FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2081803634> ?p ?o ?g. }

• W2081803634 endingPage "87" @default.
• W2081803634 startingPage "71" @default.
• W2081803634 abstract "Annals of the New York Academy of SciencesVolume 492, Issue 1 p. 71-87 General Anesthetic and Specific Effects of Ethanol on Acetylcholine Receptorsa KEITH W. MILLER, KEITH W. MILLER Departments of Anaesthesia and Pharmacology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114Search for more papers by this authorLEONARD L. FIRESTONE AND, LEONARD L. FIRESTONE AND Departments of Anaesthesia and Pharmacology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114Search for more papers by this authorSTUART A. FORMAN, STUART A. FORMAN Departments of Anaesthesia and Pharmacology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114Search for more papers by this author KEITH W. MILLER, KEITH W. MILLER Departments of Anaesthesia and Pharmacology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114Search for more papers by this authorLEONARD L. FIRESTONE AND, LEONARD L. FIRESTONE AND Departments of Anaesthesia and Pharmacology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114Search for more papers by this authorSTUART A. FORMAN, STUART A. FORMAN Departments of Anaesthesia and Pharmacology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114Search for more papers by this author First published: April 1987 https://doi.org/10.1111/j.1749-6632.1987.tb48656.xCitations: 26 a Supported by National Institute of General Medical Sciences Training Grant GM-07592 and Center Grant GM-15904 to the Harvard Anaesthesia Research Center and by the Department of Anesthesia, Massachusetts General Hospital. 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 References 1 Forman, S. A., A. S. Verkman, J. A. Dix & A. K. Solomon. 1985. n-Alkanols and halothane inhibit red cell anion transport and increase band 3 conformational change rate. Biochemistry 24: 4859– 4866. 2 Miller, K. W. 1985. The nature of the site of general anesthesia. Int. Rev. Neurobiol. 27: 1– 57. 3 Roth, S. H. 1979. Physical mechanisms of anesthesia. Annu. Rev. Pharmacol. Toxicol. 19: 159– 178. 4 Janoff, A. S. & K. W. Miller. 1982. A critical assessment of the lipid theories of general anaesthetic action. In Biological Membranes. D. Chapman, Ed. Vol. 4: 417– 476. Academic Press. London . 5 Franks, N. P. & W. R. Lieb. 1982. Molecular mechanisms of general anaesthesia. Nature 300: 487– 493. 6 Dluzewski, A. R., M. J. Halsey & A. C. Simmonds. 1983. Membrane interactions with general and local anesthetics: a review of molecular hypotheses of anaesthesia. Mol. Aspects Med. 6: 459– 573. 7 Goldstein, D. B. 1984. The effects of drugs on membrane fluidity. Annu. Rev. Pharmacol. Toxicol. 24: 43– 64. 8 Worcester, D. L. 1975. Neutron diffraction studies of biological membranes and membrane components. In Neutron Scattering for the Analysis of Biological Structures. B. P. Schoenborn, Ed. Vol. 27: 37– 57. Brookhaven National Laboratory. Upton , NY . 9 Presti, F. T. 1985. The role of cholesterol in regulating membrane fluidity. In Membrane Fluidity in Biology. R. Aloia & J. M. Boggs, Eds. Vol. 4: 97– 146. Academic Press. New York , NY . 10 Miller, K. W., L. Hammond & E. G. Porter. 1977. The solubility of hydrocarbon gases in lipid bilayers. Chem. Phys. Lipids 20: 229– 241. 11 Katz, Y. & J. M. Diamond. 