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Chemokines and Cancer synthesizes a state-of-the-art understanding of the role that chemokines and their receptors play in the pathophysiology of malignancy.
Chemokines and Cancer synthesizes a state-of-the-art understanding of the role that chemokines and their receptors play in the pathophysiology of malignancy.
Exciting new developments and discoveries of the last two decades are beginning to shed light on the complex biology of brain tumors and are advancing our understa- ing of the cellular and molecular processes involved in their initiation, progression, and clinical and biological behavior. The disease process in brain tumors is quite complex and the resulting tumors are characterized by a high degree of biological and clinical diversity. Thus, despite the advances of the last two decades, prognosis for patients with malignant brain tumors remains abysmal. Significant progress in the diagnosis, treatment and, ultimately, prevention of these tumors will require both the timely h- nessing of the advances in basic and clinical brain tumor research, and a continuing concerted effort at increasing our understanding of brain tumor biology, in particular, the molecular genetic changes and perturbations of cellular pathways involved in brain oncogenesis and which drive the biological and clinical behavior of the tumors. Brain tumor diagnosis and prognosis, which is still largely based on histopathology and other clinical criteria, will, in the future, acquire a significant molecular component, with the incorporation of knowledge of genes that are mutated, over-expressed, deleted, silenced, or functionally altered in the tumors. Treatment strategies for brain tumors, rather than being empirical, will be rationally developed based on an understanding of the cellular and molecular mechanisms and targets that have been activated, suppressed, or otherwise altered.
The authors comprehensively review the anticancer genes and gene delivery methods currently available for cancer gene therapy, including the transfer of genetic material into the cancer cells, stimulation of the immune system to recognize and eliminate cancer cells, and the targeting of the nonmalignant stromal cells that support their growth.
In the past, many tumor marker laboratory tests have not been sensitive enough for the very early detection of cancer. However, many of them have nonetheless proved useful in monitoring therapy, following the course of the tumor, and predicting prog nosis. Today, cancer may be viewed as a genetic disease with various specific chromo somal and nucleotide aberrations, such as mutations, deletions, gene amplification, gene rearrangements, and translocations occurring during the transformation of a nor mal cell into a malignant cell. The considerable advances in technology during the past several years have greatly enhanced our ability to detect human cancers in the very early stages of tumor forma tion. These technologies include: (1) nucleotide molecular assays (genomics); (2) proteomics (multiplex protein measurements); (3) DNA microarrays; and (4) bio informatics. Many of these technologies are already helping in the integration and use of multiple biomarkers for tumors. Although the individual biomarkers may reveal only limited information, the use of multiple biomarkers can help markedly elevate the diagnostic capabilities for early detection of tumors.
In recent years, elucidation of many exciting details of the complex cellular and molecular processes involved in the initiation, progression, and clinical and biological behavior of brain tumors has greatly deepened our understanding of these cancers, and is now leading to new paradigms in their diagnosis and treatment. In Brain Tumors, Francis Ali-Osman, DSc, has assembled a panel of leading experts to summarize and illuminate the full range of recent research advances in their rapidly evolving field, with particular emphasis on those that are providing novel insights into the disease. The chapters critically assess current knowledge and the challenges of the future in relevant areas of brain research, including basic mechanisms of neuro-oncogenesis, molecular neurobiology, genetics, epidemiology, pathology, immunology, and therapy. New knowledge is critically presented on molecular profiling, molecular pathology and classification, in vitro and in vivo brain tumor models, brain metastasis, and progenitor cell biology. They also discuss in depth the cellular and genetic pathways involved in brain oncogenesis, malignant progression, and therapeutic response, highlighting oncogenes and tumor suppressor genes, DNA damage and repair, invasion and migration, cell cycle, growth factors, signaling, apoptosis, and developmental biology. The discussion of brain tumor therapy focuses on advances in pharmacological thinking, therapeutic modalities, novel therapeutic targets, rational drug design, gene and viral therapies, drug delivery and the blood-brain barrier, immunotherapy, and brain imaging. Authoritative and comprehensive, Brain Tumors provides an essential state-of-the-art guide to productive work across the entire range of basic and clinical research in neuro-oncology today. For the both active researcher and the trainee, the book will provide an appreciation of new neuro-oncology concepts and facilitate incorporating them into their own ongoing research.
