Distribution of local anesthetics in lipid membranes

Absorption of local anesthetics into lipid membranes and adsorption onto their surfaces were studied as a function of the pH of aqueous bulk solutions by measuring lipid vesicle electrophoretic mobility, the partition of the anesthetics between the aqueous and membrane phases by the use of fluorescence and radioactive tracer methods, and the effect of the anesthetics on interfacial tension of lipid monolayers formed at the oil/aqueous interface.

At a pH much lower than the pK_a value of the local anesthetic, the charged form of the local anesthetic was only adsorbed onto the membrane surface, as determined from vesicle electrophoretic mobility, radioisotope tracer and the monolayer surface tension studies. Surface partition coefficients of the charged form of the local anesthetics on phosphatidylcholine and phosphatidylserine membranes were obtained from the data of electrophoretic mobilities for lipid vesicles. The surface partition coefficients of various local anesthetics paralleled those of the bulk partition coefficients.

As the pH of the solutions increased, the adsorbed amount of the charged form of the anesthetic at the membrane interface decreased, while the absorption of the uncharged form of the local anesthetic into the membrane increased. The total amount of local anesthetic adsorbed per unit area of the membrane generally increased as the pH of the solution increased. This was also observed from the measurements of the fluorescence of local anesthetics adsorbed into the membranes. At lower pH than that corresponding to the pK_a value of the local anesthetic, the amount of anesthetic adsorbed depended greatly upon the membrane surface charge. At a higher pH than its pK_a, it did not depend appreciably on the surface charge density of the membrane but did depend on the bulk partition coefficients between the aqueous and oil phases.     

Electronic processes and photosensitization in bilayer lipid membranes

Abstract— In part one of this paper, evidence for electronic processes in experimental and biological membranes are reviewed. The membrane under consideration, be it experimental or biological, is understood to mean an ultrathin bamer separating two aqueous phases. The question ‘can electronic processes occur in/across such a structure immersed in an aqueous environment?’ is answered affirmatively. In the second part of this paper, photosensitization by dyes and photoelectric effects in experimental bilayer lipid membranes observed recently are described.     

Large influence of cholesterol on solute partitioning into lipid membranes

Cholesterol plays an important role in maintaining the correct fluidity and rigidity of the plasma membrane of all animal cells, and hence, it is present in concentrations ranging from 20 to 50 mol %. Whereas the effect of cholesterol on such mechanical properties has been studied exhaustively over the last decades, the structural basis for cholesterol effects on membrane permeability is still unclear. Here we apply systematic molecular dynamics simulations to study the partitioning of solutes between water and membranes. We derive potentials of mean force for six different solutes permeating across 20 different lipid membranes containing one out of four types of phospholipids plus a cholesterol content varying from 0 to 50 mol %. Surprisingly, cholesterol decreases solute partitioning into the lipid tail region of the membranes much more strongly than expected from experiments on macroscopic membranes, suggesting that a laterally inhomogeneous cholesterol concentration and permeability may be required to explain experimental findings. The simulations indicate that the cost of breaking van der Waals interactions between the lipid tails of cholesterol-containing membranes account for the reduced partitioning rather than the surface area per phospholipid, which has been frequently suggested as a determinant for solute partitioning. The simulations further show that the partitioning is more sensitive to cholesterol (i) for larger solutes, (ii) in membranes with saturated as compared to membranes with unsaturated lipid tails, and (iii) in membranes with smaller lipid head groups.     

