McCordJMFridovichI.Superoxide dismutase. An enzymic function for erythrocuprein (hemocuprein). J Biol Chem1969; 224: 6049–55.
2.
HalliwellBGutteridgeJMC. The importance of free radicals and catalytic metal ions in human diseases. Molec Aspects Med1985; 8: 89–193.
3.
HaberFWeissJ.The catalytic decomposition of hydrogen peroxide by iron salts. Proc R Soc Lond Series A1934; 137: 332–51.
4.
MarxGChevionM.Site specific modification of albumin by free radicals: Reaction with Cu11 and ascorbateBiochem J1985; 236: 397–400.
5.
SamuniAChevionMCzapskiG.Unusual copper induced sensitisation of the biological damage due to superoxide radicals. J Biol Chem1981; 256: 12632–5.
6.
WickensDWilkinsMHLunecJBallGDormandyTL. Free radical oxidation (peroxidation) products in plasma in normal and abnormal pregnancy. Ann Clin Biochem1981; 18: 158–62.
7.
DahleLKHillEGHolmanRT. The thiobarbituric acid reaction and the autoxidation of polyunsaturated methyl esters. Arch Biochem Biophys1962; 98: 253–67.
8.
HalliwellBGutteridgeJMC. Free Radicals in Biology and Medicine. Oxford, England: Clarendon Press, 1985.
9.
LunecJBlakeDRMcClearySJBrailsfordSBaconPA. Self-perpetuating mechanisms of immunoglobulin G aggregation in rheumatoid inflammation. J Clin Invest1985; 76: 2084–90.
10.
LunecJGriffithsHRJonesAFBlakeDR. Protein fluorescence and its relationship to free radical activity. In: Rice-EvansC, ed, Free Radicals Oxidant Stress and Drug Action. London: Richelieu Press, 1987, pp 151–67.
11.
GriffithsHRUnsworthJBlakeDRLunecJ.Oxidation of amino acids within serum proteins. In: Rice-EvansC., ed, Free Radicals: Chemistry, Pathology and Medicine. London: Richelieu Press, 1989, pp 439–54.
12.
GarnerMSpectorA.Selective oxidation of cysteine and methionine in normal and senile cataractous lenses. Proc Natl Acad Sci USA1980; 77: 1274–7.
13.
DilleyKPirieA.Changes to the proteins of human lens nucleus in cataract. Exp Eye Res1974; 19: 59–72.
14.
WongPSTravisJ.Isolation and properties of alpha-1-proteinase inhibitor from human rheumatoid synovial fluid. Biochem Biophys Res Commun1980; 96: 1449–54.
15.
CarpHMillerFHoidalJRJanoffA.Potential mechanism of emphysema: Alpha proteinase inhibitor recovered from lungs of cigarette smokers contains oxidised methionine and has decreased elastase inhibitory capacity. Proc Natl Acad Sci USA1982; 79: 2041–5.
16.
ScholesG.Radiation effects on DNA. Br J Radiol1983; 56: 221–31.
17.
KenslerTWTrushMA. Role of oxygen radicals in tumour promotion. Environ Mutagen1984; 6: 593–616.
18.
WardJFEvansJWLimoliLCalabro-JonesPM. Radiation and hydrogen peroxide induced free radical damage to DNA. Br J Cancer1987; 55 (Suppl VIII): 105–12.
19.
KasaiHNishimuraS.Hydroxylation of guanine in nucleosides and DNA at the C-8 position by heated glucose and oxygen radical forming agents. Environ Health Perspec1986; 67: 111–6.
20.
FloydRAWatsonJJWongPKMillerDHRichardRC. Hydroxyl free radical adduct of deoxyguanosine: Sensitive detection and mechanism of formation. Free Rad Res Commun1986; 1: 163–72.
21.
ThornalleyPJ. Monosaccharide autoxidation in health and disease. Environ Health Perspect1985; 64: 297–309.
22.
Von SontagC.Carbohydrate oxidation. Adv Carbohydrate Chem Biochem1980; 37: 1–77.
23.
JonesAFJenningsPEWakefieldAWinklesJLunecJBarnettAH. The fluorescence of serum proteins in diabetic patients with and without retinopathy. Diabetic Med1988; 5: 547–51.