The authors comprehensively review the anticancer genes and gene delivery methods currently available for cancer gene therapy, including the transfer of genetic material into the cancer cells, stimulation of the immune system to recognize and eliminate cancer cells, and the targeting of the nonmalignant stromal cells that support their growth.
Award-winning researchers review of key aspects of DNA repair in a wide variety of organisms, including all-important model systems. Major topics include UV and X-Ray repair, repair of chemical damage, recombinational repair, mismatch repair, transcription-repair coupling, and the role of DNA repair in cell cycle regulation.
Cutting edge reviews by leading researchers illuminate key aspects of DNA repair in mammalian systems and its relationship to human genetic disease and cancer. Major topics include UV and X-Ray repair, repair of chemical damage, recombinational repair, mismatch repair, transcription-repair coupling, and the role of DNA repair in disease prevention.
The book's many distinguished contributors illuminate the biology and genetics of breast cancer, including what is known about the hereditary breast cancer genes, BRCA1 and 2, the cutting-edge cytogenic approaches, and the biology of breast cancer metastasis.
The reviews cover a wide range of topics from viruses and prokaryotes to higher eukaryotes, and include several new topics, among them the role of recombination in replication of damaged DNA, X-ray crystallographic analysis of DNA repair protein structures, DNA repair proteins and teleomere function, and the roles of BRCA1 and BRCA2 in DNA repair.
The reviews cover a wide range of topics from viruses and prokaryotes to higher eukaryotes, and include several new topics, among them the role of recombination in replication of damaged DNA, X-ray crystallographic analysis of DNA repair protein structures, DNA repair proteins and teleomere function, and the roles of BRCA1 and BRCA2 in DNA repair.
Cutting edge reviews by leading researchers illuminate key aspects of DNA repair in mammalian systems and its relationship to human genetic disease and cancer. Major topics include UV and X-Ray repair, repair of chemical damage, recombinational repair, mismatch repair, transcription-repair coupling, and the role of DNA repair in disease prevention.
The book's many distinguished contributors illuminate the biology and genetics of breast cancer, including what is known about the hereditary breast cancer genes, BRCA1 and 2, the cutting-edge cytogenic approaches, and the biology of breast cancer metastasis.
Prostate Cancer: Biology, Genetics, and the New Therapeutics, Second Edition, reviews new, valuable approaches to the treatment of prostate cancer in men. The latest edition contains new material on molecular imaging, new treatments for prostate cancer, molecular targets, cell signaling pathways, bioinformatics, and pathogenomics. The book details the latest innovations and advances in prostate cancer and may be used as a rapid reference text for readers. The volume profiles the latest advances in cancer research and treatment and includes profound studies in prostate stem cells, cancer-host interactions, hedgehog signaling in development and cancer, cholesterol and cell signaling, gene therapy for advanced prostate cancer, and noninvasive strategies such as molecular imaging to visualize gene expression. This new edition also investigates expression profiling and somatic alterations in prostate cancer progression and linkage studies of prostate cancer families to identify susceptibility genes. The issues of racial differences in prostate cancer mortality, radiotherapy for the treatment of locally advanced prostate cancer, recombinant antibody candidates for treatment, taxane-based chemotherapy, lethal phenotypes, and novel and efficient translation clinical trials are also presented in great depth. Prostate Cancer: Biology, Genetics, and the New Therapeutics, Second Edition, provides readers with a general reference for prostate cancer from prevention to therapy and will be of value to clinicians, scientists, and administrators who strive to solve the cancer problem.
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