1974. Thermodynamic constants for nonelectrolyte partition between dimyristoyl lecithin and water. J. Membr. Biol. 17: 101– 120. 12 Colley, C. M., S. M. Metcalfe, B. Turner, A. S. V. Burgen & J. C. Metcalfe. 1971. The binding of benzyl alcohol to erythrocyte membranes. Biochim. Biophys. Acta 233: 720– 729. 13 Jain, M. K. & N. M. Wu. 1977. Effect of small molecules on the dipalmitoyl lecithin liposomal bilayers: III. Phase transition in lipid bilayers. J. Membr. Biol. 34: 157– 201. 14 Rowe, E. S. 1983. Lipid chain length and temperature dependence of ethanol-phosphatidyl-choline interactions. Biochemistry 22: 3299– 3305. 15 Urban, B. W. 1985. Modifications of excitable membranes by volatile and gaseous anesthetics. In Effects of Anesthesia. B. G. Covino, H. A. Fozzard, K. Rehder & G. Strichartz, Eds. 13– 28. American Physiological Society. Bethesda , MD . 16 Haydon, J., J. R. Elliott, B. M. Hendry & B. W. Urban. 1986. The action of nonionic anesthetic substances on voltage-gated ion conductances in squid giant axons. In Molecular and Cellular Mechanisms of Anesthetics. S. H. Roth & K. W. Miller, Eds. 267– 277. Plenum Publishing Company. New York , NY . 17 Williams, R. J. P. 1979. The conformational properties of proteins in solution. Biol. Rev. 54: 389– 437. 18 Settle, W. 1973. Function of the myoglobin molecule as influenced by anesthetic molecules. In A Guide to Molecular Pharmacology and Toxicology. R. M. Featherstone, Ed. Part II: 477– 493. Marcel Dekker, Inc. New York , N.Y . 19 Tilton, R. F., Jr., I. D. Kuntz, Jr. & G. A. Petsko. 1984. Cavities in proteins: structure of a metmyoglobin-xenon complex solved to 1.9 Å. Biochemistry 23: 2849– 2857. 20 Franks, N. P. & W. R. Lieb. 1984. Do general anaesthetics act by competitive binding to specific receptors Nature 310: 599– 601. 21 Noda, M., H. Takahashi, T. Tanabe, M. Toyosato, S. Kikyotani, Y. Furutani, T. Hirose, H. Takashima, S. Inayama, T. Miyata & S. Numa. 1983. Structural homology of Torpedo californica acetylcholine receptor subunits. Nature 302: 528– 532. 22 Conti-Tronconi, B. M. & M. A. Raitery. 1982. The nicotinic cholinergic receptor: correlation of molecular structure with functional properties. Annu. Rev. Biochem. 51: 491– 530. 23 Changeux, J. -P., A. Devillers-Thiery & P. Chemouilli. 1984. Acetylcholine receptor: an allosteric protein. Science 225: 1335– 1345. 24 Fairclough, R. H., J. Finer-More, R. A. Love, D. Kristofferson, P. J. Desmeules & R. M. Stroud. 1983. Subunit organization and structure of an acetylcholine receptor. Cold Spring Harbor Symposium on Quant. Biol. 48: 9– 20. 25 Sackman, B., C. Methfessel, M. Mishina, T. Takahashi, T. Takai, M. Kurasaki, K. Fukuda & S. Numa. 1985. Role of acetylcholine receptor subunits in gating of the channel. Nature 318: 538– 543. 26 Fong, T. M. & M. G. McNamee. 1986. Correlation between acetylcholine receptor function and structural properties of membranes. Biochemistry 25: 830– 840. 27 Neubig, R. R., N. D. Boyd & J. B. Cohen. 1982. Conformations of Torpedo acetylcholine receptor associated with ion transport and desensitization. Biochemistry 21: 3460– 3467. 28 Gage, P. W. & O. P. Hamill. 1981. Effects of anesthetics on ion channels in synapses. Int. Rev. Physiol. 25: 1– 45. 29 Bradley, R. J., R. Sterz & K. Peper. 1984. The effects of alcohols and diols at the nicotinic acetylcholine receptor of the neuromuscular junction. Brain Res. 295: 101– 112. 