Local anesthetic-induced microscopic and mesoscopic effects in micelles. A fluorescence,spin label and SAXS study

The interaction of the local anesthetic tetracaine (TTC) with anionic sodium lauryl sulfate (SLS) and zwitterionic 3-(N-hexadecyl-N,N-dimethylammonio)propanesulfonate (HPS) micelles was investigated by fluorescence, spin labeling EPR and small angle X-ray scattering (SAXS). Fluorescence pH titrations allowed the choice of adequate pHs for the EPR and SAXS experiments, where either charged or uncharged TTC would be present. The data also indicated that the anesthetic is located in a less polar environment than its charged counterpart in both micellar systems. EPR spectra evidenced that both anesthetic forms increased molecular organization within the SLS micelle, the cationic form exerting a more pronounced effect. The SAXS data showed that protonated TTC causes an increase in the SLS polar shell thickness, hydration number, and aggregation number, whereas the micellar features are not altered upon incorporation of the uncharged drug. The combined results suggest that the electrostatic interaction between charged TTC and SLS, and the intercalation of the drug in the micellar polar region induce a change in molecular packing with a decrease in the mean cross-sectional area, not observed when the neutral drug sinks more deeply into the micellar hydrophobic domain. In the case of HPS micelles, the EPR spectral changes were small for the charged anesthetic and the SAXS data did not evidence any change in micellar structure, suggesting that this species protrudes more into the aqueous phase due to the lack of electrostatic attractive forces in this system.     

Copoly(styrene-maleic acid)-pirarubicin micelles: high tumor-targeting efficiency with little toxicity

The copolymer of styrene-maleic acid (SMA) was used to construct micelles containing pirarubicin (4'-O-tetrahydropyranyladriamycin, or THP) as a new anticancer drug formulation. The procedure for the preparation of the micelles was simple, the component consisting of only SMA and pirarubicin in a noncovalent association, possibly by hydrophobic interaction between the styrene portion of SMA and pirarubicin chromophore. This method ensures more than 80% recovery of pirarubicin by weight, and 60% of drug loading (by weight) was achieved. The micelles obtained (SMA-THP) showed high solubility in water and a constant pirarubicin release rate of about 3-4%/day in vitro. SMA-THP micelles had an average molecular size of about 34 kDa according to gel chromatography; this size is a marked increase from the 627.6 Da of free THP, which suggests the formation of a micellar structure. When albumin was added, the molecular size of the micelles increased to about 94 kDa, which indicates binding to albumin, a unique characteristic of SMA. SMA-THP micelle preparation had a cytotoxic effect (93-101%) on MCF-7 breast cancer cells and SW480 human colon cancer cells in vitro that was comparable to that of free THP. An in vivo assay of SMA-THP at doses of 20 mg/kg in ddY mice bearing S-180 tumor revealed complete tumor eradication in 100% of tested animals. Mice survived for more than 1 year after treatment with micellar drug doses as high as 100 mg/kg pirarubicin equivalent. This marked antitumor activity can be attributed to the enhanced permeability and retention (EPR) effect of macromolecular drugs seen in solid tumors, which enables selective delivery of drugs to tumor and thus much fewer side effects. Complete blood counts, liver function test, and cardiac histology showed no sign of adverse effects for intravenous doses of the micellar preparation. These data thus suggest that intravenous administration of the SMA-THP micellar formulation can enhance the therapeutic effect of pirarubicin more than 50-fold.     

Spin label study of local anesthetic-lipid membrane interactions. Phase separation of the uncharged from and bilayer micellization by the charged form of tetracaine

The interaction between tetracaine and egg phosphatidylcholine (egg PC) multibilayers was examined. ESR spectra of an ester spin label indicate that at low uncharged anesthetic: lipid ratios, membrane organization decreases. At higher ratios, saturation and phase separation occur, as suggested by a second spectral component which appears when the water solubility of tetracaine is reached. However, experiments with the drug in the absence and in the presence of membranes, making use of a phospholipid spin label, suggest that the new phase does not consist of solid tetracaine alone. Location of the new phase in the membrane would require a change in partition coefficient, while its location outside would imply a mechanism whereby the anesthetic would come off the membrane as aggregate containing spin probe and phospholipid. Charged tetracaine forms micelles which disrupt-unilamellar egg PC vesicles (Fernandez, M.S. (1981) Biochim. Biophys. Acta 646, 27–30). Micellar tetracaine added to bilayers containing a PC spin probe changes the spectrum from one typical of a bilayer into one typical of micelles, indicating the formation of a tetracaine-egg PC mixed micelle. The effect is reversible upon dilution to concentrations below the critical micelle concentration of tetracaine. When membranes are prepared in the presence of a water-soluble spin label, TEMPOcholine, ascorbate destroys the signal of untrapped label; when mixed phospholipid-tetracaine are formed by addition of micellar tetracaine, this leads to a complete loss of the ESR signal. High drug concentrations are often used for anesthesia and could be related to morphological nerve damage caused by large doses of anesthetics.     