24.
GreenwaldRAMoyWW. Effect of oxygen derived free radicals on hyaluronic acid. Arthritis Rheum1980; 23: 455–63.
25.
GreenwaldRAMoakSA. Degradation of hyaluronic acid by polymorphonuclear leukocytes. Inflammation1986; 10: 15–30.
26.
McCordJM. Free radicals and inflammation. Protection of synovial fluid by superoxide dismutase. Science1974; 185: 529–31.
27.
BonuraTTownCDSmithKEKaplanAS. The influence of oxygen on the yield of DNA double strand breaks in X-irradiatedE Coli Rad Res1975; 63: 567–72.
28.
HutchinsonF.Sulphydryl groups and the oxygen effect on irradiated dilute solutions of enzymes and nucleic acids. Rad Res1961; 14: 721–30.
29.
WillsonRL. Free radicals oxygen and radiosensitising drugs: A very brief introduction. In: RodgersMAZPowerEL, eds, Oxygen and Oxygen Radicals in Chemistry and Biology. New York: Academic Press, 1981: 309–30.
30.
PetkauA.Role of superoxide dismutase in modification of radiation injury. Br J Cancer1987; 55 (Suppl VII): 87–95.
31.
PetkauAKellyKChelackWSPleskachSDBarefoorCMecherBE. Radioprotection of bone marrow stem cells by superoxide dismutase. Biochem Biophys Res Commun. 1975; 67: 1167–71.
32.
KappusH.Overview of enzyme systems involved in bioreduction of drugs and in redox cycling. Biochem Pharmac1986; 35: 1–20.
33.
TrushMAMimnaughEGGramTE. Activation of pharmacological agents to radical intermediates. Implications for the role of free radicals in drug action and toxicity. Biochem Pharmac1982; 31: 3335–9.
34.
LangstonJWBallardPTetrudJWIrwinI.Chronic Parkinsonism in humans due to a product of meperidine—analog synthesis. Science1983; 219: 979–80.
35.
BorishETCosgroveJPChurchDFDeutchWAPryorWA. Cigarette tar causes single strand breaks in DNA. Biochem Biophys Res Commun1985; 133: 780–5.
36.
FanvadouY.On the mechanisms of reductive activation in the mode of action of some anticancer drugs. Biochimie1982; 7: 457–9.
37.
BabiorBM. The respiratory burst of phagocytes. J Clin Invest1984; 73: 599–601.
BabiorBMCurnutteJTMcMurrichBJ. The particulate superoxide forming system from human neutrophils. J Clin Invest1976; 58: 989–96.
40.
LunecJ.Free radical mediated aggregation of IgG. Agents Actions1983; 15: 37–8.
41.
BerendenHBridgesRAGoodRA. Fatal granulomatosis of childhood. Clinical study of a new syndrome. Minn Med1957; 40: 309–15.
42.
CurnutteJTWhittenDMBabiorBM. Defective superoxide production by granulocytes from patients with chronic granulomatous disease. N Engl J Med1974; 290: 593–605.
43.
MasonRPKalyanaramanBTainerBEElingTE. A carbon centred free radical intermediate in the prostaglandin synthetase oxidation of arachidonic acid: Spin trapping and oxygen uptake studies. J Biol Chem1980; 255: 5019–22.
44.
OginoNOhkiSYamamotoSHayaishiO.Prostaglandin endoperoxide synthetase from bovine vesicular gland microsomes. Inactivation and activation by haem and other metalloporphyrins. J Biol Chem1978; 253: 5061–8.
45.
BlakeDRAllenRELunecJ.Free radicals in biological systems—a review orientated to inflammatory processes. Brit Med Bull1987; 43: 371–85.
46.
LunecJGriffithsHR. Oxygen free radicals denature human IgG and increase its reactivity with rheumatoid factor antibody. Scand J Rheum (Suppl)1988; 75: 140–7.
LunecJHalloranSPWhiteSPWhiteAGDormandyTL. Free radical oxidation (peroxidation) products in serum and synovial fluid in rheumatoid arthritis. J Rheumatol1980; 8: 233–45.
49.
