about
Trace membrane additives affect lipid phases with distinct mechanisms: a modified Ising model.Macroscopic phase separation, modulated phases, and microemulsions: a unified picture of raftsCalculating partition coefficients of chain anchors in liquid-ordered and liquid-disordered phasesCombined effect of cortical cytoskeleton and transmembrane proteins on domain formation in biomembranes.Modulation of a small two-domain lipid vesicle by linactants.Line tension and stability of domains in cell-adhesion zones mediated by long and short receptor-ligand complexesCorrelation functions quantify super-resolution images and estimate apparent clustering due to over-countingPartitioning of lipids at domain boundaries in model membranes.Minimal model of plasma membrane heterogeneity requires coupling cortical actin to criticality.Relating domain size distribution to line tension and molecular dipole density in model cytoplasmic myelin lipid monolayers.Membrane organization and lipid rafts.Lipid-protein interactions alter line tensions and domain size distributions in lung surfactant monolayersPhysical properties of the hybrid lipid POPC on micrometer-sized domains in mixed lipid membranes.Tuning membrane phase separation using nonlipid amphiphiles.Seeing the Forest in Lieu of the Trees: Continuum Simulations of Cell Membranes at Large Length ScalesFormation and domain partitioning of H-ras peptide nanoclusters: effects of peptide concentration and lipid composition.Monolayer curvature stabilizes nanoscale raft domains in mixed lipid bilayersModel of a raft in both leaves of an asymmetric lipid bilayerPhase separation in biological membranes: integration of theory and experimentCrystalline lipid domains: characterization by X-ray diffraction and their relation to biology.Colloids in Flatland: a perspective on 2D phase-separated systems, characterisation methods, and lineactant design.Liquid general anesthetics lower critical temperatures in plasma membrane vesicles.Searching for line active molecules on biphasic lipid monolayers.The many faces of lipid raftsLine active hybrid lipids determine domain size in phase separation of saturated and unsaturated lipids.Registered and antiregistered phase separation of mixed amphiphilic bilayers.Thermal fluctuations of vesicles and nonlinear curvature elasticity--implications for size-dependent renormalized bending rigidity and vesicle size distribution.Thermal Stability of Phase-Separated Domains in Multicomponent Lipid Membranes with Local Anesthetics.Spontaneous formation of two-dimensional and three-dimensional cholesterol crystals in single hydrated lipid bilayers.Effect of integral proteins in the phase stability of a lipid bilayer: application to raft formation in cell membranes.Geodesic curvature driven surface microdomain formation.Composition Fluctuations in Lipid Bilayers.Critical Casimir forces in cellular membranes.2D lattice model of a lipid bilayer: Microscopic derivation and thermodynamic exploration.Budding of domains in mixed bilayer membranes.Formation of modulated phases and domain rigidification in fatty acid-containing lipid membranes.Hybrid lipids increase nanoscale fluctuation lifetimes in mixed membranes.
P2860
Q30644838-9A5DC954-84BF-40CC-86F1-C5505F759D94Q33595742-FF1E1EAB-B925-46A6-B0CE-3F06E5F6987EQ33820957-447B91FF-F0B5-48D0-B23B-F453D034DD03Q33990509-E35906E3-D086-4A85-9233-DBE712540AC9Q33998785-65703A16-6664-4CAE-9F8A-3CFBFF3050A3Q33999382-E10D27B0-9E92-4DF4-BAAC-A5799A0BFB6EQ34181716-093EB3C2-5D30-4D2F-B6E2-E7EBB897A490Q34398505-A84D9C5C-3FD7-405F-8752-6668F82E5B2BQ34772230-38199274-D240-4888-9BFA-8AC981A1AD6BQ35035218-1A73BA16-1F89-4E3D-9739-1AD32AC758DFQ35230032-0BBA728B-07D2-43B2-BC51-1DAC96426B42Q35649508-2E81ECAF-D08C-4848-BE49-438F253C9662Q35715929-0BD7EBE5-D7C2-4B2B-8939-A7DAB6CA0EBAQ35743337-7FEA5D49-22C4-4949-810C-30F2BAB4D5BDQ36052390-EAE84AB8-2052-4240-89E4-F5FD52AAF3D2Q36341440-C20DD919-9453-4D74-8229-4CECA7008DBBQ36712514-75793964-B97F-4942-A40C-8667D1F061E7Q37204371-AE5D891A-8AF7-4766-89B1-56A1D664716BQ37700666-1EBB57C0-C952-48EF-88B7-371F6CC0AB57Q37862668-3A5737B7-F2DC-442A-B738-3C4D01835EDEQ38068086-60733328-48A6-4169-A790-1AECDD586886Q39041422-876830E9-0384-48F1-BDC8-BD3B0C0F772BQ39046084-9D922636-EF28-4E82-8745-8B493A06D275Q39483616-8F248FEB-04B8-4EFB-9E6D-09C41D48A417Q39887342-63232915-4A6C-4A54-A2A0-987B3A367A72Q39893498-E016B7C4-85D8-4F44-B1A2-67D37DD66176Q40135408-734F6FBA-0034-4BC6-A966-466747A2743EQ41666668-997DFC4E-D769-41FE-B075-EB4E301A55EFQ41785863-1D16EFE1-7035-4FFE-A845-E98BECA9B959Q43101400-03D41073-FEE2-4582-B5CE-C6EA28045D11Q46321668-36A3D095-DC75-4307-A360-99BA7FF68496Q47270580-9D1B9FCC-4F3B-407F-990E-EAE672A3E229Q50285064-B66A7012-C55A-45B1-907C-8A7B00DF3CB5Q50891803-7C32A3D6-A635-4E98-8E03-3ACA142DE1B9Q53314248-A102DD96-2514-4196-856A-D0B12F1DA5D5Q53612860-2645F81E-1777-4768-9128-B47D55148DB0Q54763060-2D605A93-C679-4EF1-B568-299E6E9DD2AB
P2860
description
2009 nî lūn-bûn
@nan
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
2009年论文
@zh
2009年论文
@zh-cn
name
Hybrid lipids as a biological surface-active component.
@en
type
label
Hybrid lipids as a biological surface-active component.
@en
prefLabel
Hybrid lipids as a biological surface-active component.
@en
P2093
P2860
P1433
P1476
Hybrid lipids as a biological surface-active component.
@en
P2093
P A Pincus
R Brewster
S A Safran
P2860
P304
P356
10.1016/J.BPJ.2009.05.051
P407
P577
2009-08-01T00:00:00Z