The effect of solvent dielectric constant on micellisation by lecithin

Solvent-assisted lipid self-assembly at hydrophilic surfaces: factors influencing the formation of supported membranes

As a simple and efficient technique, the solvent-assisted lipid bilayer (SALB) formation method offers a versatile approach to fabricating a planar lipid bilayer on solid supports. Corresponding mechanistic aspects and the role of various governing parameters remain, however, to be better understood. Herein, we first scrutinized the effect of lipid concentration (0.01 to 5 mg/mL) and solvent type (isopropanol, n-propanol, or ethanol) on SALB formation on silicon oxide in order to identify optimal conditions for this process. The obtained fluid-phase lipid layers on silicon oxide were investigated by using the quartz crystal microbalance with dissipation monitoring, epifluorescence microscopy, and atomic force microscopy. The experimental results indicate that, in alcohol, lipid attachment to the substrate is reversible and reaches equilibrium in accordance with the bulk lipid concentration. During the solvent-exchange step, the water fraction increases and the deposited lipids are converted into planar bilayer fragments, along with the concurrent adsorption and rupture of micelles within an optimal lipid concentration range. In addition, fluid-phase lipid bilayers were successfully formed on other substrates (e.g., chrome, indium tin oxide, and titanium oxide) that are largely intractable to conventional methods (e.g., vesicle fusion). Moreover, gel-phase lipid bilayers were fabricated as well. Depending on the phase state of the lipid bilayer during fabrication, the corresponding adlayer mass varied by approximately 20% between the fluid- and gel-phase states in a manner which is consistent with the molecular packing of lipids in the two arrangements. Taken together, our findings help to explain the mechanistic details of SALB formation, optimize the corresponding procedure, and demonstrate the general utility for fabricating gel- and fluid-phase planar lipid bilayers.

Peter Howard Elworthy (1933-1995): a biographical note

Peter Elworthy had a considerable influence on pharmaceutical science, education and practice, in the UK. He died in December 1995 at the early age of 62, but he had retired from full time academic work from his post as Professor of Pharmacy and Head of the Department of Pharmacy in the University of Manchester twelve years earlier. Concerned about his health but also not a little disillusioned by the multiple pressures placed even then on senior academics, he foresaw the era of cuts and the central oversight and restrictions. His heart was elsewhere. In his 1976 Harrison Memorial Lecture (reproduced in this issue) he said: "Looking back, I have the feeling of having been very lucky. 'Much have I travell'd in the realms of gold, and many goodly states and kingdoms seen.' My main interest has been in the phenomenon of micellization. The subject has been of absorbing interest, and continually shows new bright facets which lead to new scientific advances. Travelling in the realms of gold has nothing to do with gold, but to me it means travelling in sunlight, which illuminates things brightly, and makes visible new facts, which have been invisible before. Occasionally dark clouds form; they are the disappointments and frustrations, but we need them in order to be able to recognize the sunlight by contrast."

Phospholipids at the oil/water interface: adsorption and interfacial phenomena in an electric field

Interfacial effects produced in an immiscible liquid system by the action of an external electric field have been considered. The addition of small amounts of neutral phospholipids to the nonaqueous phase has been shown to result in a marked increase in the sensitivity of the interfacial boundary to the voltage applied, which is manifested by: (i) an accelerated decrease of the interfacial tension after the two immiscible liquid phases have been brought into contact; (ii) reduced interfacial tension, by 20-30 mN/m, at the oil/water interface at field strengths of 1-10 kV/m (the interfacial tension drop in the absence of phospholipids does not exceed 5 mN/m); (iii) development of electrohydrodynamic instability at the planar dividing surface between phases; and (iv) dispersion of water into the nonaqueous phase at smaller field strengths by a factor of about 100 as compared to those normally required in the absence of phospholipids. In order to gain a deeper insight into the mechanisms of interfacial phenomena, mainly exemplified by the n-heptane/water system containing phosphatidylcholine, three major issues have been considered: (1) Kinetics of the adsorption of phospholipid at the oil/water interface from the nonaqueous phase, and effects produced by exposure to an external electric field; also, the adsorption under equilibrium conditions, and the structure of the adsorption layer formed. (2) Interactions between neutral phospholipid and inorganic or organic ions at the interfacial boundary under the voltage applied. (3) Conditions for the occurrence of electrohydrodynamic instability at the dividing surface between oil and water and the formation of a water-in-oil emulsion; also aggregation and gelation processes induced in the nonaqueous phospholipid solution bulk by the action of a weak external electric field. Throughout the present paper, an attempt has been made to relate the microscopic behaviour of phospholipids under an external electric field to macroscopically observable properties at the movable interfacial boundaries. The adsorption studies have shown that phosphatidylcholine is prone to self-organization into a liquid-crystalline state at an immiscible liquid interface. The disintegration of the interfacial lipid film thus formed by the action of a weak electric field has been explained as due to an enhanced electrohydrodynamic instability of liquid crystals. This results in the formation of either an emulsion, or a microemulsion in the nonaqueous solution bulk. The formation of a microemulsion is manifested by the appearance of an optically anisotropic gel, stable only under an external applied electric field, in the nonaqueous solution bulk.(ABSTRACT TRUNCATED AT 400 WORDS)

