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Eduardo Rios to Calcium

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This is a "connection" page, showing publications Eduardo Rios has written about Calcium.
Eduardo Rios
Connection Strength
10.919
Calcium
  1. Intracellular calcium leak lowers glucose storage in human muscle, promoting hyperglycemia and diabetes. Elife. 2020 05 04; 9.
    View in: PubMed
    Score: 0.529
  2. Abnormal calcium signalling and the caffeine-halothane contracture test. Br J Anaesth. 2019 Jan; 122(1):32-41.
    View in: PubMed
    Score: 0.473
  3. Calsequestrin depolymerizes when calcium is depleted in the sarcoplasmic reticulum of working muscle. Proc Natl Acad Sci U S A. 2017 01 24; 114(4):E638-E647.
    View in: PubMed
    Score: 0.420
  4. A better method to measure total calcium in biological samples yields immediate payoffs. J Gen Physiol. 2015 Mar; 145(3):167-71.
    View in: PubMed
    Score: 0.369
  5. Altered Ca2+ concentration, permeability and buffering in the myofibre Ca2+ store of a mouse model of malignant hyperthermia. J Physiol. 2013 Sep 15; 591(18):4439-57.
    View in: PubMed
    Score: 0.329
  6. Using two dyes with the same fluorophore to monitor cellular calcium concentration in an extended range. PLoS One. 2013; 8(2):e55778.
    View in: PubMed
    Score: 0.320
  7. On an early demonstration of the cell boundary theorem. J Physiol Sci. 2013 Mar; 63(2):161.
    View in: PubMed
    Score: 0.317
  8. Dynamic measurement of the calcium buffering properties of the sarcoplasmic reticulum in mouse skeletal muscle. J Physiol. 2013 Jan 15; 591(2):423-42.
    View in: PubMed
    Score: 0.315
  9. Synthetic localized calcium transients directly probe signalling mechanisms in skeletal muscle. J Physiol. 2012 Mar 15; 590(6):1389-411.
    View in: PubMed
    Score: 0.299
  10. D4cpv-calsequestrin: a sensitive ratiometric biosensor accurately targeted to the calcium store of skeletal muscle. J Gen Physiol. 2011 Aug; 138(2):211-29.
    View in: PubMed
    Score: 0.288
  11. Measurement of RyR permeability reveals a role of calsequestrin in termination of SR Ca(2+) release in skeletal muscle. J Gen Physiol. 2011 Aug; 138(2):231-47.
    View in: PubMed
    Score: 0.288
  12. RyR1 expression and the cell boundary theorem. J Biol Chem. 2010 Aug 20; 285(34):le13; author reply le14.
    View in: PubMed
    Score: 0.270
  13. Paradoxical buffering of calcium by calsequestrin demonstrated for the calcium store of skeletal muscle. J Gen Physiol. 2010 Sep; 136(3):325-38.
    View in: PubMed
    Score: 0.270
  14. The cell boundary theorem: a simple law of the control of cytosolic calcium concentration. J Physiol Sci. 2010 Jan; 60(1):81-4.
    View in: PubMed
    Score: 0.257
  15. Deconstructing calsequestrin. Complex buffering in the calcium store of skeletal muscle. J Physiol. 2009 Jul 01; 587(Pt 13):3101-11.
    View in: PubMed
    Score: 0.247
  16. Evolution and modulation of intracellular calcium release during long-lasting, depleting depolarization in mouse muscle. J Physiol. 2008 Oct 01; 586(19):4609-29.
    View in: PubMed
    Score: 0.234
  17. Store-operated Ca2+ entry during intracellular Ca2+ release in mammalian skeletal muscle. J Physiol. 2007 Aug 15; 583(Pt 1):81-97.
    View in: PubMed
    Score: 0.216
  18. The elusive role of store depletion in the control of intracellular calcium release. J Muscle Res Cell Motil. 2006; 27(5-7):337-50.
    View in: PubMed
    Score: 0.205
  19. The changes in Ca2+ sparks associated with measured modifications of intra-store Ca2+ concentration in skeletal muscle. J Gen Physiol. 2006 Jul; 128(1):45-54.
