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Literature DB >> 7104437

Thickness fluctuations in black lipid membranes.

Abstract

Because a black lipid membrane is compressible, there will be spontaneous fluctuations in its thickness. Qualitative arguments are given that the preferred configuration of the membranes is flat and that thickness fluctuations are smaller in amplitude than the differences in mean thickness observed using different hydrocarbon solvents. Fluctuations with short characteristic lengths will not be large as a result of the large amounts of oil-water contact these would entail. Quantitative analysis based on an extension of the treatment for soap films, predicts that the root mean square (rms) amplitude for fluctuations of wavelength longer than approximately 10 nm is negligible for glyceryl monooleate membranes with squalene (less than 3%) but may be approximately 20% with n-decane. rms fluctuations of 20% would lead to a discrepancy between the rms thickness of the core and the mean reciprocal thickness of only 6%.

Entities: Chemical

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Year: 1982 PMID： 7104437 PMCID： PMC1328866 DOI： 10.1016/S0006-3495(82)84556-6

Source DB: PubMed Journal: Biophys J ISSN： 0006-3495 Impact factor: 4.033

13 in total

1. Letter: Lenses and the compression of black lipid membranes by an electric field.

Authors:
Journal: Biophys J Date: 1975-01 Impact factor: 4.033

2. Electrical capacity of black lipid films and of lipid bilayers made from monolayers.

Authors: R Benz; O Fröhlich; P Läuger; M Montal
Journal: Biochim Biophys Acta Date: 1975-07-03

3. Studies of the physical chemistry of planar bilayer membranes using high-precision measurements of specific capacitance.

Authors: S H White
Journal: Ann N Y Acad Sci Date: 1977-12-30 Impact factor: 5.691

Thickness fluctuations in black lipid membranes.

1. Letter: Lenses and the compression of black lipid membranes by an electric field.

2. Electrical capacity of black lipid films and of lipid bilayers made from monolayers.

3. Studies of the physical chemistry of planar bilayer membranes using high-precision measurements of specific capacitance.

4. Chain ordering in liquid crystals. II. Structure of bilayer membranes.

5. Optical properties of black lecithin films.

6. A statistical mechanical model of the lipid bilayer above its phase transition.

7. The interaction of n-octanol with black lipid bilayer membranes.

8. Formation of "solvent-free" black lipid bilayer membranes from glyceryl monooleate dispersed in squalene.

9. Phase transitions and heterogeneity in lipid bilayers.

10. A mean-field model of the alkane-saturated lipid bilayer above its phase transition. I. Development of the model.

1. Inclusion-induced bilayer deformations: effects of monolayer equilibrium curvature.

2. Nonlinearities in tilt and layer displacements of planar lipid bilayers.

3. Open channel noise. V. Fluctuating barriers to ion entry in gramicidin A channels.

4. Calculation of deformation energies and conformations in lipid membranes containing gramicidin channels.

5. Viscoelastic relaxation of bilayer lipid membranes: II. Temperature dependence of relaxation time.

6. Deformation free energy of bilayer membrane and its effect on gramicidin channel lifetime.

7. Energetics of inclusion-induced bilayer deformations.

8. Tuning membrane thickness fluctuations in model lipid bilayers.

9. Viscoelastic relaxation of bilayer lipid membranes. Frequency-dependent tension and membrane viscosity.

10. A molecular model for lipid-protein interaction in membranes: the role of hydrophobic mismatch.