FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2161799774> ?p ?o ?g. }

• W2161799774 endingPage "606" @default.
• W2161799774 startingPage "593" @default.
• W2161799774 abstract "Annals of the New York Academy of SciencesVolume 204, Issue 1 p. 593-606 ACCUMULATION AND EXCLUSION OF IONS IN CONTRACTILE TISSUE OF DEVELOPING ANIMALS* C. F. Hazlewood, C. F. Hazlewood Departments of Physiology and Pediatrics Baylor College of Medicine Texas Children's Hospital and Department of Physics Rice University Houston, Texas 77025Search for more papers by this author C. F. Hazlewood, C. F. Hazlewood Departments of Physiology and Pediatrics Baylor College of Medicine Texas Children's Hospital and Department of Physics Rice University Houston, Texas 77025Search for more papers by this author First published: March 1973 https://doi.org/10.1111/j.1749-6632.1973.tb30806.xCitations: 8 * This work was supported by grants from the Robert A. Welch Foundation. The David Underwood Trust Fund, and by USPHS Research Grants RR-05425, FR-00259, and RR-0188 from the General Clinical Research Centers Program of the Division of Research Resources, National Institutes of Health, Bethesda, Md. AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onEmailFacebookTwitterLinkedInRedditWechat References 1 Vernadakis, A. & D. M. Woodbury. 1964. electrolyte and nitrogen changes in skeletal muscle of developing rats. am. j. physiol. 206: 1365. 2 Novikova, A. I. 1964. age change in the ion composition of muscle fibers and their relation to membrane potentials. fiziol. zh. sssr imeni i. m. seche-nova (moskva). 50: 626. 3 Hazlewood, C. F. & B. L. Nichols. 1969. changes in muscle sodium, potassium, chloride, water and voltage during maturation in the rat: an experimental and theoretical study. hopkins med. j. 125: 119. 4 Widdowson, E. M. & J. W. T. Dickerson. 1964. chemical composition of the body. in mineral metabolism, volume ii, part a. C. L. Comar & F. Bronner, eds. vol. 2, part a: 1. academic press. new york , n. y. 5 Bergström, J., J. Boëthius & E. Hultman. 1971. electrolytes in leg neck muscles of the rat during ontogeny. acta physiol. scand. 81: 164. 6 Luff, A. R. & G. Goldspink. 1970. changes in the water and electrolyte content of skeletal muscles of the mouse during postnatal development. comp. biochem. physiol. 82: 581. 7 Fudel-osipova, S. I. & O. A. Martynenko. 1964. early ontogenic development of membrane potential of muscle fibers in rats. fed. proc. 23, no. 1, part 2: t28. fiziol. zh. (kiev). 8(4), 1962. 8 Hazlewood, C. F. & B. L. Nichols. 1967. an in vitro study of resting muscle membrane potential in preweanling and weanling rat. nature 213: 935. 9 Hazlewood, C. F. & B. L. Nichols. 1968. the in vivo muscle resting potential in the developing rat. hopkins med. j. 123: 198. 10 Boëthius, J. 1971. electrophysiological and morphological development of leg and neck muscles in the rat. acta physiol. scand. 81: 492. 11 Hodgkin, A. L. 1951. the ionic basis of electrical activity in nerve and muscle. biol. rev. 26: 339. 12 Caldwell, P. C. 1968. factors governing movement and distribution of inorganic ions in nerve and muscle. physiol. rev. 48: 1. 13 Abetsedarskaya, L. A., F. G. Miftakhutdinova & V. D. Fedotov. 1968. state of water in live tissues (results of investigations by the nmr spin-echo method). biofizika 13: 630. (russian) translated by pergamon press. biophysics 13: 750. 14 Bratton, C. B., A. L. Hopkins & J. W. Weinberg. 1968. nuclear magnetic resonance studies of living muscle. science 147: 738. 15 Chang, D. C., C. F. Hazlewood, B. L. Nichols & H. E. Rorschach. 1972. spin-echo studies on cellular water. nature. 235: 170. 16 Chapman, G. & K. A. Mclauchlan. 