Spin label study of local anesthetic-lipid membrane interactions. Phase separation of the uncharged form and bilayer micellization by the charged form of tetracaine

The interaction between tetracaine and egg phosphatidylcholine (egg PC) multibilayers was examined. ESR spectra of an ester spin label indicate that at low uncharged anesthetic: lipid ratios, membrane organization decreases. At higher ratios, saturation and phase separation occur, as suggested by a second spectral component which appears when the water solubility of tetracaine is reached. However, experiments with the drug in the absence and in the presence of membranes, making use of a phospholipid spin label, suggest that the new phase does not consist of solid tetracaine alone. Location of the new phase in the membrane would require a change in partition coefficient, while its location outside would imply a mechanism whereby the anesthetic would come off the membrane as an aggregate containing spin probe and phospholipid. Charged tetracaine forms micelles which disrupt-unilamellar egg PC vesicles (Fernandez, M.S. (1981) Biochim. Biophys. Acta 646, 27-30). Micellar tetracaine added to bilayers containing a PC spin probe changes the spectrum from one typical of a bilayer into one typical of micelles, indicating the formation of a tetracaine-egg PC mixed micelle. The effect is reversible upon dilution to concentrations below the critical micelle concentration of tetracaine. When membranes are prepared in the presence of a water-soluble spin label, TEMPOcholine, ascorbate destroys the signal of untrapped label; when mixed phospholipid-tetracaine are formed by addition of micellar tetracaine, this leads to a complete loss of the ESR signal. High drug concentrations are often used for anesthesia and could be related to morphological nerve damage caused by large doses of anesthetics.     

Effect of lipid membranes on the apparent pK of the local anesthetic tetracaine. Spin label and titration studies

Electrometric titrations and spin label data demonstrate changes in the experimentally determined apparent pK of an ionizable drug in the presence of membranes. This effect is attributed to the difference in partition coefficients for the charged and uncharged forms of the drug. Investigation of the binding of a local anesthetic, tetracaine, to egg phosphatidylcholine membranes indicates that the drug apparent pK decreases in the presence of membranes, the decrease being a function of membrane concentration. The agreement between titration and spin label studies is very good and could be simulated by calculating membrane-bound and free populations of charged and uncharged tetracaine from the independently-measured partition coefficients for the two forms.     

Site of action of the local anesthetic tetracaine in a phosphatidylcholine bilayer with incorporated cardiolipin.

Tetracaine (TTC) increases the permeability of phospholipid liposomal membranes to water, and this increase is reduced by the incorporation of cardiolipin into the membranes. We examined the molecular interaction of a phospholipid with the TTC cation in egg-yolk phosphatidylcholine (EyPC) liposomal membranes with incorporated bovine heart cardiolipin (BhCL) by IR spectroscopy and by determination of partitioning and the pKa of membrane-bound TTC. The IR spectra indicated that TTC shifted the stretching band of the BhCL PO2- group, a potential site of hydration in the bilayer, to a lower frequency but did not shift that of EyPC. TTC intercalated into the BhCL bilayer shifted its aromatic C-N stretching band to a lower frequency. One molecule of TTC was found to bind approximately five molecules of EyPC, and the incorporation of negatively charged BhCL into EyPC membranes increased the degree of binding of TTC to the bilayer membranes. The pKa values of TTC bound to membranes were determined as 7.7, 9.4, and 10.2 for EyPC membranes, EyPC membranes containing 50 mol % BhCL, and BhCL membranes, respectively, whereas that in an aqueous 10-mM NaCl solution was 8.5, as it was dependent on the manner of binding. The IR data together with the partitioning and the pKa data suggested differences between the actions of the TTC cation on negatively charged BhCL and on neutrally charged EyPC polar groups in the region close to the aqueous interface of the lipid bilayer.     