    View in: PubMed
    Score: 0.202
  20. Depletion "skraps" and dynamic buffering inside the cellular calcium store. Proc Natl Acad Sci U S A. 2006 Feb 21; 103(8):2982-7.
    View in: PubMed
    Score: 0.197
  21. Calcium signalling in muscle: a milestone for modulation studies. J Physiol. 2006 Apr 01; 572(Pt 1):1-2.
    View in: PubMed
    Score: 0.197
  22. Concerted vs. sequential. Two activation patterns of vast arrays of intracellular Ca2+ channels in muscle. J Gen Physiol. 2005 Oct; 126(4):301-9.
    View in: PubMed
    Score: 0.192
  23. A probable role of dihydropyridine receptors in repression of Ca2+ sparks demonstrated in cultured mammalian muscle. Am J Physiol Cell Physiol. 2006 Feb; 290(2):C539-53.
    View in: PubMed
    Score: 0.192
  24. Confocal imaging of [Ca2+] in cellular organelles by SEER, shifted excitation and emission ratioing of fluorescence. J Physiol. 2005 Sep 01; 567(Pt 2):523-43.
    View in: PubMed
    Score: 0.188
  25. How source content determines intracellular Ca2+ release kinetics. Simultaneous measurement of [Ca2+] transients and [H+] displacement in skeletal muscle. J Gen Physiol. 2004 Sep; 124(3):239-58.
    View in: PubMed
    Score: 0.178
  26. Control of dual isoforms of Ca2+ release channels in muscle. Biol Res. 2004; 37(4):583-91.
    View in: PubMed
    Score: 0.170
  27. Ca2+ sparks and embers of mammalian muscle. Properties of the sources. J Gen Physiol. 2003 Jul; 122(1):95-114.
    View in: PubMed
    Score: 0.165
  28. Two components of voltage-dependent inactivation in Ca(v)1.2 channels revealed by its gating currents. Biophys J. 2003 Jun; 84(6):3662-78.
    View in: PubMed
    Score: 0.164
  29. Distinct pathophysiological characteristics in developing muscle from patients susceptible to malignant hyperthermia. Br J Anaesth. 2023 07; 131(1):47-55.
    View in: PubMed
    Score: 0.160
  30. Muscle calcium stress cleaves junctophilin1, unleashing a gene regulatory program predicted to correct glucose dysregulation. Elife. 2023 02 01; 12.
    View in: PubMed
    Score: 0.160
  31. Intracellular Ca(2+) release as irreversible Markov process. Biophys J. 2002 Nov; 83(5):2511-21.
    View in: PubMed
    Score: 0.157
  32. Initiation and termination of calcium sparks in skeletal muscle Front Biosci. 2002 05 01; 7:d1212-1222.
    View in: PubMed
    Score: 0.152
  33. Fast imaging in two dimensions resolves extensive sources of Ca2+ sparks in frog skeletal muscle. J Physiol. 2000 Nov 01; 528(Pt 3):419-33.
    View in: PubMed
    Score: 0.137
  34. Involvement of multiple intracellular release channels in calcium sparks of skeletal muscle. Proc Natl Acad Sci U S A. 2000 Apr 11; 97(8):4380-5.
    View in: PubMed
    Score: 0.132
  35. Spatially segregated control of Ca2+ release in developing skeletal muscle of mice. J Physiol. 1999 Dec 01; 521 Pt 2:483-95.
    View in: PubMed
    Score: 0.128
  36. Calcium release flux underlying Ca2+ sparks of frog skeletal muscle. J Gen Physiol. 1999 Jul; 114(1):31-48.
    View in: PubMed
    Score: 0.125
  37. Local calcium release in mammalian skeletal muscle. J Physiol. 1998 Oct 15; 512 ( Pt 2):377-84.
    View in: PubMed
    Score: 0.119
  38. The voltage sensor of excitation-contraction coupling in mammals: Inactivation and interaction with Ca2. J Gen Physiol. 2017 Nov 06; 149(11):1041-1058.
