Effect of the phase state of the lipid bilayer on the structure and characteristics of the polycation-(anionic liposome) complex

Interaction of the cationic polymer poly-N-ethyl-4-vinylpyridinium bromide with bilayer vesicles (liposomes) composed of zwitterionic dipalmitoylphosphatidylcholine and anionic cardiolipin (the molar fraction of the negatively charged cardiolipin groups is 0.2) is studied. The composition and characteristics of the polycation-liposome complex are shown to be controlled by the phase state of the lipid membrane. Liposomes whose membranes exist in their LC state (“liquid” liposomes) keep their integrity in the complex with polycation. The adsorbed polycation can be completely removed from the liposomal membrane by the addition excess amounts of a competing polyanion. The adsorption of polycation on the surface of liposomes whose membranes exist the gel state (“solid” liposomes) leads to the formation of defects in the membrane, and the polycation’s adsorption with such liposomes becomes irreversible. The defects that form are also preserved when solid liposomes on whose surface the polycation is sorbed are transformed into the liquid state. Moreover, the reversible contact between polycation and liquid liposomes becomes irreversible once the liposomal membranes bound to the polycation transform into the solid state.     

Stability of anionic liposome-cationic polymer complexes in water-salt media

Laser microelectrophoresis, dynamic light scattering, and fluorescence and UV spectroscopy are employed to study poly-N-ethyl-4-vinylpyridinium bromide adsorption on the surface of bilayer lipid vesicles (liposomes) formed from mixtures of anionic phosphatidyl serine and electroneutral phosphatidylcholine. It is established that polycation adsorption is accompanied by the neutralization of charges on liposomes and their aggregation. The subsequent addition of a low-molecular-weight salt (NaCl) solution to suspensions of complexes causes them to dissociate into their initial components, while the stability of the complexes with respect to the salt action increases with the fraction of the anionic lipid in the liposome membranes. The data obtained are interpreted from the position of the formation-disintegration of a molecular capacitor, the charge of which is generated by spatially separated anionic lipids located in the bilayer membrane and cationic units of the adsorbed polyamine.     

The Influence of the Chain Length of Polycations on their Complexation with Anionic Liposomes

A series of strong polycations is synthesized through the anionic polymerization of 2‐vinylpyridine, followed by subsequent quaternization of the resulting polymer. Polycations based on quaternized 2‐vinylpyridine (PVPQs) with degrees of polymerization (DP) from 20 to 440 are adsorbed on the surface of small anionic liposomes. Liposome/PVPQ complexes are characterized by using a number of physicochemical methods. All PVPQs are totally adsorbed onto the liposome surface up to a certain concentration at which saturation is reached (which is specific for each PVPQ). The integrity of the adsorbed liposomes remains intact. Short PVPQs interact with anionic lipids localized on the outer membrane leaflet, whereas long PVPQs extract anionic lipids from the inner to outer leaflet. Complexes tend to aggregate, and the largest aggregates are formed when the initial charge of the liposomes is fully neutralized by the charge of the PVPQ. PVPQs with intermediate DPs demonstrate behavioral features of both short and long PVPQs. These results are important for the interpretation of the biological effects of cationic polymers and the selection of cationic polymers for biomedical applications.     

Migration of a cationic polymer between lipid vesicles

The adsorption of a synthetic polycation, poly(N-ethyl-4-vinylpyridinium bromide) (PEVP), on the surface of bilayer lipid vesicles (liposomes) and the migration of adsorbed macromolecules between the liposomes are studied. Liposomes of three types are used, including (1) traditional two-component liposomes composed of neutral phosphatidylcholine (PC) and anionic cardiolipin (CL); (2) three-component liposomes consisting of PC, CL, and cationic dicetyldimethylammonium bromide (DCMAB); and (3) anionic PC/CL liposomes with a nonionic surfactant, poly(ethylene oxide)-cetyl alcohol ether (Briij 58), incorporated into their bilayers. The adsorption of PEVP on the surface of PC/CL liposomes is accompanied by their aggregation. Using the fluorescence method, it is shown that the units (segments) of the polycation undergo partial redistribution between the liposomes inside the aggregates formed from PC/CL liposomes (with and without a fluorescent label) and PEVP. On the contrary, three-component PC/CL/DCMAB and PC/CL/Briij liposomes are not aggregated, even with the complete neutralization of their charges by adsorbed PEVP. In both cases, the migration of PEVP molecules between individual (nonaggregated) liposomes is observed. Possible reasons for the aggregative stability of the three-component PC/CL/DCMAB and PC/CL/Briij liposomes and the mechanism of interliposome migration of PEVP in such systems are discussed.     