1967. oriented water in the sciatic nerve of rabbit. nature 215: 391. 17 Clifford, J., B. A. Pethica & E. G. Smith. 1968. a nuclear magnetic resonance investigation of molecular motion in erythrocyte membranes. in proceedings 1967 international conference on biological membranes. L. Bolis & B. A. Pethica, eds.: 19. north holland pub. co. amsterdam , the netherlands . 18 Cope, F. W. 1969. nuclear magnetic evidence using d 2o for structured water in muscle and brain. biophys. j. 9: 303. 19 Fritz, O. G. & T. J. Swift. 1967. the state of water is polarized and depolarized frog nerves: a proton magnetic resonance study. biophys. j. 7: 675. 20 Hazlewood, C. F., B. L. Nichols & N. F. Chamberlain. 1969. evidence for the existence of a minimum of two phases of ordered water in skeletal muscle. nature 222: 747. 21 Hazlewood, C. F. & B. L. Nichols. 1969. an nmr study of skeletal muscle: changes in water structure with normal development. physiologist 12: 251. 22 Hazlewood, C. F. & J. M. Ginsh. 1969. skeletal muscle electrolytes as a function of age in normal and dystrophic mice of strain 129. hopkins med. j. 124: 132. 23 Hazlewood, C. F., B. L. Nichols & N. F. Chamberlain. 1970. the physical state of water in skeletal muscle of normal and dystrophic mice of strain 129. in muscle diseases. int'l. congress series no. 199. J. N. Walton, N. Canal, G. Scarlato & J. R. N. Cleave, eds. excerpta medica. amsterdam , the netherlands . 24 Hazlewood, C. F., B. L. Nichols, D. C. Chang & B. Brown. 1971. on the state of water in developing muscle: a study of the major phase of ordered water in skeletal muscle and its relationship to sodium concentration. johns hopkins med. j. 128: 117. 25 Joseph, N. R. 1966. intracellular hydration of ions in relation to age. gerontologia 12: 155. 26 Joseph, N. R. 1968. electrolyte balance and cellular aging. gerontologia 14: 142. 27 Ling, G. N. & W. Negendank. 1970. the physical state of water in frog muscles. physiol. chem. phys. 2: 15. 28 Odeblad, E., B. N. Bhar & G. Lindstrom. 1956. proton magnetic resonance of human red blood cells in heavy-water exchange experiments. arch. biophys. biophys. 63: 221. 29 Pöcsik, S. 1967. bound water in muscle. acta biochim. biophys. acad. sci. hung. 2: 149. 30 Pöcsik, S. 1969. structure of muscle water. acta biochim. biophys. acad. sci. hung. 4: 395. 31 Mclaughlin, S. G. A. & J. A. M. Hinke. 1966. sodium and water binding in single striated muscle fibers of the giant barnacle. canad. j. physiol. pharmacol. 44: 837. 32 Cope, F. W. 1967. nmr evidence for complexing of na + in muscle, kidney, and brain and by actmyosin. the relation of cellular complexing of na + to water structure and transport kinetics. j. gen. physiol. 50: 1353. 33 Czeisler, J. L., O. G. Fritz, jr. & T. J. Swift. 1970. direct evidence from nuclear magnetic resonance studies for bound sodium in frog skeletal muscle. biophys. j. 10: 260. 34 Ling, G. N. & F. W. Cope. 1969. potassium ion: is the bulk of intracellular k + adsorbed science 163: 1335. 35 Martinez, D., A. A. Silvidi & R. M. Stokes. 1969. nuclear magnetic resonance studies of sodium ions in isolated frog muscle and liver. biophysical j. 9: 1256. 36 Ling, G. N. 1969. a new model for the living cell: a summary of the theory and recent experimental evidence in its support. int'l rev. cytol. 26: 1. 37 Ling, G. N. & G. Bohr. 1970. studies on ion distribution in living cells. ii. cooperative interaction between intracellular potassium and sodium ions. biophys. j. 10: 519. 38 Troshin, A. S. 1966. problems of cell permeability. pergamon press. new york , n. y. 39 Ling, G. N. 1962. a physical theory of the living state: the association-induction hypothesis. blaisdell publishing co. new york , n. y. 40 Ernst, E. 1963. biophysics of the striated muscle. hungarian academy of science. budapest , hungary . 