    View in: PubMed
    Score: 0.111
  39. Small event Ca2+ release: a probable precursor of Ca2+ sparks in frog skeletal muscle. J Physiol. 1997 Jul 01; 502 ( Pt 1):3-11.
    View in: PubMed
    Score: 0.109
  40. 'Quantal' calcium release operated by membrane voltage in frog skeletal muscle. J Physiol. 1997 Jun 01; 501 ( Pt 2):289-303.
    View in: PubMed
    Score: 0.108
  41. Calcium in close quarters: microdomain feedback in excitation-contraction coupling and other cell biological phenomena. Annu Rev Biophys Biomol Struct. 1997; 26:47-82.
    View in: PubMed
    Score: 0.105
  42. Activation of Ca2+ release by caffeine and voltage in frog skeletal muscle. J Physiol. 1996 Jun 01; 493 ( Pt 2):317-39.
    View in: PubMed
    Score: 0.101
  43. Caffeine enhances intramembranous charge movement in frog skeletal muscle by increasing cytoplasmic Ca2+ concentration. J Physiol. 1996 Jun 01; 493 ( Pt 2):341-56.
    View in: PubMed
    Score: 0.101
  44. Ca2+ release from the sarcoplasmic reticulum compared in amphibian and mammalian skeletal muscle. J Gen Physiol. 1996 Jan; 107(1):1-18.
    View in: PubMed
    Score: 0.098
  45. Characterization of Two Human Skeletal Calsequestrin Mutants Implicated in Malignant Hyperthermia and Vacuolar Aggregate Myopathy. J Biol Chem. 2015 Nov 27; 290(48):28665-74.
    View in: PubMed
    Score: 0.096
  46. A damped oscillation in the intramembranous charge movement and calcium release flux of frog skeletal muscle fibers. J Gen Physiol. 1994 Sep; 104(3):449-76.
    View in: PubMed
    Score: 0.089
  47. Reining in calcium release. Biophys J. 1994 Jul; 67(1):7-9.
    View in: PubMed
    Score: 0.088
  48. Ca(2+)-dependent inactivation of cardiac L-type Ca2+ channels does not affect their voltage sensor. J Gen Physiol. 1993 Dec; 102(6):1005-30.
    View in: PubMed
    Score: 0.085
  49. Differential effects of tetracaine on two kinetic components of calcium release in frog skeletal muscle fibres. J Physiol. 1992 Nov; 457:525-38.
    View in: PubMed
    Score: 0.079
  50. Mitochondrial calcium uptake regulates rapid calcium transients in skeletal muscle during excitation-contraction (E-C) coupling. J Biol Chem. 2011 Sep 16; 286(37):32436-43.
    View in: PubMed
    Score: 0.072
  51. The relationship between Q gamma and Ca release from the sarcoplasmic reticulum in skeletal muscle. J Gen Physiol. 1991 May; 97(5):913-47.
    View in: PubMed
    Score: 0.071
  52. Interfering with calcium release suppresses I gamma, the "hump" component of intramembranous charge movement in skeletal muscle. J Gen Physiol. 1991 May; 97(5):845-84.
    View in: PubMed
    Score: 0.071
  53. The mechanical hypothesis of excitation-contraction (EC) coupling in skeletal muscle. J Muscle Res Cell Motil. 1991 Apr; 12(2):127-35.
    View in: PubMed
    Score: 0.070
  54. Ca sparks do not explain all ryanodine receptor-mediated SR Ca leak in mouse ventricular myocytes. Biophys J. 2010 May 19; 98(10):2111-20.
    View in: PubMed
    Score: 0.066
  55. Voltage sensors of the frog skeletal muscle membrane require calcium to function in excitation-contraction coupling. J Physiol. 1988 Apr; 398:475-505.
    View in: PubMed
    Score: 0.057
  56. Calcium-dependent inactivation terminates calcium release in skeletal muscle of amphibians. J Gen Physiol. 2008 Apr; 131(4):335-48.
