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Journal Abstract Search

498 related items for PubMed ID: 7483911

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  • 4. On the mechanism of shrinkage-induced potassium influx in rat and human erythrocytes.
    Orlov SN, Pokudin NI, Gurlo TG, Okun IM, Aksentsev SL, Konev SV.
    Gen Physiol Biophys; 1991 Aug; 10(4):359-71. PubMed ID: 1663056
    [Abstract] [Full Text] [Related]

  • 5. Inhibition and stimulation of K+ transport across the frog erythrocyte membrane by furosemide, DIOA, DIDS and quinine.
    Gusev GP, Lapin AV, Agalakova NI.
    Gen Physiol Biophys; 1999 Sep; 18(3):269-82. PubMed ID: 10703743
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  • 7. Temperature effects on ion transport across the erythrocyte membrane of the frog Rana temporaria.
    Agalakova NI, Lapin AV, Gusev GP.
    Comp Biochem Physiol A Physiol; 1997 Jul; 117(3):411-8. PubMed ID: 9172392
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  • 8. Erythrocyte cationic transport systems in normal male and female volunteers.
    Lijnen P, M'Buyamba-Kabangu JR, Lissens W, Amery A.
    Methods Find Exp Clin Pharmacol; 1985 Jan; 7(1):35-40. PubMed ID: 2985891
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  • 9. Characterisation of the potassium influx in rat erythrocytes.
    Ihrig I, Schönheit C, Häussner W, Bernhardt I.
    Gen Physiol Biophys; 1992 Aug; 11(4):377-88. PubMed ID: 1330816
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  • 10. Intracellular sodium, potassium and magnesium concentration, ouabain-sensitive 86rubidium-uptake and sodium-efflux and Na+, K+-cotransport activity in erythrocytes of normal male subjects studied on two occasions.
    Lijnen P, Hespel P, Lommelen G, Laermans M, M'Buyamba-Kabangu JR, Amery A.
    Methods Find Exp Clin Pharmacol; 1986 Sep; 8(9):525-33. PubMed ID: 3773597
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  • 11. [Na+ and K+ ion transport across the human erythrocyte membrane during the formation of nystatin channels under in-vitro conditions: the characteristics and an analysis of the processes].
    Borisov IuA, Soboleva OIu, Suglobova ED, Fedorovich EE.
    Tsitologiia; 1994 Sep; 36(5):427-36. PubMed ID: 7809978
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  • 12. Activation of the Na(+)-K+ pump in frog erythrocytes by catecholamines and phosphodiesterase blockers.
    Gusev GP, Agalakova NI, Lapin AV.
    Biochem Pharmacol; 1996 Nov 08; 52(9):1347-53. PubMed ID: 8937444
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  • 13. Effect of metabolic depletion on the furosemide-sensitive Na and K fluxes in human red cells.
    Dagher G, Brugnara C, Canessa M.
    J Membr Biol; 1985 Nov 08; 86(2):145-55. PubMed ID: 2993628
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  • 14. Chloride transport in red blood cells of lamprey Lampetra fluviatilis: evidence for a novel anion-exchange system.
    Bogdanova AYu, Sherstobitov AO, Gusev GP.
    J Exp Biol; 1998 Mar 08; 201(Pt 5):693-700. PubMed ID: 9542152
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  • 16. Potassium channels of the lamprey erythrocyte membrane exhibit a high selectivity to K+ over Rb+: a comparative study of 86Rb and 41K transport.
    Gusev GP, Fleishman DG, Nikiforov VA, Sherstobitov AO.
    Gen Physiol Biophys; 1997 Sep 08; 16(3):273-84. PubMed ID: 9452948
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  • 17. Correction of hypokalemia corrects the abnormalities in erythrocyte sodium transport in Bartter's syndrome.
    Korff JM, Siebens AW, Gill JR.
    J Clin Invest; 1984 Nov 08; 74(5):1724-9. PubMed ID: 6501567
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  • 18. Sodium and potassium transport in trout (Salmo gairdneri) erythrocytes.
    Bourne PK, Cossins AR.
    J Physiol; 1984 Feb 08; 347():361-75. PubMed ID: 6707960
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  • 19. An amiloride-sensitive, volume-dependent Na+ transport across the lamprey (Lampetra fluviatilis) erythrocyte membrane.
    Gusev GP, Sherstobitov AO.
    Gen Physiol Biophys; 1996 Apr 08; 15(2):129-43. PubMed ID: 8899417
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  • 20. A furosemide-sensitive cotransport of sodium plus potassium in the human red cell.
    Wiley JS, Cooper RA.
    J Clin Invest; 1974 Mar 08; 53(3):745-55. PubMed ID: 4812437
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