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Journal Of Chronic Fatigue Syndrome Volume 6, 2000 - Issue 1
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Original Article

Investigation of Erythrocyte Oxidative Damage in Rheumatoid Arthritis and Chronic Fatigue Syndrome

R. S. Richards Bioanalytical Research Group, Department of Biological Sciences, The University of Newcastle, Callaghan, NSW 2308, Australia
,
T. K. Roberts Bioanalytical Research Group, Department of Biological Sciences, The University of Newcastle, Callaghan, NSW 2308, AustraliaCorrespondence[email protected]
,
D. Mathers Department of Rheumatology, Royal Newcastle Hospital, Newcastle, NSW 2300, Australia
,
R. H. Dunstan Bioanalytical Research Group, Department of Biological Sciences, The University of Newcastle, Callaghan, NSW 2308, Australia
,
N. R. McGregor Bioanalytical Research Group, Department of Biological Sciences, The University of Newcastle, Callaghan, NSW 2308, Australia
&
H. L. Butt Bioanalytical Research Group, Department of Biological Sciences, The University of Newcastle, Callaghan, NSW 2308, Australia
Pages 37-46 | Published online: 04 Dec 2011

References

  • Richards, R.S.; Roberts, T.K.; McGregor, N.R. et al. Erythrocyte antioxidant systems protect cultured endothelial cells against oxidant damage. Biochem Molec Biol Int 46: 857–865; 1998.
  • Richards, R.S.; Roberts, T.K.; McGregor, N.R. et al. The role of erythrocytes in the inactivation of free radicals. Med Hypoth 50: 363–367; 1998.
  • Richards, R.S.; Roberts, T.K.; McGregor, N.R. et al. Erythrocytes protect cul-tured endothelial cells from neutrophil-mediated damage. Aust J Med Sci 18: 73–77; 1997.
  • Winterbourn, C.C.; Stem, A. Human red cells scavenge extracellular hydro-gen peroxide and inhibit formation of hypochlorous acid and hydroxyl radical. J Clin Invest 80: 1486–1491; 1987.
  • Agar, N.S.; Sadrzadeh, S.M.; Hallaway, P.E. et al. Erythrocyte catalase. A so-matic oxidant defense? J Clin Invest 77: 319–321; 1986.
  • van Asbeck, B.S.; Hoidal, J.; Vercellotti, G.M. et al. Protection against lethal hyperoxia by tracheal insufflation of erythrocytes: role of red cell glutathione. Sci-ence 227: 756–759; 1985.
  • Toth, K.M.; Clifford, D.P.; Berger, E.M. et al. Intact human erythrocytes pre-vent hydrogen peroxide-mediated damage to isolated perfused rat lungs and cultured bovine pulmonary artery endothelial cells. J Clin Invest 74: 292–295; 1984.
  • Roberts, T.K.; McGregor, N.R.; Dunstan, R.H. et al. Immunological and hae-matological parameters in patients with chronic fatigue syndrome. J Chronic fatigue Syndr 4: 51–65; 1998.
  • Richards, R.S.; Roberts, T.K.; Mathers, D. et al. Erythrocyte morphology in rheumatoid arthritis and chronic fatigue syndrome: A preliminary study. J Chronic Fatigue Syndr 6(1): 23–5, 2000.
  • Simpson, L. Red cells in the chronic fatigue syndrome. Med J Aust 154: 78; 1991.
  • Lloyd, A.; Wakefield, D.; Smith, L. et al. Red blood cell morphology in chron-ic fatigue syndrome. Lancet 2: 217; 1989.
  • Simpson, L. Nondiscocytic erythrocytes in myalgic encephalomyelitis. NZ Med J102: 126–127; 1989.
  • Mukherjee, T.; Smith, K.; Maros, K. Abnormal red blood cell morphology in myalgic encephalomyelitis. Lancet 2: 328–329; 1987.
  • Simpson, L.0.; Shand, B.I.; Olds, R.J. et al. Red cell and hemorheological changes in multiple sclerosis. Pathology 19: 51–55; 1987.
  • Amon, F.; Edworthy, S.; Block, D. Revised ARA criteria for rheumatoid ar-thritis. Arthr Rheum 30: S17; 1987.
  • Holmes, G.; Kaplan, J.; Gantz, N. et al. Chronic fatigue syndrome: a working case definition. Ann Intern Med 108: 387–389; 1988.
  • Sharpe, MC.; Archard, L.C.; Banatvala, J.E. et al. A report-chronic fatigue syndrome: guidelines for research. J Royal Soc Med 84: 118–121; 1991.
  • Fillet, G.; Beguin, Y.; Baldelli, L. Model of reticuloendothelial iron metabo-lism in humans: abnormal behaviour in idiopathic haemochromatosis and in in-flammation. Blood 74: 844–850; 1989.
  • Nimer, S.D.; Golde, D.W. Molecular, cellular and clinical biology of phago-cytic cells. In: Handin, R.J.; Stossel, T.P.; Lux, S.E. eds. Blood: Principles and Prac-tice of Hematology. Philadelphia: J.B. Lippincott Company; 1995: 513–541.
  • Moriyama, R.; Lombardo, C.; Workman, R., et al. Regulation of linkages be-tween the erythrocyte membrane and its skeleton by 2,3-diphosphoglycerate. J Biol Chem 268: 10990–10996; 1993.
  • Chasis, J.; Mohandas, N. Erythrocyte membrane deformability and stability: two distinct membrane properties that are independently regulated by skeletal protein associations. J Cell Biol 103: 343–350; 1986.
  • Benesch, R.; Benesch, R.E. The effect of organic phosphates from the human erythrocyte on the allosteric properties of haemoglobin. Biochem Biophys Res Comm 26: 162; 1967.
  • Chanutin, A.; Curnish, R. Effect of organic and inorganic phosphates on the oxygen equilibrium of human erythrocytes. Arch Biochem Biophys 121: 96–102; 1967.
  • Chiu, D.; Lubin, B. Oxidative haemoglobin denaturation and RBC destruc-tion: the effect of haem on red cell membranes. Seminars in Haematology 26: 128–135; 1989.
  • Lubin, B.; Chiu, D. Properties of vitamin E-deficient erythrocytes following peroxidant injury. Pediatr Res 16: 928–932; 1982.
  • Palek, J.; Liu, S. Dependence of spectrin organization in red blood cell mem-branes on cell metabolism: implications for control of red cell shape, deformability and surface area. Semin Haematol 16: 75–93; 1979.
  • Hebbel, R.; Miller, W. Phagocytosis of sickle erythrocytes: immunologic and oxidative determinants of hemolytic anemia. Blood 64: 733–741; 1984.
  • Cox, I.; Campbell, M.; Dowson, D. Red blood cell magnesium and chronic fatigue syndrome. Lancet 337: 757–760; 1991.
  • Daleke, D.; Huestis, W. Erythrocyte morphology reflects the transbilayer dis-tribution of incorporated phospholipids. J Cell Biol 108: 1375–1385; 1989.
  • Zachee, P.; Ferrant, A.; Daelemans, R. et al. Oxidative injury to erythrocytes, cell rigidity and splenic haemolysis in haemodialysed patients before and during ery-thropoietin treatment. Nephron 65: 288–293; 1993.
  • Zachee, P.; Emonds, M.P.; Lins, R. et al. Red blood cells, the scavengers for toxic free radicals during haemodialysis [letter]. Nephrol Dial Transplant 3: 104–105; 1988.

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