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Mechanisms of Human Erythrocytes Volume Stabilization

References of this article:

  1. Физиология человека.

    Бабский ЕБ, Зубков АА, Косицкий ГИ, Ходоров БИ.

    Москва: Медицина. 1972, ,

  2. Erythrocytes: Physiology and pathophysiology.

    Lang F, Foller M, editors.

    London: Imperial College Press. 2012, ,

  3. Folding of red blood cells in capillaries and narrow pores

    W. Reinhart, C. Huang, M. Vayo, G. Norwich, S. Chien, R. Skalak

    Biorheology. 1991, 28, 537-549

  4. Анализ геометрических параметров и механических свойств эритроцитов методом фильтрации через мембранные ядерные фильтры. I. Математическая модель.

    Атауллаханов ФИ, Витвицкий ВМ, Лисовская ИЛ, Тужилова ЕГ.

    Биофизика. 1994, 39, 672–80

  5. Red cell membrane: past, present, and future

    N. Mohandas, P. Gallagher

    Blood. 2008, 112, 3939-3948

  6. The Role of the Sinus Wall in the Passage of Erythrocytes Through the Spleen

    L. Chen, L. Weiss

    Blood. 1973, 41, 529-537

  7. Contrasting splenic mechanisms in the blood clearance of red blood cells and colloidal particles

    M. Klausner, L. Hirsch, P. Leblond, J. Chamberlain, M. Klemperer, G. Segel

    Blood. 1975, 46, 965-976

  8. Biomechanics of red blood cells in human spleen and consequences for physiology and disease

    I. Pivkin, Z. Peng, G. Karniadakis, P. Buffet, M. Dao, S. Suresh

    Proceedings of the National Academy of Sciences. 2016, 113, 7804-7809

  9. Mechanical Properties of the Red Cell Membrane in Relation to Molecular Structure and Genetic Defects

    N. Mohandas, E. Evans

    Annual Review of Biophysics and Biomolecular Structure. 1994, 23, 787-818

  10. High-resolution data on the geometry of red blood cells

    Y. Fung, W. Tsang, P. Patitucci

    Biorheology. 1981, 18, 369-385

  11. On the Mechanism of Human Red Blood Cell Longevity: Roles of Calcium, the Sodium Pump, PIEZO1, and Gardos Channels

    V. Lew, T. Tiffert

    Frontiers in Physiology. 2017, 8,

  12. Computation of the average shear-induced deformation of red blood cells as a function of osmolality

    Clark MR

    Blood Cells . 1989, 15, 427-39

  13. Как регулируется объем эритроцитиа, или что могут и чего не могут математические модели в биологии.

    Атауллаханов ФИ, Корунова НО, Спиридонов ИС, Пивоваров ИО, Калягина НВ, Мартынов МВ.

    Биологические мембраны. 2009, 26, 163-79

  14. Distribution of Size and Shape in Populations of Normal Human Red Cells

    P. CANHAM, A. BURTON

    Circulation Research. 1968, 22, 405-422

  15. Geometric, osmotic, and membrane mechanical properties of density- separated human red cells

    O. Linderkamp, H. Meiselman

    Blood. 1982, 59, 1121-1127

  16. Parallel Microchannel-Based Measurements of Individual Erythrocyte Areas and Volumes

    S. Gifford, M. Frank, J. Derganc, C. Gabel, R. Austin, T. Yoshida, M. Bitensky

    Biophysical Journal. 2003, 84, 623-633

  17. Physiology of Cell Volume Regulation in Vertebrates

    E. Hoffmann, I. Lambert, S. Pedersen

    Physiological Reviews. 2009, 89, 193-277

  18. Diffusional water permeability of human erythrocytes and their ghosts

    Brahm J.

