A major compilation & presentation of amino & DNA sequences produced under the direction of Dr. Elvin A. Kabat, who received a National Medal of Science in 1991, for his "seminal contributions in the field of immunology". Contains new & expanded sections on T-cell reactors, §2-microglobulins, major histocompatibiltiy antigens, complement, thymopoietin, integrins, & post-gamma globulin. Covers 9,000 sequences, plus 3 indices: index of proteins, index of antibody specificities & index of references. Best seller!!
Tabulation and analysis of amino acid and nucleic acid sequences of precursors, v-regions, c-regions, j-chain, T-cell receptors for antigen, T-cell surface antigens, l-microglobulins, major histocompatibility antigens, thy-1, complement, c-reactive protein, thymopoietin, integrins, post-gamma globulin, -macroglobulins, and other related proteins.
Antibodies are indispensable tools for research, diagnosis, and therapy. Recombinant approaches allow the modification and improvement of nearly all antibody properties, such as affinity, valency, specificity, stability, serum half-life, effector functions, and immunogenicity. "Antibody Engineering" provides a comprehensive toolbox covering the well-established basics but also many exciting new techniques. The protocols reflect the latest "hands on" knowledge of key laboratories in this still fast-moving field. Newcomers will benefit from the proven step-by-step protocols, which include helpful practical advice; experienced antibody engineers will appreciate the new ideas and approaches. The book is an invaluable resource for all those engaged in antibody research and development.
This essential work, edited by two researchers at London’s famous Queen Mary’s medical school targets one of the most important areas in medical development today. These days, antibody therapeutics are the treatment of choice for several autoimmune and oncological conditions. They are, indeed, becoming the molecules of choice for further combination therapies and cell engineering. In this timely work, a slew of expert in the field of drug development summarize all the current developments and clinical successes.
The exquisite binding specificity of antibodies has made them valuable tools from the laboratory to the clinic. Since the description of the murine hybridoma technology by Köhler and Milstein in 1975, a phenomenal number of mo- clonal antibodies have been generated against a diverse array of targets. Some of these have become indispensable reagents in biomedical research, while others were developed for novel therapeutic applications. The attractiveness of an- bodies in this regard is obvious—high target specificity, adaptability to a wide range of disease states, and the potential ability to direct the host’s immune s- tem for a therapeutic response. The initial excitement in finding Paul Ehrlich’s “magic bullet,” however, was met with widespread disappointment when it was demonstrated that murine antibodies frequently elicit the human anti-murine an- body (HAMA) response, thus rendering them ineffective and potentially unsafe in humans. Despite this setback, advances in recombinant DNA techniques over the last 15–20 years have empowered the engineering of recombinant antibodies with desired characteristics, including properties to avoid HAMA. The ability to p- duce bulk quantities of recombinant proteins from bacterial fermentation also fueled the design of numerous creative antibody constructs. To date, the United States Food and Drug Administration has approved more than 10 recombinant antibodies for human use, and hundreds more are in the development pipeline. The recent explosion in genomic and proteomic information appears ready to deliver many more disease targets amenable to antibody-based therapy.
