Antioxidants endogenous

A variety of other metals and their complexes have been studied for radioprotective activity. Among these are copper glycinate, strontium chloride, ZnNa -diethylenetriaminepentaacetate (ZnDTPA), and selenium, which has been studied because of its relationship to endogenous antioxidant mechanisms, especiaHy GSH peroxidase and vitamin E. 

PIETTA p G and siMONETTi p (1998) Dietary flavonoids and interaction with endogenous antioxidant , Biochem Molec Biol Int, 44(5), 1069-74. 

Ubiquinone, known also as coenzyme Q, plays a crucial role as a respiratory chain electron carrier transport in inner mitochondrial membranes. It exerts this function through its reversible reduction to semiquinone or to fully hydrogenated ubiquinol, accepting two protons and two electrons. Because it is a small lipophilic molecule, it is freely diffusable within the inner mitochondrial membrane. Ubiquinones also act as important lipophilic endogenous antioxidants and have other functions of great importance for cellular metabolism. ... 

Convincing evidence indicates that ROS generated both endogenously and also in response to diet and lifestyle factors may play a significant role in the etiology of atherosclerosis and CHD. Indeed, free radicals are responsible for LDL oxidation, which is involved in the initiation and promotion of atherosclerosis. Thus, protection from LDL oxidation by antioxidants such as carotenoids may lead to protection against human CHD. 

Herz, H., Blake, D.R and Grootveld, M. (1994). Multicomponent investigations of the hydrogen peroxide- and hydroxyl radical-scavenging antioxidant capacities of biofluids the roles of endogenous pyruvate and lactate. Free Rad. Res. Commun. (in press). 

The potency of a chain-breaking antioxidant, which scavenges peroxyl radicals, will decrease as the concentration of lipid peroxides in the LDL particle increases (Scheme 2.2). This is illustrated in the experiment shown in Fig. 2.3 in which the antioxidant potency of a peroxyl radical scavenger (BHT) decreases as a function of added exogenous hpid hydroperoxide. If the endogenous lipid peroxide content of LDL were to vary between individuals, this could explain the observed diferences in the effectiveness of a-tocopherol in suppressing lipid peroxidation promoted by copper. 

Esterbauer et cil. (1992) have studied the in vitro effects of copper on LDL oxidation and have shown that there are three distinct stages in this process. In the first part of the reaction, the rate of oxidation is low and this period is often referred to as the lag phase the lag phase is apparently dependent on the endogenous antioxidant content of the LDL, the lipid hydroperoxide content of the LDL particle and the fatty acid composition. In the second or propagation phase of the reaction, the rate of oxidation is much faster and independent of the initial antioxidant status of the LDL molecule. Ultimately, the termination reactions predominate and suppress the peroxidation process. The extensive studies of Esterbauer et al. have demonstrated the relative importance of the endogenous antioxidants within the LDL molecule in protecting it from oxidative modification. 

Stocker, R. and Frei, B. (1991). Endogenous antioxidant defences in human plasma. In Oxidative Stress, Oxidants and Antioxidants (ed. H. Sies) pp. 213-243, Academic Press, London. 

Hiraishi, H., Razandi, M., Terano, A. and Ivey, K.J. (1990). Antioxidant defenses of culture gastric mucosal cells against toxic oxygen metabolites. Role of glutathione redox cycle and endogenous catalase. Gastroenterology 98, A544. 

Marubayashi, S., Dohi, K., Sumimoto, K., Oku, J., Ochi, K. and Kawasaki, T. (1989). Changes in activity of free radical scavengers and in levels of endogenous antioxidants during hepatic ischaemia and subsequent reperfusion. Transplant. Proc. 21, 1317-1318. 

In animals it is clear that both endogenous and exogenous ROS can produce acute injury to pulmonary cells in vitro and in vivo, and that a variety of antioxidant substances can reduce such damage. However, although... 

The natural endogenous physiological antioxidant systems for controUing the potentially injurious elFects of environmentally exacerbated oxidative stress, may be modulated by a number of various nutritional and pharmacological supplementary interventions. 

A major contribution of the free-radical scavenging activity in blood plasma is attributable to the macro-molecular proteins (Wayner et al., 1985) of which albumin is a primary component and trapping agertt (Holt et al., 1984). Serum sulphydryl levels, primarily albumin-related, are decreased in subjects with rheumatoid complicated coalworkers pneumoconiosis, indicative of exacerbated inflammatory R.OM production (Thomas and Evans, 1975). Experimental asbestos inhalation in rats leads to an adaptive but evidendy insufficient response by an increase in endogenous antioxidant enzymes (Janssen etal., 1990). Protection of the vascular endothelium against iron-mediated ROM generation and injury is afforded by the iron sequestiant protein ferritin (Balia et al., 1992). 

Experimental in vitro investigations utilizing liposomal-encapsulated and polyethylene glycol-conjugated SOD and catalase have demonstrated the potential value of such means in countering oxidative asbestos-related diseases (Freeman etal., 1985 Mossman etal., 1986). In addition to using supplementary endogenous antioxidant enzymes, the use of iron chelators like desferrioxamine... 

Janssen, Y.M.W., Marsh, J.P., Absher, M., Borm, P.J.A. and Mossman, B.T. (1990). Increases in endogenous antioxidant enzymes during asbestos inhalation in rats. Free Rad. Res. Commun. 11, 53-58. 

Normally, the cascade from oxygen to water is well controlled by SOD, catalase and endogenous antioxidants such as glutathione, ascorbate and vitamin E. Vitamin E is the most important membrane-bound antioxidant. However, during ischaemia, the local control of ROS is lost, thus reactive free radicals can attack the membranes and lipid peroxidation begins. Endogenous antioxidants can be supplemented. This section describes this supplementation strategy. 

Ascorbic acid (vitamin C) is one of the body s endogenous water-soluble antioxidants. Modifications on the ascorbic acid structure have led to some very interesting compounds, such as a novel series of 3-O-alkyl ascorbic-acid derivatives. They have been found to be inhibitors of lipid peroxidation (Nihro etal., 1991). This antioxidant activity is directly related to the lipophilicity of the alkyl chain, su esting that the lipid chain may anchor the antioxidant portion of the molecule in the membrane. 

Phenols are important antioxidants, with vitamin E being the most important endogenous phenolic membrane-bound antioxidant. Membrane levels of vitamin E are maintained through recycling of the vitamin E radical with ascorbate and thiol reductants. Vitamin E is a mixture of four lipid-soluble tocopherols, a-tocopherol being the most efiective radical quencher. The reaction of a-tocopherol with alkyl and alkylperoxyl radicals of methyl linoleate was recently reported. These are facile reactions that result in mixed dimer adducts (Yamauchi etal., 1993). 

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