    J Gen Physiol. 1982, 79, 791-819

  19. Volume stabilization in human erythrocytes: combined effects of Ca2+-dependent potassium channels and adenylate metabolism

    M. Martinov, V. Vitvitsky, F. Ataullakhanov

    Biophysical Chemistry. 1999, 80, 199-215

  20. Deficiencies of glycolytic enzymes as a possible cause of hemolytic anemia

    M. Martinov

    Biochimica et Biophysica Acta (BBA) - General Subjects. 2000, 1474, 75-87

  21. Stretch-activated single channel currents in tissue-cultured embrionic chick skeletal muscle

    Guharay F. SF

    J Physiol . 1984, 352, 685-701

  22. Stoichiometry and Localization of Adenosine Triphosphate-dependent Sodium and Potassium Transport in the Erythrocyte

    A. Sen, R. Post

    Journal of Biological Chemistry. 1964, 239, 345-352

  23. Energy metabolism in human erythrocytes: the role of phosphoglycerate kinase in cation transport

    G. Segel, S. Feig, B. Glader, A. Muller, P. Dutcher, D. Nathan

    Blood. 1975, 46, 271-278

  24. Erythrocyte cation permeability induced by mechanical stress: a model for sickle cell cation loss

    R. Johnson, S. Gannon

    American Journal of Physiology-Cell Physiology. 1990, 259, C746-C751

  25. Membrane stress increases cation permeability in red cells

    R. Johnson

    Biophysical Journal. 1994, 67, 1876-1881

  26. Recent advances in the pathophysiology of <scp>PIEZO1</scp> ‐related hereditary xerocytosis

    N. Jankovsky, A. Caulier, J. Demagny, C. Guitton, S. Djordjevic, D. Lebon, H. Ouled‐Haddou, V. Picard, L. Garçon

    American Journal of Hematology. 2021, 96, 1017-1026

  27. Нарушения метаболизма эритроцитов и гемолитическая анемия.

    Бойтлер Э.

    Москва: Медицина. 1981, ,

  28. A methemoglobin-dependent and plasma-stimulated experimental model of oxidative hemolysis

    U. Benatti, A. Morelli, G. Damiani, A. De Flora

    Biochemical and Biophysical Research Communications. 1982, 106, 1183-1190

  29. Метаболические изменения, ведущие к окислительному лизису эритроцитов, поддерживаемых в нормальном состоянии in vitro

    Атауллаханов ФИ, Витвицкий ВМ, Жаботинский АМ, Кияткин АБ, Пичугин АВ, Синауридзе ЕИ.

    Биохимия. 1986, 51, 1562-70

  30. Leak formation in human erythrocytes by the radical-forming oxidant t-

    B. Deuticke, K. Heller, C. Haest

    Biochimica et Biophysica Acta (BBA) - Biomembranes. 1986, 854, 169-183

  31. Reversible deformation-dependent erythrocyte cation leak. Extreme sensitivity conferred by minimal peroxidation

    R. Hebbel, N. Mohandas

    Biophysical Journal. 1991, 60, 712-715

  32. The effects of tert-butyl hydroperoxide on human erythrocyte membrane ion transport and the protective actions of antioxidants

    J. Dwight, B. Hendry

    Clinica Chimica Acta. 1996, 249, 167-181

  33. Математическая модель стабилизации объема эритроцитов.

    Мороз ИА, Атауллаханов ФИ, Кияткин АБ, Пичугин АВ, Витвицкий ВМ.

    Биологические Мембраны. 1989, 6, 409-19

  34. Регуляция объема эритроцитов человека. Роль калиевых каналов, активируемых кальцием

    Атауллаханов ФИ, Витвицкий ВМ, Кияткин АБ, Пичугин АВ.

    Биофизика. 1993, 38, 809-21

  35. A Possible Role of Adenylate Metabolism in Human Erythrocytes. 2. Adenylate Metabolism is Able to Improve the Erythrocyte Volume Stabilization

    F. Ataullakhanov, S. Komarova, M. Martynov, V. Vitvitsky

    Journal of Theoretical Biology. 1996, 183, 307-316

  36. A Possible Role of Adenylate Metabolism in Human Erythrocytes: Simple Mathematical Model

    F. Ataullakhanov, S. Komarova, V. Vitvitsky

    Journal of Theoretical Biology. 1996, 179, 75-86

  37. Hereditary stomatocytosis: membrane and metabolism studies

    W. Mentzer, W. Smith, J. Goldstone, S. Shohet

    Blood. 1975, 46, 659-669

  38. Congenital Stomatocytosis and Chronic Haemolytic Anaemia

    U. Bienzle, D. Niethammer, U. Kleeberg, K. Ungefehr, E. Kohne, E. Kleihauer

    Scandinavian Journal of Haematology. 1975, 15, 339-346

  39. Changes in sodium, potassium, and adenosine triphosphate contents of red blood cells in sepsis and septic shock

    Illner H, Shires GT

    Circ Shock . 1982, 9, 259-67

  40. Транспорт ионов в эритроцитах человека при различных формах гемолитической анемии: Корреляционный анализ.