Local anesthetics facilitate ion transport across lipid planar bilayer membranes under an electric field: dependence on type of lipid bilayer

In order to elucidate the role of structural change of lipid membrane bilayer in the mode of action of local anesthetic, we studied the effects of local anesthetics, charged tetracaine and uncharged benzocaine, on ion permeability across various lipid planar bilayers (PC, mixed PC/PS (4/1, mol/mol); mixed PC/PE (1/1, mol/mol); mixed PC/SM (4/1, mol/mol)) under a constant applied voltage. The membrane conductances increased in the order of PC  PC/PS ≤ PC/SM  PC/PE. When the constant voltage of −100 or −70 mV was applied through the lipid bilayer membranes in the presence of positively charged tetracaine, the fluctuating current pulses with the large amplitude generated, but not appeared in the absence of tetracaine. The addition of uncharged benzocaine generated the fluctuating currents with the small amplitude. Both charged tetracaine and uncharged benzocaine facilitated electrophoretically the transport of small ions such as KCl in the buffer solution through the fluctuating pores in the lipid bilayer membranes formed by interaction with the local anesthetic under the negative applied membrane potential. The current pulses also contained actual transport of charged tetracaine together with the transport of the small ions. The amplitude and the duration time of the electrical current generated by adding the local anesthetics were dependent on the type of the lipid, the applied voltage and its voltage polarity.     

Transport processes in responding lipid membranes: a possible mechanism for the pH gradient in the stratum corneum

The "acidic mantle" of the skin surface has been related to several essential functions of the skin, although the origin of the acidity is still obscure. In this paper, we investigate how different transport processes can influence the local proton concentration inside a membrane consisting of oriented lipid bilayers. This system is chosen as a simple model of the extracellular lipids in the upper layer of the skin, the stratum corneum. We present a theoretical model for diffusional transport over the membrane in the presence of an osmotic gradient and a gradient in CO(2), taking into account the influence of these gradients on the lipid structure and the local electrostatics. We are also discussing the complications in applying the concept of pH to the stratum corneum. From this, we make the following conclusions: (i) The definition of pH in the stratum corneum is ambiguous, and thus, all statements regarding pH should always be related to a clear definition. (ii) A natural definition of pH in the stratum corneum can be proposed which takes into account local heterogeneity, local charges, and the fact that the stratum corneum is not in thermodynamical equilibrium. (iii) Diffusive transport across an oriented bilayer stack in the presence of an osmotic gradient and/or a gradient in CO(2) can give rise to a substantial gradient in pH. (iv) The results from the simplified model can be correlated to experimental observations of pH in the stratum corneum.     

Domains and rafts in lipid membranes

"It takes a membrane to make sense out of disorder in biology. You have to be able to catch energy and hold it, storing precisely the needed amount and releasing it in measured shares". So wrote Lewis Thomas in The Lives of Cells. Domains and rafts are shown in the present Review to play an important role in this amazing behavior of lipid membranes. Topics touched upon include the experimental detection of domains, their composition, domain induction, properties of rafts (a special form of domain), and the relationship of rafts to human diseases. Lipids, polymers, and proteins can contribute to this type of micro- and nanostructuring within membranes, thus imposing a new structural hierarchy on top of the classical bilayer membrane. The purpose of this Review is to develop an appreciation for the multiple organizational levels in self-assembling systems.     

Composition fluctuations, chemical exchange, and nuclear relaxation in membranes containing cholesterol

A thermodynamic model of cholesterol-phospholipid complexes is used as a starting point for calculating fluctuations in membranes containing cholesterol and phospholipids. The calculations describe fluctuations in the concentration of complexes formed between cholesterol and phospholipids with longer saturated fatty acid chains. The fluctuations in complex concentrations arise by two distinct mechanisms. In one, the chemical composition of the sample varies from point to point, and the concentration of the complexes varies according to local chemical equilibrium. In the second, the composition remains fixed, and the complexes form and dissociate according to chemical reaction kinetics. In both cases the nuclear resonance frequency of a deuterium labeled phospholipid undergoes fluctuations and line broadening as a consequence of the formation and dissociation of complexes. For a specific ternary lipid mixture at its critical composition, deuterium nuclear resonance line broadening of chain labeled phospholipids is calculated for temperatures up to 10 degrees -20 degrees above the miscibility critical temperature. This line broadening is associated with fluctuations in the degree of phospholipid chain ordering related to the formation and dissociation of complexes.     

