Compounds > acebutolol

acebutolol and phloretin

acebutolol has been researched along with phloretin in 11 studies

Research

Studies (11)

TimeframeStudies, this research(%)All Research%
pre-19907 (63.64)18.7374
1990's1 (9.09)18.2507
2000's2 (18.18)29.6817
2010's0 (0.00)24.3611
2020's1 (9.09)2.80

Authors

AuthorsStudies
Basketter, DA; Widdas, WF1
May, JM2
Krupka, RM2
Widdas, WF1
Baker, GF; Widdas, WF1
Baker, GF; Baker, P; O'Gorman, R1
Blodgett, DM; Carruthers, A1
Carruthers, A; Leitch, JM1
Hatano, R; Kimura, I; Lee, E; Ma, Y; Miki, T; Miyamoto, J; Noda, T; Yoshikawa, H1

Other Studies

11 other study(ies) available for acebutolol and phloretin

ArticleYear
Asymmetry of the hexose transfer system in human erythrocytes. Comparison of the effects of cytochalasin B, phloretin and maltose as competitive inhibitors.
    The Journal of physiology, 1978, Volume: 278

    Topics: Binding, Competitive; Biological Transport; Cytochalasin B; Depression, Chemical; Erythrocytes; Glucose; Hexoses; Humans; Kinetics; Maltose; Phloretin

1978
Selective labeling of the erythrocyte hexose carrier with a maleimide derivative of glucosamine: relationship of an exofacial sulfhydryl to carrier conformation and structure.
    Biochemistry, 1989, Feb-21, Volume: 28, Issue:4

    Topics: 3-O-Methylglucose; Binding, Competitive; Dithionitrobenzoic Acid; Erythrocyte Membrane; Glucosamine; Glycine; Humans; Kinetics; Maltose; Methylglucosides; Monosaccharide Transport Proteins; Peptide Fragments; Phloretin; Protein Conformation

1989
Reaction of an exofacial sulfhydryl group on the erythrocyte hexose carrier with an impermeant maleimide. Relevance to the mechanism of hexose transport.
    The Journal of biological chemistry, 1988, Sep-25, Volume: 263, Issue:27

    Topics: 3-O-Methylglucose; Affinity Labels; Binding, Competitive; Biological Transport; Cysteine; Cytochalasin B; Dithiothreitol; Drug Synergism; Erythrocytes; Humans; Maleimides; Maltose; Methylglucosides; Monosaccharide Transport Proteins; Phloretin; Photochemistry; Protein Conformation; Sulfhydryl Compounds

1988
Reaction of the glucose carrier of erythrocytes with sodium tetrathionate: evidence for inward-facing and outward-facing carrier conformations.
    The Journal of membrane biology, 1985, Volume: 84, Issue:1

    Topics: 4-Acetamido-4'-isothiocyanatostilbene-2,2'-disulfonic Acid; Androstenedione; Carrier Proteins; Erythrocytes; Humans; Maltose; Mathematics; Monosaccharide Transport Proteins; Phloretin; Protein Conformation; Sulfhydryl Reagents; Tetrathionic Acid; Thiosulfates; Time Factors

1985
Aspects of competitive inhibition.
    Biomembranes, 1972, Volume: 3

    Topics: Animals; Biological Transport; Copper; Disaccharides; Drug Synergism; Erythrocytes; Fluorine; Glucose; Glycerol; Guinea Pigs; Hemolysis; Humans; Maltose; Nitrobenzenes; Phloretin; Species Specificity; Structure-Activity Relationship

1972
The permeation of human red cells by 4,6-O-ethylidene- -D-glucopyranose (ethylidene glucose).
    The Journal of physiology, 1973, Volume: 231, Issue:1

    Topics: Animals; Carbon Isotopes; Cell Membrane Permeability; Diffusion; Erythrocytes; Glucose; Glycosides; Guinea Pigs; Hemolysis; Humans; Hydrogen-Ion Concentration; In Vitro Techniques; Maltose; Nitrobenzenes; Osmolar Concentration; Phloretin; Solubility; Temperature

1973
Evidence for a carrier conformational change associated with sugar transport in erythrocytes.
    Biochemistry, 1971, Mar-30, Volume: 10, Issue:7

    Topics: Binding Sites; Biological Transport, Active; Carbohydrate Metabolism; Cell Membrane Permeability; Depression, Chemical; Disaccharides; Drug Stability; Drug Synergism; Erythrocytes; Fluorine; Fructose; Galactose; Glucose; Guanidines; Hexoses; Humans; Kinetics; Light; Maltose; Mannose; Mathematics; Nitrobenzenes; Phloretin; Phlorhizin; Scattering, Radiation; Stimulation, Chemical; Urea; Urethane

1971
Glucose transport inhibitors protect against 1,2-cyclohexanedione-produced potassium loss from human red blood cells.
    Experimental physiology, 1998, Volume: 83, Issue:2

    Topics: Arginine; Blood Glucose; Cyclohexanones; Cytochalasin B; Erythrocytes; Furosemide; Glucose; Humans; In Vitro Techniques; Maltose; Monosaccharide Transport Proteins; Phloretin; Potassium

1998
Quench-flow analysis reveals multiple phases of GluT1-mediated sugar transport.
    Biochemistry, 2005, Feb-22, Volume: 44, Issue:7

    Topics: 3-O-Methylglucose; Binding Sites; Biological Transport, Active; Cytochalasin B; Erythrocyte Membrane; Extracellular Fluid; Glucose Transporter Type 1; Hemolysis; Humans; Hypotonic Solutions; Intracellular Fluid; Maltose; Models, Biological; Models, Chemical; Monosaccharide Transport Proteins; Phloretin; Temperature; Time Factors; Tritium

2005
alpha- and beta-monosaccharide transport in human erythrocytes.
    American journal of physiology. Cell physiology, 2009, Volume: 296, Issue:1

    Topics: 3-O-Methylglucose; Adenosine Triphosphate; Biological Transport; Carbohydrate Epimerases; Cell Shape; Cytochalasin B; Deoxyglucose; Erythrocytes; Glucose; Glucose Transporter Type 1; Humans; Kinetics; Maltose; Mannose; Models, Biological; Monosaccharides; Phloretin

2009
Phloretin suppresses carbohydrate-induced GLP-1 secretion via inhibiting short chain fatty acid release from gut microbiome.
    Biochemical and biophysical research communications, 2022, 09-17, Volume: 621

    Topics: Animals; Fatty Acids, Volatile; Gastric Inhibitory Polypeptide; Gastrointestinal Microbiome; Glucagon-Like Peptide 1; Glucose; Maltose; Mammals; Mice; Phloretin; Phlorhizin; Receptors, G-Protein-Coupled

2022