    Орлов СН, Покудин НИ, Эль-Раби ЛС, Брусованик ВИ, Кубатиев АА.

    Биохимия . 1993, 58, 866-73

  41. . Cellular Energy Metabolism and its Regulation

    Atkinson DE.

    New York: Academic Press. 1977, ,

  42. The function of calcium in the potassium permeability of human erythrocytes

    G. Gárdos

    Biochimica et Biophysica Acta. 1958, 30, 653-654

  43. The role of calcium in the potassium permeability of human erythrocytes

    Gardos G.

    Acta Physiol Hung. 1959, 15, 121-5

  44. Calcium ions, drug action and the red cell membrane

    J. Wiley, K. McCulloch

    Pharmacology &amp; Therapeutics. 1982, 18, 271-292

  45. Intracellular calcium content of human erythrocytes: Relation to sodium transport systems

    B. Engelmann, J. Duhm

    The Journal of Membrane Biology. 1987, 98, 79-87

  46. Intracellular free calcium concentration and calcium transport in human erythrocytes of lead-exposed workers

    M. Quintanar-Escorza, M. González-Martínez, L. Navarro, M. Maldonado, B. Arévalo, J. Calderón-Salinas

    Toxicology and Applied Pharmacology. 2007, 220, 1-8

  47. Serum ionised calcium concentration: measurement versus calculation.

    S. Conceicao, D. Weightman, P. Smith, J. Luno, M. Ward, D. Kerr

    BMJ. 1978, 1, 1103-1105

  48. Normal reference ranges for biochemical substances relating to renal, hepatic, and bone function in fetal and maternal plasma throughout pregnancy.

    C. Moniz, K. Nicolaides, F. Bamforth, C. Rodeck

    Journal of Clinical Pathology. 1985, 38, 468-472

  49. Normocalcemic Hyperparathyroidism: Study of its Prevalence and Natural History

    M. Schini, R. Jacques, E. Oakes, N. Peel, J. Walsh, R. Eastell

    The Journal of Clinical Endocrinology &amp; Metabolism. 2020, 105, e1171-e1186

  50. Calcium-dependent potassium exchange in human red cell ghosts.

    T. Simons

    The Journal of Physiology. 1976, 256, 227-244

  51. Variable Ca sensitivity of a K-selective channel in intact red-cell membranes

    V. LEW, H. FERREIRA

    Nature. 1976, 263, 336-338

  52. Single Ca2+-activated k+ channels in human erythrocytes: Ca2+ dependence of opening frequency but not of open lifetimes

    T. Leinders, R. Kleef, H. Vijverberg

    Biochimica et Biophysica Acta (BBA) - Biomembranes. 1992, 1112, 67-74

  53. Distinct metal ion binding sites on Ca2+-activated K+ channels in inside-out patches of human erythrocytes

    T. Leinders, R. van Kleef, H. Vijverberg

    Biochimica et Biophysica Acta (BBA) - Biomembranes. 1992, 1112, 75-82

  54. Studies on adenine and adenosine metabolism by intact human erythrocytes using high performance liquid chromatography

    B. DEAN, D. PERRETT

    Biochimica et Biophysica Acta (BBA) - General Subjects. 1976, 437, 1-15

  55. Adenosine metabolism in human erythrocytes: A study of some factors which affect the metabolic fate of adenosine in intact red cells in vitro

    C. Hawkins, J. Kyd, A. Bagnara

    Archives of Biochemistry and Biophysics. 1980, 202, 380-387

  56. Mechanisms of adenosine 5'-monophosphate catabolism in human erythrocytes

    D. Paglia, W. Valentine, M. Nakatani, R. Brockway

    Blood. 1986, 67, 988-992

  57. Degradation of AMP in erythrocytes of man. Evidence for a cytosolic phosphatase activity

    Rapoport I, Rapoport SM, Gerber G.

    Biomed Biochim Acta . 1987, 46, 317-29

  58. Adenine nucleotide catabolism in human erythrocytes: Pathways and regulation.

    Van Den Berghe G, Bontemps F.

    Biomed. Biochim. Acta. 1990, 49, S117-22

  59. Связь между скоростью АТР-потребляющих процессов и концентрацией АТР в интактных эритроцитах

    Атауллаханов ФИ, Буравцев ВН, Витвицкий ВМ, Дибров БФ, Жаботинский АМ, Пичугин АВ, et al.