Nonuniform lipid distribution in membranes

The noniform lateral and transbilayer lipid arrangement existing in two-component lipid bilayers are reviewed.

The lateral lipid organization is considered on the basis of the temperature-composition phase diagrams of the lipid binaries. A comparative analysis of the phase diagrams of synthetic phospholipid mixtures is carried out. The various types of the phase diagrams observed are set in a continuous row determined by the increase of the lipid lateral immiscibility. A special emphasis is laid on the appearance of peculiar points in the phase diagrams--triple, critical, and isoconcentration points. Two basic statistical-mechanical methods for simulation of phase diagrams--Bragg-Williams (regular solutions, mean field) and quasichemical--are compared. Stability criteria indicating the regions of lateral phase separation are also given. The main advantage of the quasichemical method is that it also allows the short-range order in the lipid arrangement to be determined.

The physical interactions contributing to an equilibrium lipid asymmetry in mixed lipid bilayers are pointed out. The most important among them are: (i) electrostatic forces induced by differences in the membrane electric double layers; (ii) nonideal lateral mixing of the lipids; (iii) packing restrictions important in curved bilayers.

A unified electrostatic model is presented to calculate the surface charge asymmetry created by any factors affecting the electric double layers of the bilayer (external electric potential, overlapping electric double layers in parallel membranes or in vescicles, etc.).

The transmembrane asymmetry strongly depends on the degree of c corrections may increase up two-three times the asymmetry induced by factors of the order of 1–3 kT. A typical nonideality effect, which may be used in an experimental verification, is the appearance of an extremum in the dependence of the asymmetry on the mole fraction of the components.

As previously shown in other reviews on membrane organization, the packing restrictions are of importance in highly curved bilayers, e.g., in small unilamellar vesicles.

The experimental data on the asymmetry of two-component small unilamellar vesicles are summarized and some general conclusions are formulated.

With a view toward the native membranes, some inferences are drawn about (i) the state of thermodynamic equilibrium and (ii) the lipid organization in multicomponent membranes.     

Cooperative domains in lipid membranes

Journal of Thermal Analysis and Calorimetry - Phase transitions of multibilayer structures of hydrated L-α-dipalmitoyl- and L-α-dimyristoylphosphatidylcholine (DPPC and DMPC) were studied...     

Dielectric relaxation processes in PVDF composite

The present study aims at the detailed elaboration of the dielectric relaxation behavior in PVDF composites using broadband dielectric spectroscopy and the Havriliak – Negami method. The composites with multi-wall nanotube carbon and zirconium dioxide in PVDF is fabricated using a simple melt mixing method. The polarization behavior in PVDF composites are investigated on the different frequency region with various temperature. The complex dielectric constants are calculated with the aid of the Havriliak – Negami equation. The characteristic parameters in Havriliak – Negami equation were in excellent agreement with the experimental complex dielectric constants. The results of utilizing these calculated parameters to analyze the origination of the polarization relaxation are given. The purposes of this work expect to give a deeper insight into the impact of different fillers on the dielectric relaxation behavior, and it could provide the technique for the discrepancy with the dipolar for interfacial polarization and the filler effect on the dielectric relaxation.     

The influence of zwitterionic lipids on the electrostatic adsorption of macroions onto mixed lipid membranes

Charged lipid membranes commonly consist of a mixture of charged and zwitterionic lipids. We suggest a model that characterizes the influence of the dipolar nature of the zwitterionic lipid species on the electrostatic adsorption of macroions onto mixed membranes in the fluid state. The model is based on Poisson-Boltzmann theory which we have modified so as to account for the dipolar character of the zwitterionic lipids. In addition the membrane lipids are allowed to adjust their lateral distribution upon macroion adsorption. We consider and compare two experimentally relevant scenarios: cationic macroions adsorbed onto anionic membranes and anionic macroions adsorbed onto cationic membranes. We show that in the former case the adsorption strength is slightly weakened by the presence of the headgroup dipoles of the zwitterionic lipids. Here, macroion-induced lipid demixing is more pronounced and the lipid headgroups tilt away from a cationic macroion upon adsorption. In contrast, for the adsorption of anionic macroions onto a cationic membrane the zwitterionic lipids strongly participate in the electrostatic interaction between membrane and macroion, thus enhancing the adsorption strength significantly (we predict up to 20%). Consistent with that we find less lateral demixing of the charged lipids and a reorientation of the dipoles of the zwitterionic headgroups towards the anionic macroions. Our results may be of importance to understand the differences in the electrostatic adsorption of proteins/peptides onto cellular membranes versus complex formation between cationic membranes and DNA.     