Studies on the mechanism of interaction of a bioresponsive endosomolytic polyamidoamine with interfaces. 1. Micelles as model surfaces

Polymers are appealing as pH-responsive elements of multicomponent systems designed to promote cytosolic delivery of macromolecular drugs (including proteins and genes), but so far the delivery efficiency achieved has been relatively modest. Therefore, the aim of this study was to apply several physicochemical techniques that are well established in the colloid field (surface tension measurements, small-angle neutron scattering (SANS), and electron paramagnetic resonance (EPR)) to probe the mechanism of endosomolytic polymer-surface interaction over the pH range 7.4 to 5.5 using the poly(amidoamine) (PAA) ISA23 x HCl and a series of "model" micelle surfaces. These micellar models were chosen to represent increasing complexity from simple, single surfactant sodium dodecylsulfate (SDS) micelles, surfactant mixtures containing bulky malono-bis-N-methylglucamide headgroups, or highly extended ethylene oxide headgroups. Spherical micelles composed of 1-palmitoyl-2-hydroxy-sn-glycero-3-phosphocholine (lyso-PC) were also used. Changes in the onset of micellization, micelle surface fluidity, and in selected cases, the overall micelle shape and size were all quantified as a function of pH in the presence and absence of ISA23 x HCl. This amphoteric PAA is negatively charged at pH 7.4 and becomes gradually more protonated on exposure to lower pH values representative of the endosomal-lysosomal pathway. As expected, the strength of polymer interaction with anionic micelles increased with a decrease in pH, while for cationic micelles the opposite was observed. Addition of bulky, nonionic surfactant headgroups led to weaker interactions. The observations from surface tension and SANS studies showed a complex pattern of interaction with both an electrostatic and hydrophobic component. Using EPR it was confirmed that ISA23 x HCl perturbed the micelle palisade layer leading to a decrease in fluidity of the interface with a lower degree of headgroup hydration, and a significant change in micelle morphology. Surprisingly, there was no interaction between ISA23 x HCl and globular micelles formed from lyso-PC (a more biologically relevant model), and this suggests that the PAA structure could be better optimized to promote rapid interaction with endosomal membranes at the physiologically relevant pH 6.5.     

Insights into the molecular basis of action of the AT1 antagonist losartan using a combined NMR spectroscopy and computational approach

The drug:membrane interactions for the antihypertensive AT1 antagonist losartan, the prototype of the sartans class, are studied herein using an integrated approach. The pharmacophore arrangement of the drug was revealed by rotating frame nuclear Overhauser effect spectroscopy (2D ROESY) NMR spectroscopy in three different environments, namely water, dimethyl sulfoxide (DMSO), and sodium dodecyl sulfate (SDS) micellar solutions mimicking conditions of biological transport fluids and membrane lipid bilayers. Drug association with micelles was monitored by diffusion ordered spectroscopy (2D DOSY) and drug:micelle intermolecular interactions were characterized by ROESY spectroscopy. The localisation of the drug in the micellar environment was investigated by introducing 5-doxyl and 16-doxyl stearic acids. The use of spin labels confirmed that losartan resides close to the micelle:water interface with the hydroxymethyl group and the tetrazole heterocyclic aromatic ring facing the polar surface with the potential to interact with SDS charged polar head groups in order to increase amphiphilic interactions. The spontaneous insertion, the diffusion pathway and the conformational features of losartan were monitored by Molecular Dynamics (MD) simulations in a modeled SDS micellar aggregate environment and a long exploratory MD run (580 ns) in a phospholipid dipalmitoylphosphatidylcholine (DPPC) bilayer with the AT₁ receptor embedded. MD simulations were in excellent agreement with experimental results and further revealed the molecular basis of losartan:membrane interactions in atomic-level detail. This applied integrated approach aims to explore the role of membranes in losartan's pathway towards the AT₁ receptor.     

Effect of lipid membranes on the apparent pK of the local anesthetic tetracaine spin label and titration studies

Electrometric titrations and spin label data demonstrate changes in the experimentally determined apparent pK of an ionizable drug in the presence of membranes. This effect is attributed to the difference in partition coefficients for the charged and uncharged forms of the drug. Investigation of the binding of a local anesthetic, tetracaine, to egg phosphatidylcholine membranes indicates that the drug apparent pK decreases in the presence of membranes, the decrease being a function of membrane concentration. The agreement between titration and spin label studies is very good and could be simulated by calculating membrane-bound and free populations of charged and uncharged tetracaine from the independently-measured partition coefficients for the two forms.     

