The use of differential scanning calorimetry and differential thermal analysis in studies of model and biological membranes.
about
Tracking molecular interactions in membranes by simultaneous ATR-FTIR-AFMNanoscopic substructures of raft-mimetic liquid-ordered membrane domains revealed by high-speed single-particle tracking.Chemical properties of lipids strongly affect the kinetics of the membrane-induced aggregation of α-synucleinTwo-photon fluorescence microscopy observation of shape changes at the phase transition in phospholipid giant unilamellar vesicles.Bilayer structure and physical dynamics of the cytochrome b5 dimyristoylphosphatidylcholine interactionLipid bilayer surface association of lung surfactant protein SP-B, amphipathic segment detected by flow immunofluorescence.Interaction of a peptide model of a hydrophobic transmembrane alpha-helical segment of a membrane protein with phosphatidylethanolamine bilayers: differential scanning calorimetric and Fourier transform infrared spectroscopic studiesDimyristoylphosphatidylcholine/C16:0-ceramide binary liposomes studied by differential scanning calorimetry and wide- and small-angle x-ray scattering.Differential dynamic and structural behavior of lipid-cholesterol domains in model membranes.Probing protein sequences as sources for encrypted antimicrobial peptidesEffect of lanthanum ions on the phase transitions of lecithin bilayersMulticomponent phase transitions of diacylphosphatidylethanolamine dispersions.Differential scanning calorimetry: An invaluable tool for a detailed thermodynamic characterization of macromolecules and their interactionsThe use of exogenous fluorescent probes for temperature measurements in single living cells.Proteoliposomes with the ability to transport Ca(2+) into the vesicles and hydrolyze phosphosubstrates on their surface.Theory of protein-induced lateral phase separation in lipid membranes.Comparative calorimetric and spectroscopic studies of the effects of lanosterol and cholesterol on the thermotropic phase behavior and organization of dipalmitoylphosphatidylcholine bilayer membranes.Killing of melanoma cells and their metastases by human lactoferricin derivatives requires interaction with the cancer marker phosphatidylserineFormulation and characterization of boanmycin-loaded liposomes prepared by pH gradient experimental design.Conformation of a bactericidal domain of puroindoline a: structure and mechanism of action of a 13-residue antimicrobial peptide.A calorimetric study of binary mixtures of dihydrosphingomyelin and sterols, sphingomyelin, or phosphatidylcholine.Thermodynamics and membrane processes.Reconstitution of the glycosylphosphatidylinositol-anchored protein Thy-1: interaction with membrane phospholipids and galactosylceramide.Adaptational changes of fatty acid composition and the physical state of membrane lipids following the change of growth temperature in Yersinia enterocolitica.Apolipophorin III interaction with model membranes composed of phosphatidylcholine and sphingomyelin using differential scanning calorimetry.Encrypted Antimicrobial Peptides from Plant Proteins.Phase transition behavior of single phosphatidylcholine bilayers on a solid spherical support studied by DSC, NMR and FT-IRCelecoxib-loaded liposomes: effect of cholesterol on encapsulation and in vitro release characteristics.Concentration-dependent differing actions of the nonsteroidal anti-inflammatory drug, celecoxib, in distearoyl phosphatidylcholine multilamellar vesicles.Lipid-packing perturbation of model membranes by pH-responsive antimicrobial peptides.Thermodynamics of lipid multi-lamellar vesicles in presence of sterols