41 Jones, A. W. & G. Karreman. 1969. ion exchange properties of the canine artery. biophysical j. 9: 884. 42 Jones, A. W. & G. Karreman. 1969. potassium accumulation and permeation in the canine carotid artery. biophysical j. 9: 910. 43 Jones, A. W. 1970. effects of progesterone treatment on potassium accumulation and permeation in rabbit myometrium. physiol. chem. and physics. 2: 151. 44 Reisin, I. L., C. A. Rotunno, L. Corchs, V. Kowalewski & M. Cereijido. 1970. the state of sodium in epithelial tissues as studied by nuclear resonance. physiol. chem. and physics. 2: 171. 45 Ling, G. N. & M. M. Ochsenfeld. 1966. studies on ion accumulation in muscle cells. biophysical j. 49: 819. 46 Cope, F. W. & R. Damadian. 1970. cell potassium by 39k spin-echo nuclear magnetic resonance. nature 228: 76. 47 Damadian, R. 1971. biological ion exchanger resins i. quantitative electrostatic correspondence of fixed charge and mobile counter ion. biophys. j. 11: 739. 48 Damadian, R., M. Goldsmith & K. S. Zaner. 1971. biological ion exchanger resins ii. querp water and ion exchange selectivity. biophys. j. 11: 761. 49 Damadian, R. 1971. biological ion exchanger resins iii. molecular interpretation of cellular ion exchange. biophys. j. 11: 773. 50 Goldspink, G. 1968. an attempt at estimating extra fiber fluid in small skeletal muscles by a simple physical method. canad. j. physiol. pharmacol. 44: 765. 51 Dean, R. B. 1941. theories of electrolyte equilibrium in muscle. biol. symp. 3: 331. 52 Keynes, R. D. & G. W. Maisel. 1954. the energy requirement for sodium extrusion from a frog muscle. proc. roy. soc. series b, 142: 383. 53 Hodgkin, A. L. & P. Horowitz. 1959. movements of na and k in single muscle fibres. j. physiol. 145: 405. 54 Ling, G. N. 1970. studies on ion permeability. i. what determines the rate of na + ion efflux from frog muscle cells physiol. chem. & physics. 2: 242. 55 Lev, A. A. 1964. determination of activity and activity coefficients of potassium and sodium ions in frog muscle fibres. nature 201: 1132. 56 Brigden, M. L., A. W. Spira & J. A. M. Hinke. 1971. the extracellular space of the single fiber from the giant barnacle. canad. j. physiol. and pharm. 49: 801. 57 Hazlewood, C. F., D. C. Chang, H. E. Rorschach & B. L. Nichols. 1972. cellular water and macromolecules. in reversibility of cellular injury due to inadequate perfusion. T. I. Malinin & Charles C. Thomas, eds. springfield , illinois . 58 Miller, C. & G. N. Ling. 1970. structural change of intracellular water in caffeine-contracted muscle cells. physiol. chem. and physics. 2: 495. 59 Chambers, R. & H. P. Hale. 1932. the formation of ice in protoplasm. proc. roy. soc. series b, 110: 336. 60 Rapatz, G. & B. Luyet. 1959. on the mechanism of ice formation and propagation in muscle. biodynamica 8: 121. 61 Gulati, J., M. M. Ochsenfeld & G. N. Ling. 1971. metabolic co-operative control of electrolyte levels by adenosine triphosphate in the frog muscle. biophys. j. 11: 973. 62 Trayer, I. P., C. I. Harris & S. V. Perry. 1968. 3-methyl histidine and adult and foetal forms of skeletal muscle myosin. nature 217: 452. 63 Ling, G. N. 1972. This volume. Citing Literature Volume204, Issue1Physicochemical State of Ions and Water in Living Tissues and Model SystemsMarch 1973Pages 593-606 ReferencesRelatedInformation" @default.
• W2161799774 created "2016-06-24" @default.
• W2161799774 creator A5054340492 @default.
• W2161799774 date "1973-03-01" @default.
• W2161799774 modified "2023-10-16" @default.
• W2161799774 title "ACCUMULATION AND EXCLUSION OF IONS IN CONTRACTILE TISSUE OF DEVELOPING ANIMALS" @default.