    Биохимия. 1980, 45, 1075-9

  60. Increase of Na-K-ATPase activity, glutamate, and aspartate uptake in dog erythrocytes associated with hereditary high accumulation of GSH, glutamate, glutamine, and aspartate

    Y. Maede, M. Inaba, N. Taniguchi

    Blood. 1983, 61, 493-499

  61. 2,3-Дифосфоглицератный шунт и стабилизация уровня АТФ в эритроцитах млекопитающих.

    Атауллаханов АИ, Атауллаханов ФИ, Витвицкий ВМ, Жаботинский АМ, Пичугин АВ.

    Биохимия. 1985, 50, 1005-11

  62. Effects of altering the ATP/ADP ratio on pump-mediated Na/K and Na/Na exchanges in resealed human red blood cell ghosts.

    B. Kennedy, G. Lunn, J. Hoffman

    Journal of General Physiology. 1986, 87, 47-72

  63. Энергозависимые процессы и метаболизм аденилатов в эритроцитах человека

    Атауллаханов ФИ, Витвицкий ВМ, Комарова СВ, Мошаров ЕВ.

    Биохимия. 1996, 61, 266-74

  64. The Regulation of Glycolysis in Human Erythrocytes. The Dependence of the Glycolytic Flux on the ATP Concentration

    F. ATAULLAKHANOV, V. VITVITSKY, A. ZHABOTINSKY, A. PICHUGIN, O. PLATONOVA, B. KHOLODENKO, L. EHRLICH

    European Journal of Biochemistry. 1981, 115, 359-365

  65. Принципы регуляции стационарно функционирующих систем метаболизма.

    Атауллаханов ФИ, Мартынов МВ, Комарова СВ, Витвицкий ВМ.

    Успехи Физиологических Наук. 2022, 53, 1-12

  66. Amino acid transporters revisited: New views in health and disease

    P. Kandasamy, G. Gyimesi, Y. Kanai, M. Hediger

    Trends in Biochemical Sciences. 2018, 43, 752-789

  67. Regulation of cytosol 5′-nucleotidase by adenylate energy charge

    R. Itoh

    Biochimica et Biophysica Acta (BBA) - Enzymology. 1981, 659, 31-37

  68. What determines the intracellular ATP concentration.

    Ataullakhanov FI, Vitvitsky VM.

    Biosci Rep . 2002, 22, 501-11

  69. Древние системы натрий-калиевого гомеостаза клетки как предшественники мембранной биоэнергетики

    Диброва ДВ, Гальперин МЮ, Кунин ЕВ, Мулкиджанян АЯ.

    Биохимия. 2015, 80, 590-611

  70. Anion permeability and erythrocyte swelling

    V. Vitvitsky, E. Frolova, M. Martinov, S. Komarova, F. Ataullakhanov

    Bioelectrochemistry. 2000, 52, 169-177

  71. POTENTIAL, IMPEDANCE, AND RECTIFICATION IN MEMBRANES

    D. Goldman

    Journal of General Physiology. 1943, 27, 37-60

  72. Metabolic dynamics in the human red cell. Part IV—Data prediction and some model computations

    A. Joshi, B. Palsson

    Journal of Theoretical Biology. 1990, 142, 69-85

  73. Application of Biochemical Systems Theory to Metabolism in Human Red Blood Cells

    T. Ni, M. Savageau

    Journal of Biological Chemistry. 1996, 271, 7927-7941

  74. Measurement of membrane potentials (ψ) of erythrocytes and white adipocytes by the accumulation of triphenylmethylphosphonium cation

    K. Cheng, H. Haspel, M. Vallano, B. Osotimehin, M. Sonenberg

    The Journal of Membrane Biology. 1980, 56, 191-201

  75. CVODE, A Stiff/Nonstiff ODE Solver in C.

    Cohen CD, Hindmarsh AC.

    Comput Phys . 1996, 10, 138-43

  76. AUTO 2000: Continuation and bifurcation software for ordinary differential equations (with HomCont).

    Doedel EJ, Paffenroth RC, Champneys AR, Fairgrieve TF, Kuznetsov YA, Sandstede B, et al.

    Tech Report, Calif Inst Technol . 2001, ,