at high hydrostatic pressure.Effect of divalent cations on the structure of dipalmitoylphosphatidylcholine and phosphatidylcholine/phosphatidylglycerol bilayers: an 2H-NMR study.Structural aspects of the interaction of peptidyl-glycylleucine-carboxyamide, a highly potent antimicrobial peptide from frog skin, with lipids.The damage to phospholipids caused by free radical attack on glycerol and sphingosine backbone.Lipid phase behavior studied with a quartz crystal microbalance: A technique for biophysical studies with applications in screening.Studies on osmotic stability of liposomes prepared with bacterial membrane lipids by carboxyfluorescein release.Lyophilization of Liposomal Formulations: Still Necessary, Still ChallengingEffect of polyethylene glycol-2000 on amino acid surfactant-based vesiclesPhase Transitions of Binary Lipid Mixtures: A Combined Study by Adiabatic Scanning Calorimetry and Quartz Crystal Microbalance with Dissipation MonitoringEthanol-induced changes in the fatty acid composition ofLactobacillus hilgardii, its effects on plasma membrane fluidity and relationship with ethanol tolerance
P2860
Q24652246-736E333F-A7BD-4719-8C2C-89329A9A858BQ27350332-1C2CEA08-B38F-4286-BB7C-266A2DF0649DQ28831283-DF0CD49E-E685-4164-B2B0-C88E6A8EBD4DQ30786868-2C02DB30-5E4C-481F-A3C1-F532131BBD86Q34088709-13C91EC2-185C-450F-8802-9B6145EB321EQ34091756-016741FD-32DA-42E0-89FA-99201CD1900FQ34128648-565501B7-0CB5-49D9-9027-56B52F184EF3Q34173038-CC350D9E-162F-4798-B65A-3F880AB2A793Q34328817-AD07230F-E4F4-4475-895E-557BF0A4830DQ34430210-6608A1BE-C4F3-4DF1-84DC-38F71561809FQ34534596-D889B75D-2343-4D72-B575-BB23EE9AF465Q34535044-B994702C-FE2B-47DA-B3E3-6B79245D520EQ34648464-E44C0CB1-508C-487E-AB7D-609AD18DF0DAQ36792023-C4D788A4-51E6-4AE8-8CE4-7144380E03CDQ37600840-DA436670-8560-432D-9627-23A465EC9C49Q38197812-BB0A8F6F-8EC2-4CDC-A1EA-B33B7BA0E17AQ38719385-58874C52-B601-474F-A6CE-EC2A41F4EEBDQ38994009-45720369-E0D0-4DFA-A4FD-1770C42BC984Q39405268-C50CC9F3-1FA0-4162-AC76-AFF779E3DC5AQ39793865-927B478B-6E21-466F-840B-A26B3E37FC47Q40235875-370F205A-4DC1-48F9-9E79-7F42CC9245DCQ40253402-176EAA25-50C3-4AEC-AF01-07E2D5C344D2Q40925805-7E2AA860-779E-4DF6-8972-685718EB0776Q41510212-7E819CBA-61E0-48F4-865E-BF0CBFB9269CQ41764867-5D87E569-74AF-411A-AE9A-395492A4C544Q42378943-55D823D1-D317-480C-B2C7-F5B9DEFD8CBCQ42582995-B98E4693-8FC1-4BCF-A7B3-3600E5E9DE3FQ43245633-4FF57C6B-0AD6-420F-8C25-29D6DA305CB9Q43256754-8D077CA6-4597-4D4A-8327-1A3C3D6549F3Q44385177-5C1ADB49-E54E-4B31-8353-2A760053BE57Q45422577-71F9E940-2076-4805-8EF9-54CEA9E2574DQ46116360-C3EEF0D6-DEB9-4281-9FF6-5D448B253E9FQ46972340-94286BF3-1229-472B-B4E4-3AB2288BABC7Q48712747-5CC327B7-B6C5-40AF-81FD-6F5C0C9DBD13Q50269377-28744A19-2BFC-475F-9ECD-A27B036209AAQ54278440-B768D0A3-4F20-4904-A0DF-96B4A2D3E878Q57091280-7B96BBD3-EC63-46CA-888E-93A15BF14177Q57347306-5EDD0888-FE6C-4D43-9B32-30AE58261211Q58832589-016B760A-5922-44D8-8B66-6F22C1FACA49Q58903856-EEDA0E42-31F6-40C2-A278-215A469ACEA6
P2860
The use of differential scanning calorimetry and differential thermal analysis in studies of model and biological membranes.
description
1982 nî lūn-bûn
@nan
1982年の論文
@ja
1982年論文
@yue
1982年論文
@zh-hant
1982年論文
@zh-hk
1982年論文
@zh-mo
1982年論文
@zh-tw
1982年论文
@wuu
1982年论文
@zh
1982年论文
@zh-cn
name
The use of differential scanni ...... odel and biological membranes.
@en
type
label
The use of differential scanni ...... odel and biological membranes.
@en
prefLabel
The use of differential scanni ...... odel and biological membranes.
@en
P1476
The use of differential scanni ...... odel and biological membranes.
@en
P2093
R N McElhaney
P304
P356
10.1016/0009-3084(82)90053-6
P577
1982-05-01T00:00:00Z