Structure and properties of complexes formed by cationic polymers and anionic cholesterol-containing liposomes

The adsorption of the synthetic polycation poly(N-ethyl-4-vinylpyridinium bromide) on the surface of three-component lipid vesicles (liposomes) formed from a mixture of anionic cardiolipin, electroneutral egg lecithin, and nonionic cholesterol is studied via laser microelectropheresis, dynamic light scattering, conductometry, fluorescence spectroscopy, and UV spectroscopy. The incorporation of cholesterol into the liposomal membrane increases its microviscosity; however, the membrane remains liquid-crystalline. Simultaneously, an increase in the fraction of cholesterol causes the formation of defects in liposome membranes during their binding with poly(N-ethyl-4-vinylpyridium bromide) and makes complexation irreversible. The results of this study are of interest for predicting the behavior of polyelectrolytes and biologically active structures formed on their basis on the surface of cells and the reaction of the cellular membrane to the adsorbed polymer.     

Colloid stability of sodium dihexadecyl phosphate/poly(diallyldimethylammonium chloride) decorated latex

The colloid stability of supramolecular assemblies composed of the synthetic anionic lipid sodium dihexadecyl phosphate (DHP) on cationic poly(diallyldimethylammonium chloride) (PDDA) supported on polystyrene sulfate (PSS) microspheres was evaluated via turbidimetry kinetics, dynamic light scattering for particle sizing, zeta-potential analysis, and determination of DHP adsorption on PDDA-covered particles. At 0.05 g/L PDDA and 5 x 10(9) PSS particles/mL, PDDA did not induce significant particle flocculation and a vast majority of PDDA covered single particles were present in the dispersion so that this was the condition chosen for determining DHP concentration (C) effects on particle size and zeta-potentials. At 0.8 mM DHP, charge neutralization, maximal size, and visible precipitation indicated extensive flocculation and minimal colloid stability for the DHP/PDDA/PSS assembly. At 0.05 g L(-1) PDDA, isotherms of high affinity for DHP adsorption on PDDA-covered particles presented a plateau at a limiting adsorption of 135 x 10(19) DHP molecules adsorbed per square meter PSS which was well above bilayer deposition on a smooth particle surface. The polyelectrolyte layer on hydrophobic particles was swelled and fluffy yielding ca. 6 +/- 1.5 nm hydrodynamic thickness. Maximal and massive adsorption of DHP lipid onto this layer produced polydisperse DHP/PDDA/PSS colloidal particles with low colloid stability and which, at best, remained aggregated as doublets over a range of large lipid concentrations so that it was not possible to evaluate the mean total thickness for the deposited film. The assembly anionic lipid/cationic PDDA layer/polymeric particle was relatively stable as particle doublets only well above charge neutralization of the polyelectrolyte by the anionic lipid, at relatively large lipid concentrations (above 1 mM DHP) with charge neutralization leading to extensive particle aggregation.     

Contrasting behavior of zwitterionic and cationic polymers bound to anionic liposomes

Zwitterionic polymers were prepared by quaternizing polyvinylpyridine (DP = 1100) with bromoacids (Br(CH2)nCOOH, where n = 1, 2, 3, and 5). The resulting polymers were then added to unilamellar liposomes composed of egg lecithin or dipalmitoylphosphatidylcholine admixed with 20 mol % of cardiolipin (a phospholipid with two negative charges). These systems were compared (along with polyethylvinylpyridinium chloride, a polycation) by light scattering, electrophoretic mobility, fluorescence, and high-sensitivity differential scanning calorimetry. The external zwitterionic polymers induce no flip-flop of cardiolipin from the inner leaflet to the outer leaflet as does the polycation. Aside from this similarity, the four zwitterionic polymers all behave differently from each other toward the anionic liposomes: (a) For n = 1, there is no detectable interaction between the polymer and the liposomes. (b) For n = 2, electrostatic attraction induces polymer-liposome association (reversed by the addition of NaCl) that maintains the original negative charge on the liposome. Aggregation of the liposomes accompanies polymer adsorption. (c) For n = 3, electrostatic binding also occurs along with aggregation. However, the binding is so strong that NaCl is unable to induce polymer/liposome dissociation. (d) For n = 5, there is polymer binding and NaCl-promoted dissociation but no substantial aggregation. These differences among the closely related polymers are discussed and analyzed in molecular terms.     