Phospholipid-based reverse micelles

Physicochemical investigations on the aggregation of phospholipids (mainly phosphatidylcholines) in organic solvents are reviewed and compared with the aggregation behaviour of phospholipids in aqueous medium. In particular we review the data showing that phosphatidylcholines (lecithins) form reverse micellar structures in certain apolar solvents. In these systems not only low molecular weight compounds but also catalytically active enzymes and entire cells can be solubilized. In addition, highly viscous phosphatidylcholine gels can be obtained in organic solvents upon solubilizing a critical amount of water. Generally, phospholipid-based reverse micelles can be regarded as thermodynamically stable models for inverted micellar lipid structures possibly occurring in biological membranes.

Preparation and characterization of disodium fluorescein powders in association with lauric and capric acids

Hygroscopic growth of pharmaceutical aerosol powders is a factor governing their deposition, absorption, and pharmacologic effect in the respiratory tract. Surface association of hydrophobic molecules may reduce this effect. Disodium fluorescein was coated with the hydrophobic materials lauric and capric acids. The nature and extent of the association was investigated by a variety of techniques, with the notable use of X-ray photoelectron spectroscopy to examine the powder surface directly. It was concluded that the fatty acids associate at the phenol--sodium bond of the disodium fluorescein, and that the extent of the bulk interaction was governed by a fatty acid-, solute-, and concentration-dependent expanded surface area effect which resulted in much higher surface concentrations than might be expected by simple adsorption.

Solubilization of enzymes and nucleic acids in hydrocarbon micellar solutions

The present state of the field of biopolymers solubilized in apolar solvents via reverse micelles is reviewed. First, an extensive discussion of the physical and chemical properties of reverse micelles is presented. Particular attention is devoted to the nature of water in the water pools of reverse micelles; to the structure and shape of the micellar aggregates; and to the dynamic properties of the reverse micelles. In the second part of the paper, the mechanism of solubilization of proteins and nucleic acids in hydrocarbon reverse micelles is discussed. Spectroscopic data, mostly circular dichroism and fluorescence, are reviewed in order to clarify the conformational changes which the biopolymers undergo upon their uptake into the micellar environment and determine the location of the biopolymers inside the reverse micelles. Data from neutron scattering, light scattering, ultracentrifugation, and electron microscopy of the protein-containing micelles are reviewed and discussed with the aim of illustrating the structure of the micellar aggregates containing the biopolymer as guest molecules. The activity of enzymes and nucleic acids is discussed, with emphasis on the influence upon the chemical reactivity brought about by the micellar parameters. Finally, a brief review of the applications and potentialities of biopolymer-containing reverse micelles is presented.

The effect of osmotic pressure of aqueous PEG solutions on red blood cells

A drastic increase of the intracellular microviscosity of red blood cells in the presence of polyethylene glycol (PEG) was established by electron spin resonance using the small spin label molecule 2,2,6,6-tetramethyl-piperidine-N-oxyl-4-one (TEMPONE). The effective osmotic pressure of PEG solutions stressing the cells was estimated by comparison with those cytoplasmic rotational correlation times of TEMPONE measured in NaCl or sucrose containing media of known osmotic pressure.

The dielectric properties of aqueous solutions of poly(ethylene glycol) and their influence on membrane structure

The dielectric constant of water is reduced drastically on addition of poly(ethylene glycol). The behaviour is not described by a linear mixture equation. The decreased dielectric constant can lead to the general perturbation of the membrane structure which is necessary in such a manner that a strong aggregation of membranes would lead to their fusion. The changed cation permeability in the presence of poly(ethylene glycol) can explained as the effect of the lowered dielectric constant on the transfer energy.

