and applications Chapters offer a rigorous overview with summary of limitations, emerging approaches, questions, and realistic future industry and basic science applications Discusses higher level integrative aspects, including technical challenges and applications for drug discovery Accessible to the novice while providing experienced investigators essential information Proteomics for Biological Discovery is an essential resource for students, postdoctoral fellows, and researchers across all fields of biomedical research, including biochemistry, protein chemistry, molecular genetics, cell/developmental biology, and bioinformatics.
In this, the post-genomic age, our knowledge of biological systems continues to expand and progress. As the research becomes more focused, so too does the data. Genomic research progresses to proteomics and brings us to a deeper understanding of the behavior and function of protein clusters. And now proteomics gives way to neuroproteomics as we beg
Still the only concise practical guide to laboratory experiments in proteomics, this new edition now also covers DIGE technology and liquid-chromatography, while the troubleshooting section has been considerably extended. Adopting a practical approach, the authors present the relevant techniques and explain the route to successful experimental design and optimal method selection. They cover such electrophoretic techniques as isoelectric focusing, SDS page, 2-D page, and DIGE, as well as liquid-chromatography techniques, such as ion exchange, affinity chromatography and reversed-phase HPLC. Mass-spectrometric techniques include MALDI, ESI, and FT ICR. Generously illustrated, partly in color, the book also features updates of protocols as well as animations illustrating crucial methodological steps on a companion website.
This issue of Clinics in Laboratory Medicine will focus on Clinical Pathology and is edited by Geza S. Bodor. Topics include, but are not limited to, Steroid measurement / Salivary cortisol measurement, Protein testing by LCMSMS, LCMSMS in the Clinical Laboratory, Laboratory Standards for Clinical LCMSMS, The need to teach LCMSMS to clinical laboratory scientists, MALDI-TOF in the clinical laboratory, MALDI TOF MS in the clinical microbiology laboratory, LCMSMS method development consideration in clinical laboratory practice, Cancer diagnosis using mass spectrometry, Adulteration and LCMSMS drug testing, Diagnosis of inherited metabolic disorders using LCMSMS, Harmonization of LCMSMS protein assays, Vitamin D testing by LCMSMS versus by immunoassay, Pain management testing by LCMSMS, and Development of FDA approved clinical mass spectrometer.
This book fulfils the need to keep up with the high number of innovations in proteomics, and at the same time to warn the readers about the danger of manufacturers and scientists claims around new technologies. Mass spectrometry stands as the core technology in proteomics. The emerging field of targeted proteomics and its potential applications in the cardiovascular arena are also reviewed and discussed. A concluding section highilghts the promise of proteomics in the light of these recent developments. As this technique and its applications have undergone remarkable advances in the past years, recent updates on proteomic applications are covered. Another key concept revealed by proteomic technologies is that the extent of protein post-translational modifications (PTMs) as well as their impact on the phenotype has been underestimated by pre-proteomics science. As such, part of the manual focuses on the emerging role of PTMs in basic cardiovascular sciences and in the clinics. In fact, there is an emerging consensus that the detailed annotation of protein PTMs could lead to a more in-depth representation of biological systems, translating into more specific targets for therapy as well as biomarkers. Moreover, a recent trend is so-called “targeted proteomics”. The approach was awarded the title of “Method of the Year” by Nature in 2013 (see the editorial by Vivien Marx in 1st issue of Nature in Jan 2013). According to a few proteomic scientists the emphasis should not be placed on generating long lists of proteins but lists of proteins with a true biological meaning.
Introduction to the proteome (K. L. Williams, D. F. Hochstrasser). Two-dimensional electrophoresis: the state of the art and future directions (B. R. Herbert, J.-C. Sanchez, L. Bini). large-scale comparative protein modeling ( M. C. Peitsch, N. Guex); Clinical and biomedical applications of proteomics (D. F. Hochstrasser). Biological applications of proteomics (K. L. Williams, V. Pallini). Conclusions (D. F. Hochstrasser, L. Williams). Index.
Mass Spectrometry for the Clinical Laboratory is an accessible guide to mass spectrometry and the development, validation, and implementation of the most common assays seen in clinical labs. It provides readers with practical examples for assay development, and experimental design for validation to meet CLIA requirements, appropriate interference testing, measuring, validation of ion suppression/matrix effects, and quality control. These tools offer guidance on what type of instrumentation is optimal for each assay, what options are available, and the pros and cons of each. Readers will find a full set of tools that are either directly related to the assay they want to adopt or for an analogous assay they could use as an example. Written by expert users of the most common assays found in a clinical laboratory (clinical chemists, toxicologists, and clinical pathologists practicing mass spectrometry), the book lays out how experts in the field have chosen their mass spectrometers, purchased, installed, validated, and brought them on line for routine testing. The early chapters of the book covers what the practitioners have learned from years of experience, the challenges they have faced, and their recommendations on how to build and validate assays to avoid problems. These chapters also include recommendations for maintaining continuity of quality in testing. The later parts of the book focuses on specific types of assays (therapeutic drugs, Vitamin D, hormones, etc.). Each chapter in this section has been written by an expert practitioner of an assay that is currently running in his or her clinical lab. Provides readers with the keys to choosing, installing, and validating a mass spectrometry platform Offers tools to evaluate, validate, and troubleshoot the most common assays seen in clinical pathology labs Explains validation, ion suppression, interference testing, and quality control design to the detail that is required for implementation in the lab
