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Journal Abstract Search

155 related items for PubMed ID: 8457430

  • 1. The production, buffering and efflux of protons in human skeletal muscle during exercise and recovery.
    Kemp GJ, Taylor DJ, Styles P, Radda GK.
    NMR Biomed; 1993; 6(1):73-83. PubMed ID: 8457430
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  • 2. In vivo ATP synthesis rates in single human muscles during high intensity exercise.
    Walter G, Vandenborne K, Elliott M, Leigh JS.
    J Physiol; 1999 Sep 15; 519 Pt 3(Pt 3):901-10. PubMed ID: 10457099
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  • 7. Proton efflux in human skeletal muscle during recovery from exercise.
    Kemp GJ, Thompson CH, Taylor DJ, Radda GK.
    Eur J Appl Physiol Occup Physiol; 1997 Sep 15; 76(5):462-71. PubMed ID: 9367287
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  • 9. Muscle energy metabolism in McArdle's syndrome by in vivo phosphorus magnetic resonance spectroscopy.
    Argov Z, Bank WJ, Maris J, Chance B.
    Neurology; 1987 Nov 15; 37(11):1720-4. PubMed ID: 3478608
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  • 10. Estimating the ATP cost of force production in the human gastrocnemius/soleus muscle group using 31P MRS and 1H MRI.
    Boska M.
    NMR Biomed; 1991 Aug 15; 4(4):173-81. PubMed ID: 1657100
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  • 11. MR imaging as a potential diagnostic test for metabolic myopathies: importance of variations in the T2 of muscle with exercise.
    Jehenson P, Leroy-Willig A, de Kerviler E, Duboc D, Syrota A.
    AJR Am J Roentgenol; 1993 Aug 15; 161(2):347-51. PubMed ID: 8333376
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  • 12. Physiological constraints on changes in pH and phosphorus metabolite concentrations in ischemically exercising muscle: implications for metabolic control and for the interpretation of 31P-magnetic resonance spectroscopic studies.
    Kemp GJ.
    MAGMA; 1997 Sep 15; 5(3):231-41. PubMed ID: 9351027
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  • 13. Cellular energetics of dystrophic muscle.
    Kemp GJ, Taylor DJ, Dunn JF, Frostick SP, Radda GK.
    J Neurol Sci; 1993 Jun 15; 116(2):201-6. PubMed ID: 8393092
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  • 14. Comparisons of ATP turnover in human muscle during ischemic and aerobic exercise using 31P magnetic resonance spectroscopy.
    Kemp GJ, Thompson CH, Barnes PR, Radda GK.
    Magn Reson Med; 1994 Mar 15; 31(3):248-58. PubMed ID: 8057795
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  • 15. Control of phosphocreatine resynthesis during recovery from exercise in human skeletal muscle.
    Kemp GJ, Taylor DJ, Radda GK.
    NMR Biomed; 1993 Mar 15; 6(1):66-72. PubMed ID: 8457428
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  • 16. ATP production and mechanical work in exercising skeletal muscle: a theoretical analysis applied to 31P magnetic resonance spectroscopic studies of dialyzed uremic patients.
    Kemp GJ, Thompson CH, Taylor DJ, Radda GK.
    Magn Reson Med; 1995 May 15; 33(5):601-9. PubMed ID: 7596263
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  • 17. Regulation of oxidative and glycogenolytic ATP synthesis in exercising rat skeletal muscle studied by 31P magnetic resonance spectroscopy.
    Kemp GJ, Sanderson AL, Thompson CH, Radda GK.
    NMR Biomed; 1996 Sep 15; 9(6):261-70. PubMed ID: 9073304
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  • 18. Skeletal muscle bioenergetics in myotonic dystrophy.
    Taylor DJ, Kemp GJ, Woods CG, Edwards JH, Radda GK.
    J Neurol Sci; 1993 Jun 15; 116(2):193-200. PubMed ID: 8336166
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  • 19. Interrelations of ATP synthesis and proton handling in ischaemically exercising human forearm muscle studied by 31P magnetic resonance spectroscopy.
    Kemp GJ, Roussel M, Bendahan D, Le Fur Y, Cozzone PJ.
    J Physiol; 2001 Sep 15; 535(Pt 3):901-28. PubMed ID: 11559784
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  • 20. Intersubject differences in the effect of acidosis on phosphocreatine recovery kinetics in muscle after exercise are due to differences in proton efflux rates.
    van den Broek NM, De Feyter HM, de Graaf L, Nicolay K, Prompers JJ.
    Am J Physiol Cell Physiol; 2007 Jul 15; 293(1):C228-37. PubMed ID: 17392383
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