Micelle formation of diacylglycerophosphocholines in organic solvents I. Effects of the solvents on Krafft points

Krafft points of diacylglycerophosphocholines (PC) were measured in alkanes-cyclohexane solutions by differential scanning calorimetry, and it was found that they were regularly increased following the increase in alkane content in the solutions and the chain length of the alkanes. From these results it was deduced that the mixing of PC with alkanes occurred in the gel state of the PC, but not in micelles at higher temperatures above the Krafft points, where micellar solutions are provided. The penetration of alkanes into gel state PC was found to be dominated by Langmuir type interaction, and the affinity of alkanes increases with increasing in chain lengths. Above the Krafft points, the micelle formation was confirmed by using the fluorescence probe technique.

Selective 31P(1H) nuclear Overhauser effect study on the polar headgroup conformation of phospholipids in micelles in organic solvents

The polar headgroup structure of phosphatidylcholine (PC), phosphatidylethanolamine (PE) and phosphatidylserine (PS) in inverted micelles in chloroform or benzene was investigated by the selective 31P(H) nuclear Overhauser effect (NOE). In the frequency dependence of the 31P(1H) NOE, PC micelles in CDCl3 showed two maxima. The larger maximum was located at the resonance of the glycerol-CH2OP protons and the smaller at the resonance of the N-methyl protons. In PC/PE mixed micelles in C6D6, both PC and PE showed three maxima which were located at the resonance of the CH2OP protons, the N-methyl protons and the amino protons in the frequency dependence of the 31P-NOE. The N-methyl protons of PC and the amino protons of PE were closely spaced to the phosphate groups of neighboring lipid molecules. The polar headgroups of PC and PE in the mixed micelles were concluded to lie in the plane perpendicular to the molecular axes. The frequency dependence of the 31P(H) NOE for PS micelles in C6D6 showed the maxima at the resonances of the amino protons and the CH2OP protons. The polar headgroups of PS molecules were not extended parallel to the molecular axes in the inverted micelles.

Dynamics of phospholipid aggregation in ethanol--water solutions

The kinetics of liposome and vesicle formation of a synthetic lecithin has been studied by light scattering techniques. It is shown, that by evaporation of alcohol from a lipid--alcohol--water mixture, the aggregates formed undergo several changes in shape. A hypothesis is presented, visualising the formation of liposomes or vesicles from monomers, which is consistent with the experimental observations.

Conformational difference in the polar groups of phosphatidylcholine and phosphatidylethanolamine in aqueous phase

Proton and phosphorus nuclear magnetic resonance was used to investigate conformations of o-phosphorylcholine(OPC), o-phosphorylethanolamine(OPE) and L-alpha-glycerophosphorylethanolamine in aqueous solution, and the conformations of dipalmitoyl-3-sn-phosphatidylcholine and phosphatidylethanolamine from E. coli in methanol and chloroform solutions. It has been shown that in every case the O-C-C-N system prefers a gauche conformations, but in the choline moiety the dihedral angle around the C-C bond is distorted from the usual gauche angle, 60 degrees, to a larger one. The dihedral angle of OPC is shown to be more variable than that of OPE. This may be due to the curvature of its potential curve, i.e. asymmetrical curvature around the gauche minima. This property of the phosphatidylcholine molecule may be partly responsible for the flexibility of the phosphatidylcholine bilayer. The coupling is dominant in the P-O-C-C systems of the 5 compounds examined. The results also indicated that the two hydrocarbon chains in phosphatidylcholine or phosphatidylethanolamine are apt to take nearly parallel orientation in methanol solution. This characteristic is favourable for the formation of the bilayer structure.

Interaction of water with egg lecithin in benzene solution

Benzene solutions of purified egg lecithin, with small amounts of water added, have been examined by 60 MGz and 100 MHz NMR spectroscopy, infrared spectrophotometry and phase contrast microscopy. The transverse relaxation times of the water, N-methyl and O--H protons are dependent on water concentration. This dependence changes sharply for the water proton at a level of one water molecule per lecithin monohydrate molecule. These results do not fully agree with those reported by other workers. Four mathematical models are examined which could account for the behaviour of the water protons. Models which assume a constant transverse relaxation time for water protons above a level of one water molecule per lecithin molecule cannot predict the behaviour observed. It is sufficient to assume that water protons above this concentration have a single relaxation time which is a linear function of water concentration. The added water associates primarily with the phosphate in the lecithin head group. Above nine water molecules per lecithin monohydrate molecule free water is present in the system.