References
- Uri N. Inorganic free radicals in solution. Chem. Rev. 1952; 30: 375–454
- Walling C., Kurz M., Schugar H. J. The iron (III) ethylenediaminetetraacetic acid - Peroxide system. Inorg. Chem. 1970; 9: 931–937
- McCord J. M., Day E. D. Superoxide-dependent production of hydroxyl radical catalyzed by iron-EDTA complex. FEBS Lett. 1978; 86: 139–142
- Halliwell B. Superoxide-dependent formation of hydroxyl radicals in the presence of iron chelates. Is it a mechanism for hydroxyl radical production in biochemical systems?. FEBS Lett. 1978; 92: 321–326
- Fridovich I. The biology of oxygen radicals. Science 1978; 209: 875–877
- Fong K. L., McCay P. B., Poyer J. L., Misra H. P., Keele B. B. Evidence for superoxide-dependent reduction of iron (III) and its role in enzyme-generated hydroxyl radical formation. Chem. Biol. lnterac 1976; 15: 77–89
- Gutteridge J. M.C. Superoxide dismutase inhibits the superoxide-driven Fenton reaction at two different levels: Implications for a wider protective role. FEBS Lett. 1985; 185: 19–23
- Gutteridge J. M.C., Bannister J. V. Copper-zinc and manganese superoxide dismutase inhibit deoxyribose degradation by the superoxide-driven Fenton reaction at two different stages. Implications for the redox states of copper and manganese. Biochem. J. 1986; 234: 225–228
- Gutteridge J. M.C, Maidt L., Poyer L. Superoxide dismutase and the Fenton reaction: Hydroxyl radical formation from EDTA-iron (III) and hydrogen peroxide without the apparent direct formation of iron (II). Biochem. J. 1990, in press
- Gutteridge J. M.C. Thiobarbituric acid-reactivity following iron-dependent free radical damage to aminoacids and carbohydrates. FEBS Lett. 1981; 128: 343–346
- Halliwell B., Gutteridge J. M.C. Formation of a thiobarbituric acid-reactive substance from deoxyribose in the presence of iron salts. The role of superoxide and hydroxyl radicals. FEBS Lett. 1981; 128: 347–352
- Melnyk D. L., Horwitz S. B., Peisach J. Redox potential or iron-bleomycin. Biochemistry 1981; 20: 5327–5331
- Muir W. A., Hopfer V., King M. Iron transport across Brush-border Membranes from normal and iron-deficient mouse upper small intestine. J. Biol. Chem. 1984; 259: 4896–4903
- Merck and Co., Inc., Rahway, NJUSA 1976, The Merck Index 9th Ed.
- Bourne E. J., Nery R., Weigel H. Metal chelates of polyhydroxy compounds. Chem. Ind. (London) 1959; 998–999
- Cederbaum A. I., Dicker E., Rubin E., Cohen G. Effect of thiourea on microsomal oxidation of alcohols and associated microsomal functions. Biochemistry 1979; 18: 1187–1191
- Goldstein S., Czapski G. Mannitol as an OH scavenger in aqueous solutions and in biological systems. Int. J. Radial. Res. 1984; 46: 725–729
- Elgavish G. A., Granot J. Enhancement of 31P relaxation rates of orthophosphate and of ATP in the presence of EDTA. Evidence for EDTA-Fe3+ phosphate ternary complexes. J. Mag. Reson. 1979; 36: 147–150
- Burger R. M., Horwitz S. B., Peisach J. Stimulation of iron (II) bleomycin activity by phosphate-containing compounds. Biochemistry 1985; 24: 3623–3629
- Gutteridge J. M.C. Ferrous-salt-promoted damage to deoxyribose and benzoate. The increased effectiveness of hydroxyl radical scavengers in the presence of EDTA. Biochem. J. 1987; 243: 709–714
- Halliwell B., Gutteridge J. M.C., Aruoma O. I. The deoxyribose method: A single “test-tube” assay for determination of rate constants for reactions of hydroxyl radicals. Analyt. Biochem. 1987; 165: 215–219