Binding of Lipid Vesicles to Protein-Coated Solid Polymer Surfaces: A Model for Cell Adhesion to Artificial Biocompatible Materials

The adhesion of lipid vesicles (liposomes) having controlled chemical and physical structure to polymer supported human serum albumin (HSA) thin layers was investigated by a spectrofluorimetric technique. The vesicle lipid bilayer was labeled with a small amount of an apolar fluorescent probe (diphenylexathriene) and the vesicle suspension was set in contact with the protein film. After washing and drying, the adhering vesicles containing sample was dissolved in chloroform and the homogeneous solution was analyzed by standard spectrofluorimetric techniques. Different parameters of the lipid bilayer, suspending solution, and protein film were varied and their influence on the liposome binding was investigated. Concerning the lipid bilayer, we studied the effect of liposome surface charge by using different mixtures of neutral (dipalmitoyl-phosphatidylcholine) and charged (dipalmitoyl-phosphatidic acid) phospholipids and the fluid or gel nature of the lipid bilayer (switched on and off by temperature variation). Variations of the local environment involve Ca(2+) and H(+) changes in the millimolar range as well as different hydrodynamical flows (in the range 0.1-10 cm/s). Preliminary measurements using different protein layers were also performed. Results show: (a) negligible adhesion without the protein layer, (b) the presence of a maximum for the liposome adhesion vs ion concentration (depending on the liposome composition and kind of the adsorbed ions), (c) a much stronger adhesion for vesicles in the fluid phase (overcoming the entropy-driven desorption increase with temperature), and (d) a dramatic lowering of the adhesion capability under hydrodynamic flow. Points a-c have been interpreted on the basis of a simple mechanoelectrical model. Copyright 2000 Academic Press.     

Stabilization of Liposomes by Polyelectrolytes: Mechanism of Interaction and Role of Experimental Conditions

ζ-potential measurements on LUVs allow to evidence the influence of pH, ionic salt concentration, and polyelectrolyte charge on the interaction between polyelectrolyte (chitosan and hyaluronan) and zwitterionic lipid membrane. First, chitosan adsorption is studied: adsorption is independent on the chitosan molecular weight and corresponds to a maximum degree of decoration of 40% in surface coverage. From the dependence with pH and independence with MW, it is concluded that electrostatic interactions are responsible of chitosan adsorption which occurs flat on the external surface of the liposomes. The vesicles become positively charged in the presence of around two repeat units of chitosan added per lipid accessible polar head in acid medium down to pH = 7.2. Direct optical microscopy observations of GUVs shows a stabilization of the composite liposomes under different external stresses (pH and salt shocks) which confirms the strong electrostatic interaction between the chitosan and the lipid membrane. It is also demonstrated that the liposomes are stabilized by chitosan adsorption in a very wide range of pH (2.0 < pH < 12.0). Then, hyaluronan (HA), a negatively charged polyelectrolyte, is added to vesicles; the vesicles turn rapidly negatively charged in presence of adsorbed HA Finally, we demonstrated that hyaluronan adsorbs on positively charged chitosan-decorated liposomes at pH < 7.0 leading to charge inversion in the liposome decorated by the chitosan-hyaluronan bilayer. Our results demonstrate the adsorption of positive and/or negative polyelectrolyte at the surface of lipidic vesicles as well as their role on vesicle stabilization and charge control.     

Effect of lipid headgroup composition on the interaction between melittin and lipid bilayers

The effect of the lipid polar headgroup on melittin-phospholipid interaction was investigated by cryo-TEM, fluorescence spectroscopy, ellipsometry, circular dichroism, electrophoresis and photon correlation spectroscopy. In particular, focus was placed on the effect of the lipid polar headgroup on peptide adsorption to, and penetration into, the lipid bilayer, as well as on resulting colloidal stability effects for large unilamellar liposomes. The effect of phospholipid headgroup properties on melittin-bilayer interaction was addressed by comparing liposomes containing phosphatidylcholine, -acid, and -inositol at varying ionic strength. Increasing the bilayer negative charge leads to an increased liposome tolerance toward melittin which is due to an electrostatic arrest of melittin at the membrane interface. Balancing the electrostatic attraction between the melittin positive charges and the phospholipid negative charges through a hydration repulsion, caused by inositol, reduced this surface arrest and increased liposome susceptibility to the disruptive actions of melittin. Furthermore, melittin was demonstrated to induce liposome structural destabilization on a colloidal scale which coincided with leakage induction for both anionic and zwitterionic systems. The latter findings thus clearly show that coalescence, aggregation, and fragmentation contribute to melittin-induced liposome leakage, and that detailed molecular analyses of melittin pore formation are incomplete without considering also these colloidal aspects.     