30 McLarnon, J. G., P. Pennefather & D. M. J. Quastel. 1986. Mechanism of nicotinic channel blockade by anesthetics. In Molecular and Cellular Mechanisms of Anesthetics. S. H. Roth & K. W. Miller, Eds. 155– 164. Plenum Publishing Company. New York , NY . 31 Gage, P. W., D. McKinnon & B. Robertson. 1986. The influence of anesthetics on postsynaptic ion channels. In Molecular and Cellular Mechanisms of Anesthetics. S. H. Roth & K. W. Miller, Eds. 139– 153. Plenum Publishing Company. New York , NY . 32 Boyd, N. D. & J. Cohen. 1984. Desensitization of membrane-bound Torpedo acetylcholine receptor by amine noncompetitive antagonists and aliphatic alcohols: studies of [3H]-acetylcholine binding and 22Na+ ion fluxes. Biochemistry 23: 4023– 4033. 33 Young, A. P. & D. S. Sigman. 1981. Allosteric effect of volatile anesthetics on the membrane-bound acetylcholine receptor. Mol. Pharmacol. 20: 498– 505. 34 El-Fakahany, E. F., E. R. Miller, M. A. Abbassy, A. T. Eldefrawi & M. E. Eldefrawi. 1983. Alcohol modulation of drug binding to the channel sites of the nicotinic acetylcholine receptor. J. Pharmacol. Exp. Ther. 224: 289– 296. 35 Braswell, L. M., K. W. Miller & J. F. Sauter. 1984. Pressure reversal of the action of octanol on postsynaptic membranes from Torpedo. Br. J. Pharmacol. 83: 305– 311. 36 Miller, K. W., L. M. Braswell, L. L. Firestone, B. A. Dodson & S. A. Forman. 1986. General anesthetics act both specifically and nonspecifically on acetylcholine receptors. In Molecular and Cellular Mechanisms of Anesthetics. S. H. Roth & K. W. Miller, Eds. 125– 137. Plenum Medical Book Company. New York , NY . 31 Firestone, L. L., J.-F. Sauter, L. M. Braswell & K. W. Miller. 1986. The actions of general anesthetics on acetylcholine receptor-rich membranes from Torpedo. Anesthesiology 64: 694– 702. 38 Hubbell, W. L. & H. M. McConnell. 1971. Molecular motion in spin-labeled phospholipids and membranes. J. Amer. Chem. Soc. 93: 314– 326. 39 Nelson, D. J. & F. Sachs. 1981. Ethanol decreases dissociation of agonist from nicotinic channels. Biophys. J. 33: 121a. 40 Meyer, H. H. 1901. Zur theorie der alkoholnarkose. Arch. Exp. Pathol. Pharmakol. 46: 338– 346. Citing Literature Volume492, Issue1Alcohol and the CellApril 1987Pages 71-87 ReferencesRelatedInformation" @default.
• W2081803634 created "2016-06-24" @default.
• W2081803634 creator A5038922547 @default.
• W2081803634 creator A5050184660 @default.
• W2081803634 creator A5065081270 @default.
• W2081803634 date "1987-04-01" @default.
• W2081803634 modified "2023-10-16" @default.
• W2081803634 title "General Anesthetic and Specific Effects of Ethanol on Acetylcholine Receptors" @default.
• W2081803634 cites W1639006700 @default.
• W2081803634 cites W1963892699 @default.
• W2081803634 cites W1964490459 @default.
• W2081803634 cites W1968639255 @default.
• W2081803634 cites W1971518907 @default.
• W2081803634 cites W1971780885 @default.
• W2081803634 cites W1977726639 @default.
• W2081803634 cites W1982426004 @default.
• W2081803634 cites W1995123084 @default.
• W2081803634 cites W2005782249 @default.
• W2081803634 cites W2009159998 @default.
• W2081803634 cites W2016510182 @default.
• W2081803634 cites W2018781128 @default.
• W2081803634 cites W2021020591 @default.
• W2081803634 cites W2024234388 @default.
• W2081803634 cites W2028401432 @default.
• W2081803634 cites W2037824324 @default.