• W2161799774 cites W1436151645 @default.
• W2161799774 cites W1760159343 @default.
• W2161799774 cites W1964174461 @default.
• W2161799774 cites W1966136588 @default.
• W2161799774 cites W1967024534 @default.
• W2161799774 cites W1968301424 @default.
• W2161799774 cites W1977853330 @default.
• W2161799774 cites W1977882338 @default.
• W2161799774 cites W1978768868 @default.
• W2161799774 cites W1988107141 @default.
• W2161799774 cites W1992095948 @default.
• W2161799774 cites W1993009287 @default.
• W2161799774 cites W2009722605 @default.
• W2161799774 cites W2009829796 @default.
• W2161799774 cites W2011208714 @default.
• W2161799774 cites W2012327383 @default.
• W2161799774 cites W2023774535 @default.
• W2161799774 cites W2027939789 @default.
• W2161799774 cites W2031553442 @default.
• W2161799774 cites W2040402953 @default.
• W2161799774 cites W2046711081 @default.
• W2161799774 cites W2056895505 @default.
• W2161799774 cites W2058933118 @default.
• W2161799774 cites W2075824447 @default.
• W2161799774 cites W2078427366 @default.
• W2161799774 cites W2079793987 @default.
• W2161799774 cites W2079938832 @default.
• W2161799774 cites W2085047220 @default.
• W2161799774 cites W2090168621 @default.
• W2161799774 cites W2135091009 @default.
• W2161799774 cites W2147413889 @default.
• W2161799774 cites W2181286072 @default.
• W2161799774 cites W2409914831 @default.
• W2161799774 cites W2616110872 @default.
• W2161799774 cites W2767933585 @default.
• W2161799774 cites W50627222 @default.
• W2161799774 doi "https://doi.org/10.1111/j.1749-6632.1973.tb30806.x" @default.
• W2161799774 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/4513171" @default.
• W2161799774 hasPublicationYear "1973" @default.
• W2161799774 type Work @default.
• W2161799774 sameAs 2161799774 @default.
• W2161799774 citedByCount "11" @default.
• W2161799774 crossrefType "journal-article" @default.
• W2161799774 hasAuthorship W2161799774A5054340492 @default.
• W2161799774 hasConcept C105702510 @default.
• W2161799774 hasConcept C12554922 @default.
• W2161799774 hasConcept C145148216 @default.
• W2161799774 hasConcept C178790620 @default.
• W2161799774 hasConcept C185592680 @default.
• W2161799774 hasConcept C86803240 @default.
• W2161799774 hasConcept C95444343 @default.
• W2161799774 hasConceptScore W2161799774C105702510 @default.
• W2161799774 hasConceptScore W2161799774C12554922 @default.
• W2161799774 hasConceptScore W2161799774C145148216 @default.
• W2161799774 hasConceptScore W2161799774C178790620 @default.
• W2161799774 hasConceptScore W2161799774C185592680 @default.
• W2161799774 hasConceptScore W2161799774C86803240 @default.
• W2161799774 hasConceptScore W2161799774C95444343 @default.
• W2161799774 hasIssue "1 Physicochemic" @default.
• W2161799774 hasLocation W21617997741 @default.
• W2161799774 hasLocation W21617997742 @default.
• W2161799774 hasOpenAccess W2161799774 @default.
• W2161799774 hasPrimaryLocation W21617997741 @default.
• W2161799774 hasRelatedWork W1531601525 @default.
• W2161799774 hasRelatedWork W2319480705 @default.
• W2161799774 hasRelatedWork W2384464875 @default.
• W2161799774 hasRelatedWork W2398689458 @default.
• W2161799774 hasRelatedWork W2606230654 @default.
• W2161799774 hasRelatedWork W2607424097 @default.
• W2161799774 hasRelatedWork W2748952813 @default.
• W2161799774 hasRelatedWork W2899084033 @default.
• W2161799774 hasRelatedWork W2948807893 @default.
• W2161799774 hasRelatedWork W2778153218 @default.
• W2161799774 hasVolume "204" @default.
• W2161799774 isParatext "false" @default.
• W2161799774 isRetracted "false" @default.
• W2161799774 magId "2161799774" @default.
• W2161799774 workType "article" @default.