Complexes of a cationic polymer with oxidized anionic liposomes: Composition,structure, and properties

Formation of complexes obtained by the adsorption of a cationic polymer, poly(N-ethyl-4-vinylpyridium bromide), with a degree of polymerization of 600 on the surface of 50-nm bilayer vesicles (liposomes) formed from neutral phosphatidyl choline, anionic diphosphatidyl glycerol (cardiolipin), and a surfactant with one alkyl radical, such as electroneutral n-hexadecylphosphocholine, palmitic acid, or heptanoic acid, is studied. The incorporation of these surfactants into the liposomal membrane stimulates the appearance of oxidized forms of lipids in it. The incorporation of n-hexadecylphosphocholine into the membrane of n-hexadecylphosphocholine and palmitic acid with the alkyl radical, whose length is comparable with the length of alkyl radicals in a lipid molecule, has no effect on the permeability of the membrane. However, these liposomes lose integrity upon the adsorption of polycation; as a result, complexation becomes irreversible. Electroneutral and anionic surfactants with long hydrocarbon chains may accumulate in a cellular membrane owing to the oxidative degradation of unsaturated radicals in lipid molecules. This finding may be used in the design of polymeric therapeutic means specifically interacting with damaged cells.     

Arraying of intact liposomes into chemically functionalized microwells

Here, we describe a protocol to bind individual, intact phospholipid bilayer liposomes, which are on the order of 1 microm in diameter, in microwells etched in a regular array on a silicon oxide substrate. The diameter of the wells is on the order of the liposome diameter, so only one liposome is located in each well. The background of the silicon oxide surface is functionalized with a PEG oligomer using the contact printing of a PEG silane to present a surface that resists the adsorption of proteins, lipid material, and liposomes. The interiors of the wells are functionalized with an aminosilane to facilitate the conjugation of biotin, which is then bound to Neutravidin. The avidin-coated well interiors bind the liposomes whose surfaces contain biotinylated lipids. The specific binding of the liposomes to the surface using the biotin-avidin linkage, together with the resistant nature of the background and the physical confinement of the wells, allows the liposomes to remain intact and to not unravel, rupture, and fuse onto the surface. We demonstrate this intact arraying using confocal laser scanning microscopy of fluorophores specifically tagging the microwells, the lipid bilayer, and the aqueous interior of the liposome.     

Structure and characteristics of the complexes between polyampholites and anionic liposomes

Polyampholites are synthesized by the alkylation of poly-4-vinylpyridine with ω-bromocarboxylic acids, and their interaction with the negatively charged bilayer lipid vesicles (liposomes) is studied. In the above polymers, quaternized pyridine units are zwitterion (betaine) groups, in which cationic and anionic groups are linked by the -(CH₂) _n -bridges. Via the methods of fluorescence, laser scattering, and DSC, the length of the ethylene spacer in the betaine group is shown to control the ability of the polymer to interact with anionic liposomes and induce structural rearrangements in the liposomal membrane. At n = 1, polybetaine is not linked to anionic liposomes. At n = 2, polybetaine is sorbed on the membrane, but it causes no dramatic structural rearrangements in the bilayer. At n = 3, the adsorption of polybetaine triggers the lateral segregation of lipids in the outer membrane layer. At n = 5, adsorption of polymer is accompanied by the lateral segregation and flip-flop of lipid molecules; as a result, all anionic membrane lipids are involved in the microphase separation. This evidence is of evident interest for the controlled design of polymers and related complexes and conjugates for biomedical applications.     

