silicon and 1-2-distearoyllecithin

Lipid translocation in membranes is still far from being understood and well characterized for natural cell membranes as well as for simpler bilayer model systems. Several discrepancies with respect to its occurrence and its characteristic time scale are present in the literature. In the current work, the structural changes induced by lipid rearrangement in a distearoyl-/dimyristoyl-phosphocholine binary lipid system have been addressed by means of neutron reflectivity. It has been shown that a fast, spontaneous compositional reorganization with lipid transfer between the two leaflets of the bilayer takes place only when the lipid species are both in the fluid phase. This process has been identified as the so-called lipid flip-flop. Moreover, the influence of the preparation protocol on the structural properties of the system has been investigated.

Topics: Dimyristoylphosphatidylcholine; Kinetics; Lipid Bilayers; Neutron Diffraction; Phosphatidylcholines; Scattering, Small Angle; Silicon; Surface Properties; Temperature

Lipid bilayers exhibit structural diversity that contributes to the complex properties of the cell membrane. We use interfacial force microscopy to correlate mechanical properties with the two-dimensional phase behavior of supported lipid bilayers (SLBs). Upon indentation by a 500 nm tungsten tip, a contrast in the mechanical response is observed for gel vs fluid phase SLBs. We measure the yield force and time scale for recovery for these films. Consistent with a gel phase, a DSPC SLB has a relatively high yield force and slow recovery. In the higher mobility fluid phase, a DLPC SLB has a lower yield force and completely recovers within the experimental time scale. Friction measurements offer further contrast between the two SLBs.

Topics: Elasticity; Friction; Gels; Lipid Bilayers; Phase Transition; Phosphatidylcholines; Silicon; Surface Properties

Neutron reflectivity was used to probe the structure of single phosphatidylcholine (PC) lipid bilayers adsorbed onto a planar silicon surface in an aqueous environment. Fluctuations in the neutron scattering length density profiles perpendicular to the silicon/water interface were determined for different lipids as a function of the hydrocarbon chain length. The lipids were studied in both the gel and liquid crystalline phases by monitoring changes in the specularly-reflected neutron intensity as a function of temperature. Contrast variation of the neutron scattering length density was applied to both the lipid and the solvent. Scattering length density profiles were determined using both model-independent and model-dependent fitting methods. During the reflectivity measurements, a novel experimental set-up was implemented to decrease the incoherent background scattering due to the solvent. Thus, the reflectivity was measured to Q approximately 0.3 A-1, covering up to seven orders of magnitude in reflected intensity, for PC bilayers in D2O and silicon-matched (38% D2O/62% H2O) water. The kinetics of lipid adsorption at the silicon/water interface were also explored by observing changes in the reflectivity at low Q values under silicon-matched water conditions.

Topics: 1,2-Dipalmitoylphosphatidylcholine; Deuterium Oxide; Lipid Bilayers; Molecular Conformation; Molecular Structure; Neutrons; Phosphatidylcholines; Scattering, Radiation; Silicon; Water