RowleyDAGutteridgeJMCBlakeDRFarrMHalliwellB.Lipid peroxidation in rheumatoid arthritis: Thiobarbituric acid reactive material and catalytic iron salts in synovial fluid from rheumatoid patients. Clin Sci1984; 66: 691–5.
50.
LunecJBrailsfordSHewittSDMorrisCJBlakeDR. Free radicals in RA. Int J Immunotherapy1986; II (1): 6442–7.
51.
DeanRTRobertsCRForniL.Oxygen centred free radicals efficiently degrade the polypeptide of proteoglycans in cartilage. Biosci Rep1985; 4: 1017–20.
52.
AllanIMLunecJSalmonMBaconPA. Reactive oxygen species selectively deplete normal T lymphocytes via a hydroxyl radical dependent mechanism. Scand J Immunol1987; 26: 47–53.
53.
FantoneJCWardPA. Role of oxygen derived free radicals and metabolites in leukocyte dependent inflammatory reactions. J Pathol1982; 107: 397–418.
54.
WardPAJohnsonKJTillGO. Oxygen radicals and microvascular injury of lungs and kidney. Acta Physiol Scand (Suppl)1986; 548: 79–85.
55.
CasaleASBulkleyGBBulkleyBHFlahertyJTGoyyVLGardnerTJ. Oxygen free radical scavengers protect the arrested, globally ischaemic heart upon reperfusion. Surg Forum1983; 34: 313–6.
56.
YonnesMSchoenbergMHJungHFedholdBBHaglundUSchildbergFW. Oxidative tissue damage following regional intestinal ischaemia and reperfusion in the cat. Res Exp Med1984; 184: 259–64.
57.
McCordJM. Oxygen derived free radicals in post ischaemic tissue injury. N Engl J Med1985; 312: 159–63.
58.
LunecJFullerBJHealingGSimpkinsSGreenCJ. Lipid peroxidation in rabbit kidneys after warm ischaemia and subsequent reperfusion. IRCS Med Sci1985; 13: 818–9.
59.
GreenCJHealingGLunecJFullerBJSimpkinsS.Evidence for free radical induced damage in rabbit kidneys after simple hypothermic preservation and autotransplantation. Transplantation1986; 41: 161–5.
60.
GreenCJHealingGSimpkinsSFullerBJLunecJ.Reduced susceptibility to lipid peroxidation in cold ischaemic rabbit kidneys when desferrioxamine, mannitol or uric acid are added to washout solution. Cryobiology1986; 23: 358–65.
61.
BlakeDRWoodruffTFreemanJAndrewsFJSaltPLunecJ.Is chronic synovitis an example of reperfusion injury?Ann Rheum Dis1986; 45: 608–11.
62.
AllenREOuthwaiteJMMorrisCJBlakeDR. Xanthine oxidoreductase is present in human synovium. Ann Rheum Dis1987; 46: 843–5.
63.
BlakeDRUnsworthJOuthwaiteJMorrisCJLunecJ.Hypoxic reperfusion injury in the inflamed human joint. Lancet1989; i: 289–93.
OlesenLund KMenanderKB. A new antiinflammatory metalloprotein drug: Preliminary evaluation of clinical efficacy and safety in degenerative joint disease. Curr Ther Res1974; 16: 706–16.
66.
MullerACadenasEGrafPSiesH.A novel biologically active seleno oranic compound—I. Glutathione peroxidase like activity in vitro and antioxidant capacity of PZ51 (Ebselen). Biochem Pharmacol1984; 33: 3235–9.
67.
ParnhamMKindtS.A novel biologically active seleno organic compound—III. Effect of PZ51 (Ebselen) on glutathione peroxidase and secretory activity of mouse macrophages. Biochem Pharmacol1984; 33: 3247–50.
68.
VapaatoloH.Free radicals and antiinflammatory drugs. Med Biol1986; 64: 1–7.
69.
HoeSRowleyDAHalliwellB.Reactions of ferrioxamine and desferrioxamine with the hydroxyl radical. Chem-Biol Interact1982; 41: 75–87.
70.
BlakeDRWinyardPLunecJCerebral and ocular toxicity induced by deferrioxamine. Quart J Med1985; 56: 345–55.
71.
LunecJ.Oxygen radicals: Their measurement in vivo. Analyt Proc1989; 26: 130–1.