    View in: PubMed
    Score: 0.057
  57. Ca(2+) sparks operated by membrane depolarization require isoform 3 ryanodine receptor channels in skeletal muscle. Proc Natl Acad Sci U S A. 2007 Mar 20; 104(12):5235-40.
    View in: PubMed
    Score: 0.053
  58. Beta-adrenergic enhancement of sarcoplasmic reticulum calcium leak in cardiac myocytes is mediated by calcium/calmodulin-dependent protein kinase. Circ Res. 2007 Feb 16; 100(3):391-8.
    View in: PubMed
    Score: 0.053
  59. Regulation of Ca2+ sparks by Ca2+ and Mg2+ in mammalian and amphibian muscle. An RyR isoform-specific role in excitation-contraction coupling? J Gen Physiol. 2004 Oct; 124(4):409-28.
    View in: PubMed
    Score: 0.045
  60. The quantal nature of Ca2+ sparks and in situ operation of the ryanodine receptor array in cardiac cells. Proc Natl Acad Sci U S A. 2004 Mar 16; 101(11):3979-84.
    View in: PubMed
    Score: 0.043
  61. Differential effects of voltage-dependent inactivation and local anesthetics on kinetic phases of Ca2+ release in frog skeletal muscle. Biophys J. 2003 Jul; 85(1):245-54.
    View in: PubMed
    Score: 0.041
  62. Thermodynamically irreversible gating of ryanodine receptors in situ revealed by stereotyped duration of release in Ca(2+) sparks. Biophys J. 2002 Jul; 83(1):242-51.
    View in: PubMed
    Score: 0.038
  63. Molecular cloning and functional expression of a skeletal muscle dihydropyridine receptor from Rana catesbeiana. J Biol Chem. 1998 Sep 25; 273(39):25503-9.
    View in: PubMed
    Score: 0.030
  64. Characterization of Post-Translational Modifications to Calsequestrins of Cardiac and Skeletal Muscle. Int J Mol Sci. 2016 Sep 13; 17(9).
    View in: PubMed
    Score: 0.026
  65. Imaging elementary events of calcium release in skeletal muscle cells. Science. 1995 Sep 22; 269(5231):1723-6.
    View in: PubMed
    Score: 0.024
  66. Properties and roles of an intramembranous charge mobilized at high voltages in frog skeletal muscle. J Physiol. 1995 Jul 15; 486 ( Pt 2):385-400.
    View in: PubMed
    Score: 0.024
  67. Perchlorate enhances transmission in skeletal muscle excitation-contraction coupling. J Gen Physiol. 1993 Sep; 102(3):373-421.
    View in: PubMed
    Score: 0.021
  68. An allosteric model of the molecular interactions of excitation-contraction coupling in skeletal muscle. J Gen Physiol. 1993 Sep; 102(3):449-81.
    View in: PubMed
    Score: 0.021
  69. Isoproterenol increases the fraction of spark-dependent RyR-mediated leak in ventricular myocytes. Biophys J. 2013 Mar 05; 104(5):976-85.
    View in: PubMed
    Score: 0.020
  70. Two classes of gating current from L-type Ca channels in guinea pig ventricular myocytes. J Gen Physiol. 1992 Jun; 99(6):863-95.
    View in: PubMed
    Score: 0.019
  71. Charge movement and the nature of signal transduction in skeletal muscle excitation-contraction coupling. Annu Rev Physiol. 1992; 54:109-33.
    View in: PubMed
    Score: 0.019
  72. Voltage sensor of excitation-contraction coupling in skeletal muscle. Physiol Rev. 1991 Jul; 71(3):849-908.
    View in: PubMed
    Score: 0.018
  73. Hyperactive intracellular calcium signaling associated with localized mitochondrial defects in skeletal muscle of an animal model of amyotrophic lateral sclerosis. J Biol Chem. 2010 Jan 01; 285(1):705-12.
    View in: PubMed
    Score: 0.016
  74. Effects of extracellular calcium on calcium movements of excitation-contraction coupling in frog skeletal muscle fibres. J Physiol. 1988 Apr; 398:441-73.
    View in: PubMed
    Score: 0.014
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