Physicochemical and biological properties of polyampholytes: Quaternized derivatives of poly(4-vinylpyridine)

The modification of poly(4-vinylpyridine) with ω-bromocarboxylic acids and alkyl bromides yields three types of polyampholytes: polyampholytes containing both cationic and anionic groups in each monomer unit (polybetaines), polyampholytes containing betaine and cationic units, and polyampholytes containing betaine units and side cetyl radicals. Their complex formation with liposomes formed from zwitterionic (electroneutral) phosphatidylcholine and anionic diphosphatidylglycerol (cardiolipin) is investigated. The method for fixation of polymers on the liposomal membrane and the stability of the formed complexes are determined by the chemical structure of macromolecules. For the most part, polyelectrolytes are electrostatically adsorbed on the membrane and are fully removed from it with an increase in the salt concentration in the surrounding solution. An exception is the polybetaine obtained through the modification of poly(4-vinylpyridine) with ω-bromobutyric acid, which irreversibly binds to liposomes probably owing to the incorporation of macromolecular fragments into the hydrophobic part of the lipid bilayer. The insertion of side cetyl radicals into polybetaine molecules stabilizes their complexes with liposomes in the presence of salts. The cytotoxicity of the synthesized polyampholytes is one to two orders of magnitude lower than that of a cationic polymer with the same degree of polymerization.     

Interaction Between Liposomes and Neutral Polymers: Effect of Adsorption on Drug Release

The processes of adsorption of two neutral polymers (poly(vinyl pyrrolidone), PVP and poly(vinyl alcohol), PVA) were investigated on liposomes composed of soy lecithin/dicetyl phosphate/cholesterol = 25:2:3 (molar ratio). The liposomes were prepared in buffered solution at pH = 7.4 and mixed with the solution of the measured polymers in the desired polymer/lipid (w/w) ratios. Adsorption was measured by determination of the equilibrium bulk concentration of the polymer. In the case of PVA quantitative adsorption measurements with a specific reagent were possible. Adsorption isotherms were recorded at 25 ± 1°C. It was concluded that adsorbed and unadsorbed PVA molecules are in equilibrium even at low polymer/ lipid ratios. The results were confirmed by dynamic laser light scattering (DLS), and thermal activity monitoring (TAM) experiments. Another group of the liposomes was prepared in 60 mM ammonium sulphate (pH = 5.0) and we filled the vesicles with a test dye, acridine orange (AO) using the pH-gradient (remote loading) method. The AO release property of liposomes was tested with a special vertical diffusion cell after we had made PVA adsorb on their surface in different PVA/lipid (w/w) ratios.     

Inverse-phosphocholine lipids: a remix of a common phospholipid

Zwitterionic inverse-phosphocholine (iPC) lipids contain headgroups with an inverted charge orientation relative to phosphocholine (PC) lipids. The iPC lipid headgroup has a quaternary amine adjacent to the bilayer interface and a phosphate that extends into the aqueous phase. Neutral iPC lipids with ethylated phosphate groups (CPe) and anionic iPC lipids nonethylated phosphate groups (CP) were synthesized. The surface potential of CPe liposomes remains negative across a broad pH range and in the presence of up to 10 mM Ca(2+). CP liposomes aggregate in the presence of Ca(2+), but at a slower rate than other anionic lipids. Hydrolysis of CP lipids by alkaline phosphatases generates a cationic lipid. CPe liposomes release encapsulated anionic carboxyfluorescein (CF) 20 times faster than PC liposomes and release uncharged glucose twice as fast as PC liposomes. As such, iPC lipids afford a unique opportunity to investigate the biophysical and bioactivity-related ramifications of a charge inversion at the bilayer surface.     

Polyelectrolyte-coated liposomes: stabilization of the interfacial complexes

Anionic liposomes, composed of egg lecithin (EL) or dipalmitoylphosphatidylcholine (DPPC) with 20 mol% of cardiolipin (CL(2-)), were mixed with cationic polymers, poly(4-vinylpyridine) fully quaternized with ethyl bromide (P2) or poly-l-lysine (PL). Polymer/liposome binding studies were carried out using electrophoretic mobility (EPM), fluorescence, and conductometry as the main analytical tools. Binding was also examined in the presence of added salt and polyacrylic acid (PAA). The following generalizations arose from the experiments: (a) Binding of P2 and PL to small EL/CL(2-) liposomes (60-80 nm in diameter) is electrostatic in nature and completely reversed by addition of salt or PAA. (b) Binding can be enhanced by hydrophobization of the polymer with cetyl groups. (c) Binding can also be enhanced by changing the phase state of the lipid bilayer from liquid to solid (i.e. going from EL to DPPC) or by increasing the size of the liposomes (i.e. going from 60-80 to 300 nm). By far the most promising systems, from the point of view of constructing polyelectrolyte multilayers on liposome cores without disruption of liposome integrity, involve small, liquid, anionic liposomes coated initially with polycations carrying pendant alkyl groups.     

