Deuteration of water enables self-organization of phospholipid-based reverse micelles.

Phospholipid-based reverse micelles are composed of branched cylinders. Their branching points are known to attract themselves and to slide along branches. The rate of this sliding is governed by the lifetime of H(D)-bonded water bridges between phospholipid molecules.

Water isotope effect on the phosphatidylcholine bilayer properties: a molecular dynamics simulation study.

Physicochemical properties of heavy water (D2O) differ to some extent from those of normal water. Substituting D2O for H2O has been shown to affect the structural and dynamic properties of proteins, but studies of its effects on lipid bilayers are scarce. In this paper, the atomic level molecular dynamics (MD) simulation method was used to determine the effects of this substitution on the properties of a dipalmitoylphosphatidylcholine (DPPC) bilayer and its hydrating water.

Different properties of H2O- and D2O-containing phospholipid-based reverse micelles near a critical temperature.

Dipalmitoylphosphatidylcholine (DPPC)/water/pyridine reverse micelles have been found to transform from a clear liquid into a glass when the DPPC-to-water volume fraction is in the 0.78-0.89 range at 28 or 26 degrees C depending on whether water is H2O or D2O.

New insights into water-phospholipid model membrane interactions.

Modulating the relative humidity (RH) of the ambient gas phase of a phospholipid/water sample for modifying the activity of phospholipid-sorbed water [humidity-controlled osmotic stress methods, J. Chem. Phys.

Two QTLs located on chromosomes 1 and 5 modulate different aspects of the performance of mice of the B x D Ty RI strain series in the Morris navigation task.

The Morris navigation task is widely used to study spatial abilities in rodents; namely, to analyze the effects of mutations in genetically engineered mice. Although quantitative and Mendelian genetic studies have shown that the variation of these abilities is partly under genetic control, little is known about these genetic factors. In order to analyze the genetic architecture of spatial navigation in mice, a wide genome scan was performed to map the QTLs that control various aspects of the performance, using the RI strain methodology.