• W2081803634 cites W2045961778 @default.
• W2081803634 cites W2048649242 @default.
• W2081803634 cites W2050687568 @default.
• W2081803634 cites W2051989261 @default.
• W2081803634 cites W2058371612 @default.
• W2081803634 cites W2064048353 @default.
• W2081803634 cites W2095919951 @default.
• W2081803634 cites W2107326323 @default.
• W2081803634 cites W2320829433 @default.
• W2081803634 cites W2333346662 @default.
• W2081803634 cites W2475736087 @default.
• W2081803634 cites W2489696179 @default.
• W2081803634 cites W2489887089 @default.
• W2081803634 cites W2504326298 @default.
• W2081803634 cites W2895881097 @default.
• W2081803634 cites W3026678189 @default.
• W2081803634 doi "https://doi.org/10.1111/j.1749-6632.1987.tb48656.x" @default.
• W2081803634 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/2440361" @default.
• W2081803634 hasPublicationYear "1987" @default.
• W2081803634 type Work @default.
• W2081803634 sameAs 2081803634 @default.
• W2081803634 citedByCount "31" @default.
• W2081803634 countsByYear W20818036342015 @default.
• W2081803634 countsByYear W20818036342018 @default.
• W2081803634 crossrefType "journal-article" @default.
• W2081803634 hasAuthorship W2081803634A5038922547 @default.
• W2081803634 hasAuthorship W2081803634A5050184660 @default.
• W2081803634 hasAuthorship W2081803634A5065081270 @default.
• W2081803634 hasConcept C170493617 @default.
• W2081803634 hasConcept C185592680 @default.
• W2081803634 hasConcept C2775910092 @default.
• W2081803634 hasConcept C2778162923 @default.
• W2081803634 hasConcept C2780161600 @default.
• W2081803634 hasConcept C42219234 @default.
• W2081803634 hasConcept C55493867 @default.
• W2081803634 hasConcept C71924100 @default.
• W2081803634 hasConcept C80161118 @default.
• W2081803634 hasConcept C98274493 @default.
• W2081803634 hasConceptScore W2081803634C170493617 @default.
• W2081803634 hasConceptScore W2081803634C185592680 @default.
• W2081803634 hasConceptScore W2081803634C2775910092 @default.
• W2081803634 hasConceptScore W2081803634C2778162923 @default.
• W2081803634 hasConceptScore W2081803634C2780161600 @default.
• W2081803634 hasConceptScore W2081803634C42219234 @default.
• W2081803634 hasConceptScore W2081803634C55493867 @default.
• W2081803634 hasConceptScore W2081803634C71924100 @default.
• W2081803634 hasConceptScore W2081803634C80161118 @default.
• W2081803634 hasConceptScore W2081803634C98274493 @default.
• W2081803634 hasIssue "1 Alcohol and t" @default.
• W2081803634 hasLocation W20818036341 @default.
• W2081803634 hasLocation W20818036342 @default.
• W2081803634 hasOpenAccess W2081803634 @default.
• W2081803634 hasPrimaryLocation W20818036341 @default.
• W2081803634 hasRelatedWork W1964242422 @default.
• W2081803634 hasRelatedWork W1988615846 @default.
• W2081803634 hasRelatedWork W1990648371 @default.
• W2081803634 hasRelatedWork W2045644095 @default.
• W2081803634 hasRelatedWork W2079880301 @default.
• W2081803634 hasRelatedWork W2085694694 @default.
• W2081803634 hasRelatedWork W2133494168 @default.
• W2081803634 hasRelatedWork W2141284133 @default.
• W2081803634 hasRelatedWork W2335529075 @default.
• W2081803634 hasRelatedWork W2085620404 @default.
• W2081803634 hasVolume "492" @default.
• W2081803634 isParatext "false" @default.
• W2081803634 isRetracted "false" @default.
• W2081803634 magId "2081803634" @default.
• W2081803634 workType "article" @default.