Physical aging and relaxation processes in epoxy systems

Relaxation transitions in epoxy oligomers of various chemical nature and three-dimensional polymer networks on their basis are considered. Additional factors affecting relaxation of the networks, namely, the conversion of reactive functional groups of monomers during curing and the crosslink density of the network being formed, are discussed. Special attention is given to the phenomenon of physical aging in glassy crosslinked epoxy systems, which is analyzed from the experimental and theoretical viewpoints.     

The influence of anisotropic membrane inclusions on curvature elastic properties of lipid membranes

A membrane inclusion can be defined as a complex of protein or peptide and the surrounding significantly distorted lipids. We suggest a theoretical model that allows for the estimation of the influence of membrane inclusions on the curvature elastic properties of lipid membranes. Our treatment includes anisotropic inclusions whose energetics depends on their in-plane orientation within the membrane. On the basis of continuum elasticity theory, we calculate the inclusion-membrane interaction energy that reflects the protein or peptide-induced short-ranged elastic deformation of a bent lipid layer. A numerical estimate of the corresponding interaction constants indicates the ability of inclusions to sense membrane bending and to accumulate at regions of favorable curvature, matching the effective shape of the inclusions. Strongly anisotropic inclusions interact favorably with lipid layers that adopt saddlelike curvature; such structures may be stabilized energetically. We explore this possibility for the case of vesicle budding where we consider a shape sequence of closed, axisymmetric vesicles that form a (saddle-curvature adopting) membrane neck. It appears that not only isotropic but also strongly anisotropic inclusions can significantly contribute to the budding energetics, a finding that we discuss in terms of recent experiments.     

Supramolecular chemistry in lipid bilayer membranes

Lipid bilayer membranes form compartments requisite for life. Interfacing supramolecular systems, including receptors, catalysts, signal transducers and ion transporters, enables the function of the membrane to be controlled in artificial and living cellular compartments. In this perspective, we take stock of the current state of the art of this rapidly expanding field, and discuss prospects for the future in both fundamental science and applications in biology and medicine.

This perspective provides an overview of the current state of the art in supramolecular chemistry in lipid bilayer membranes, including receptors, signal transducers, catalysts and transporters, and highlights prospects for the future.     

How does internal motion influence the relaxation of the water protons in Ln(III)DOTA-like complexes?

Taking advantage of the Curie contribution to the relaxation of the protons in the Tb(III) complex, and the quadrupolar relaxation of the 17O and 2H nuclei on the Eu(III) complex, the effect of the internal motion of the water molecule bound to [Ln(DOTAM)(H2O)]3+ complexes was quantified. The determination of the quadrupolar coupling constant of the bound water oxygen chi(Omicron)(1 + eta(Omicron)2/3)1/2 = 5.2 +/- 0.5 MHz allows a new analysis of the 17O and 1H NMR data of the [Gd(DOTA)(H2O)]- complex with different rotational correlation times for the Gd(III)-O(water) and Gd(III)-H(water) vectors. The ratio of the rotational correlation times for the Ln(III)-H(water) vector and the overall rotational correlation time is calculated tau(RH)/tau(RO) = 0.65 +/- 0.2. This could have negative consequences on the water proton relaxivity, which we discuss in particular for macromolecular systems. It appears that the final effect is actually attenuated and should be around 10% for such large systems undergoing local motion of the chelating groups.     