Probing mechanical properties of liposomes using acoustic sensors

Acoustic devices were employed to characterize variations in the mechanical properties (density and viscoelasticity) of liposomes composed of 1-oleoyl-2-palmitoyl- sn-glycero-3-phosphocholine (POPC) and cholesterol. Liposome properties were modified in three ways. In some experiments, the POPC/cholesterol ratio was varied prior to deposition on the device surface. Alternatively, the ratio was changed in situ via either insertion of cholesterol or removal of cholesterol with beta-cyclodextrin. This was done for liposomes adsorbed directly on the device surface and for liposomes attached via a biotin-terminated poly(ethylene glycol) linker. The acoustic measurements make use of two simultaneous time-resolved signals: one signal is related to the velocity of the acoustic wave, while the second is related to dissipation of acoustic energy. Together, they provide information not only about the mass (or density) of the probed medium but also about its viscoelastic properties. The cholesterol-induced increase in the surface density of the lipid bilayer was indeed observed in the acoustic data, but the resulting change in signal was larger than expected from the change in surface density. In addition, increasing the bilayer resistance to stretching was found to lead to a greater dissipation of the acoustic energy. The acoustic response is assessed in terms of the possible distortions of the liposomes and the known effects of cholesterol on the mechanical properties of the lipid bilayer that encloses the aqueous core of the liposome. To aid the interpretation of the acoustic response, it is discussed how the above changes in the lipid bilayer will affect the effective viscoelastic properties of the entire liposome/solvent film on the scale of the acoustic wavelength. It was found that the acoustic device is very sensitive to the mechanical properties of lipid vesicles; the response of the acoustic device is explained, and the basic underlying mechanisms of interaction are identified.     

Adsorption of neutral polymers on negatively charged liposomes. A novel quantitative method to measure the rate of polymer adsorption on the liposomal surface

We studied the adsorption of two neutral polymers [poly(vinyl pyrrolidone) and poly(vinyl alcohol) (PVA)] on negatively charged liposomes composed of 25:2:3 (molar ratio) soy lecithin/dicetyl phosphate/cholesterol.The liposomes were prepared in buffered solution at pH 7.4 and were mixed with the solution of the polymers in the desired polymer/lipid ratios. Adsorption was measured by determination of the equilibrium bulk concentration of the polymer. Protamine hydrochloride was used to aggregate the liposomes with polymers adsorbed on their surface and to facilitate their separation from the equilibrium bulk solution. In the case of PVA, quantitative adsorption measurements with a specific reagent were possible. Adsorption isotherms were recorded at 25 ± 0.2 °C. It was concluded that adsorbed and nonadsorbed PVA molecules are in equilibrium even at low polymer/lipide ratios. The results were confirmed by dynamic laser light scattering, X-ray diffraction and thermal activity monitoring experiments. Received: 13 October 2000 Accepted: 8 March 2001     

Adsorption of cationic lipid bilayer onto flat silicon wafers: effect of ion nature and concentration

The effect of monovalent salt nature and concentration over a range of low ionic strengths (0-10 mM LiCl, NaCl, KCl, or CsCl) and at two different pH values (6.3 and 10.0) on adsorption of dioctadecyldimethylammonium bromide (DODAB) bilayer fragments (BF) onto flat SiO(2) surfaces was systematically evaluated by means of in situ ellipsometry. High-affinity adsorption isotherms fitted by the Langmuir model indicated that adsorption maxima were consistent with bilayer deposition only around 10 mM monovalent salt at both pH values. In pure water, the mean thickness of the DODAB adsorbed layer was close to zero with bilayer deposition taking place only around 10 mM ionic strength. In the presence of 10 mM CsCl or LiCl, the highest and the lowest affinity constants for DODAB adsorption onto SiO(2) were, respectively, obtained consistently with the expected facility of cation exchange at the surface required for DODAB adsorption. The cation more tightly bound to the solid surface should be Li(+), which would present the largest resistance to displacement by the DODAB cation, whereas the less tightly bound cation should be Cs(+) due to its largest ionic radius and lowest charge density. In other words, DODAB adsorption proceeds in accordance with charge density on the solid surface, which depends on the nature and concentration of bound counterions as well as DODAB cation ability to displace them. AFM images show a very smooth DODAB film adsorbed onto the surface in situ with a large frequency of BF auto-association from their edges. The present results for flat surfaces entirely agree with previous data from our group for DODAB adsorption onto silica particles.