Oxyradicals in medical biology / series editor, E. Edward Bittar ; guest editor, Joe M. McCord.

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Series: Advances in molecular and cell biology ; v. 25.1998Description: 1 online resource (x, 189 pages) : illustrationsContent type:

text

Media type:

computer

Carrier type:

online resource

ISBN:

9780080877105
0080877109
0762303794
9780762303793
1281716715
9781281716712

Other title:

Oxyradicals in molecular biology [Cover title]

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Genre/Form:

Electronic books.

Additional physical formats: Print version:: Oxyradicals in medical biology.LOC classification:

QP535.O1 O985 1998eb

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Click here to access online

Contents:

Front Cover; Advances in Molecular and Cell Biology: Oxyradicals in Medical Biology; Copyright Page; Contents; List of Contributors; Preface; CHAPTER 1. AN OVERVIEW OF OXYRADICALS IN MEDICAL BIOLOGY; CHAPTER 2. REGULATION OF GENE EXPRESSION BY OXIDATIVE STRESS; CHAPTER 3. OXYRADICALS AND MALIGNANT TRANSFORMATION; CHAPTER 4. OXIDATIVE STRESS AND HUMAN IMMUNODEFICIENCY VIRUS; CHAPTER 5. NEUTROPHILS AND ISCHEMIC/REPERFUSION INJURY; CHAPTER 6. OXYRADICALS AND ACUTE LUNG INJURY; CHAPTER 7. NITRIC OXIDE REGULATION OF SUPEROXIDE AND PEROXYNITRITE-DEPENDENT REACTIONS.

Summary: The rapid expansion of the area of free radical biology in the last 25 years has occurred within a framework of assumptions and preconceived notions that has at times directed the course of this movement. The most dominant of these notions has been the view that free radical production is without exception a bad thing, and that the more efficient our elimination of these toxic substances, the better off we will be. The very important observation by Bernard Babior and colleagues in 1973 that activated phagocytes produce superoxide in order to kill micro organisms, served to illustrate that constructive roles are possible for free radicals. For many in the field, however, this merely underscored the deadly nature of oxygen-derived radicals, both from the microbe's point of view and from the host's as well. (Phagocyte-produced superoxide is responsible in part for the tissue injury manifested as inflammation. See Harris and Granger, Chapter 5, and Leff, Hybertson and Repine, Chapter 6.) Mother Nature, however, has a penchant for being able to make a silk purse from a sow's ear. If one is dealt a bad hand, one must simply make the best of it. After two decades of focusing on the destructive side of free radicals, the last few years have begun to reveal a new and finer perspective on free radical metabolism - a role in regulation of cellular function (see Schulze-Osthoff and Baeuerle, Chapter 2). Evidence from a number of sources suggests that an increase in the oxidative status of cell encourages that cell to grow and divide. Increasing the expression of mangnese superoxide dismutase can suppress the malignant phenotype of melanon cells (see Oberley and Oberley, Chapter 3). Oxidative stress beyond a certain poitosis (from the Greek, literally "to fall apart"). Is this suicide response an evolutionary fail-safe device to curtail tumorogenesis? Does oxidative stress-induced apoptosis account for the loss of immune cells in AIDS (see Flores and McCor Chapter 4)? This volume attempts to present the spectrum of roles, both good and bad played by active oxygen species as understood at this point in the evolution of this field of free radical biology.

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eBooks

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Includes bibliographical references and index.

The rapid expansion of the area of free radical biology in the last 25 years has occurred within a framework of assumptions and preconceived notions that has at times directed the course of this movement. The most dominant of these notions has been the view that free radical production is without exception a bad thing, and that the more efficient our elimination of these toxic substances, the better off we will be. The very important observation by Bernard Babior and colleagues in 1973 that activated phagocytes produce superoxide in order to kill micro organisms, served to illustrate that constructive roles are possible for free radicals. For many in the field, however, this merely underscored the deadly nature of oxygen-derived radicals, both from the microbe's point of view and from the host's as well. (Phagocyte-produced superoxide is responsible in part for the tissue injury manifested as inflammation. See Harris and Granger, Chapter 5, and Leff, Hybertson and Repine, Chapter 6.) Mother Nature, however, has a penchant for being able to make a silk purse from a sow's ear. If one is dealt a bad hand, one must simply make the best of it. After two decades of focusing on the destructive side of free radicals, the last few years have begun to reveal a new and finer perspective on free radical metabolism - a role in regulation of cellular function (see Schulze-Osthoff and Baeuerle, Chapter 2). Evidence from a number of sources suggests that an increase in the oxidative status of cell encourages that cell to grow and divide. Increasing the expression of mangnese superoxide dismutase can suppress the malignant phenotype of melanon cells (see Oberley and Oberley, Chapter 3). Oxidative stress beyond a certain poitosis (from the Greek, literally "to fall apart"). Is this suicide response an evolutionary fail-safe device to curtail tumorogenesis? Does oxidative stress-induced apoptosis account for the loss of immune cells in AIDS (see Flores and McCor Chapter 4)? This volume attempts to present the spectrum of roles, both good and bad played by active oxygen species as understood at this point in the evolution of this field of free radical biology.

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