Protecting, patterning, and scaffolding supported lipid membranes using carbohydrate glasses

Disaccharides are known to protect sensitive biomolecules against stresses caused by dehydration, both in vivo and in vitro. Here we demonstrate how interfacial accumulation of trehalose can be used to (1) produce rugged supported lipid bilayers capable of near total dehydration; (2) enable spatial patterning of membrane micro-arrays; and (3) form stable bilayers on otherwise lipophobic substrates (e.g., metal transducers) thus affording protecting, patterning, and scaffolding of lipid bilayers.     

Ligand-induced reorganization and assembly in synthetic lipid membranes

Membrane targetting of soluble ligands accompanied by assembly of membrane components into functional superstructures underlies biological signal transduction and a variety of other processes ranging from blood coagulation to biomineralization. Protein or lipid components provide the interactions required for targetting and specific orientation of bound molecules; the membrane's fluidity allows reorganization and sampling of intermolecular contacts required for assembly into superstructures. We are developing synthetic membrane-based recognition systems capable of reproducing important features of biological targetting and assembly. Systems such as these may open up new routes to controlling molecular architecture in materials and devices. Specially designed metal-chelating receptor/reporter lipids have been used to study lipid reorganization induced by binding of metal-complexing ligands. Proteins and peptides are targetted to the Cu²⁺- and Ni²⁺-complexing lipids via coordination interactions with surface histidines. Binding and assembly of multivalent ligands are accompanied by reorganization of the lipid receptors, as measured by fluorescence spectroscopy and fluorescence microscopy. Coordination interactions between protein and chelating lipid components can be used for direct assembly into superstructures such as patterned lipid monolayers and two-dimensional protein crystals.     

Competitive adsorption of Ca and local anesthetics on lipid membrane surfaces

Adsorption fo tertriary amine local anesthetics and Ca²⁺ onto lipid membranes having various negative surface charge densities was studied by measuring lipid vesicle electrophoretic mobility.

As the surface charge density of the membrane was reduced, the adsorption of the local anesthetics dominated that of the divalent cation. For a relatively high negatively charged membrane, the adsorption of both local anesthetic and Ca²⁺ became comparable and competitive.

It is deduced that the major factor for the adsorption of local anesthetic onto lipid membranes is due to simple physical partitioning between aqueous and membrane phases, and not due to ionic type of binding as seen for divalent cations with membranes. However, the adsorption of anesthetics is influenced by the surface potential of membranes which is in turn related to the surface concentration of local anesthetics near the membrane.

The amounts of competitive adsorption of divalent cations and local anesthetics are analyzed with respect to their bulk concentrations and various surface charge densities of the membranes. With the results of the above studies, a possible interpretation for the interaction site as well as the mode of adsorption of local anesthetics onto axon membranes is made in relation to divalent cation concentrations in the bulk phases.     

Multiple relaxation processes versus the fragile-to-strong transition in confined water

Broadband dielectric spectroscopy data on water confined in three different environments, namely at the surface of a globular protein or inside the small pores of two silica substrates, in the temperature range 140 K ≤ T ≤ 300 K, are presented and discussed in comparison with previous results from different techniques. It is found that all samples show a fast relaxation process, independently of the hydration level and confinement size. This relaxation is well known in the literature and its cross-over from Arrhenius to non-Arrhenius temperature behavior is the object of vivid debate, given its claimed relation to the existence of a second critical point of water. We find such a cross-over at a temperature of ~180 K, and assign the relaxation process to the layer of molecules adjacent and strongly interacting with the substrate surface. This is the water layer known to have the highest density and slowest translational dynamics compared to the average: its apparent cross-over may be due to the freezing of some degree of freedom and survival of very localized motions alone, to the onset of finite size effects, or to the presence of a calorimetric glass transition of the hydration shell at ~170 K. Another relaxation process is visible in water confined in the silica matrices: this is slower than the previous one and has distinct temperature behaviors, depending on the size of the confining volume and consequent ice nucleation.