Dynamical and structural properties of charged and uncharged lidocaine in a lipid bilayer

Molecular dynamics computer simulations have been performed to investigate dynamical and structural properties of a lidocaine local anesthetic. Both charged and uncharged forms of the lidocaine molecule were investigated. Properties such as membrane area per lipid, diffusion, mass density, bilayer penetration and order parameters have been examined. An analysis of the lidocaine interaction with the lipid surrounding according to a simple mean field theory has also been performed. Almost all examined properties were found to depend on which of the two forms of lidocaine, charged or uncharged, is studied. The overall picture is a rather static behavior determined by the lipids for the charged molecules and more mobile situation of the uncharged form with higher diffusion and lower orientational and positional order.     

Stability of a Pseudomonas Sp. Lipase:Comparison Between Solubilized Enzyme in Reverse Micelles and Suspended Lipase in Dry Solvents

The stability of a relatively hydrophobic lipase from Pseudomonas sp., solubilized in reverse micellar media or suspended in dry solvents, was studied and compared. Factors such as the enzyme-solvent interaction, enzyme environment, hydration degree of the system, interphase quality, droplet size, and water activity were studied. A mixed micellar system which stabilized the lipase is reported. In the case of simple AOT micelles, lipase destabilization with respect to water in small droplet sizes and stabilization in the biggest micelles was observed. These effects resulted from lipase penetration into the interphase of the smaller nanodroplets, and the restriction of its conformational mobility in the region of structured water of the largest micelles, respectively. Mixed micelles increased lipase stability, which was mainly related to increased droplet size. Modification with polyethylene glycol decreased lipase stability in reverse micelles, due to the greater interaction with the micellar interphase. The preparation of nanodroplets, in which native and modified lipases were 5.4 and 9.4 times, respectively, more stable than in water, is reported. In contrast to the micellar media, low water contents (low A_w values) stabilized the solid lipase suspended in organic solvent systems. Under the hydration conditions studied here, lipase stability increased when more polar solvents were used. Two alternatives were necessary to obtain similar stabilities in n-heptane as compared with polar solvents: reduction of the water content or use of a low aquaphilic support.     

Ionization and binding equilibria of papaverine in ionic micelles studied by 1H NMR and optical absorption spectroscopy

The binding of the vasodilator drug papaverine (PAV) to micelles of zwitterionic N-hexadecyl-N,N-dimethyl-3-ammonio-1-propanesulfonate (HPS), cationic cetyltrimethylammonium chloride (CTAC) and anionic sodium dodecylsulfate (SDS) in aqueous solution was studied by 1H NMR and electronic absorption spectroscopy. In the presence of HPS or CTAC, the apparent pK(a) of PAV decreased by about 2 units, while it increased by about 2 units upon binding to SDS. However, the chemical shift patterns of both protonated (PAVH+) and deprotonated (PAV0) forms of PAV are not sensitive to the type of surfactant. The association constants were estimated as 5 +/- 2 M(-1) for PAVH+-CTAC, 8 +/- 3 M(-1) for PAVH+-HPS, (7 +/- 2) x 10(5) M(-1) for PAVH+-SDS, and 1.5 x 10(3) to 3.0 x 10(3) M(-1) for the complexes of PAV0 with all three types of micelles. Using these data, an electrostatic potential difference on the micelle-water interface was calculated as 150 +/- 10 mV for CTAC, 140 +/- 10 mV for HPS and - 140 +/- 10 mV for SDS. The results suggest that PAV aromatic rings are located in the hydrophobic part of the micelle. The electrostatic attraction or repulsion of the protonated quinoline nitrogen and surfactant headgroups changes the affinity of PAV to micelles and, thus, shifts the ionization equilibrium of PAV. The electrostatic potential of HPS micellar surface is determined by the cationic dimethylammonium headgroup fragment, whereas the anionic sulfate fragment attenuates the effective charge of HPS headgroup.     

Aqueous solubility and membrane interactions of hydrophobic peptides with peptoid tags

Lysine tagging of hydrophobic peptides of parent sequence KKAAALAAAAALAAWAALAAAKKKK-NH(2) has been shown to facilitate their synthesis and purification through water solubilization, yet not impact on the intrinsic properties of the hydrophobic core sequence with respect to its insertion into membranes in an alpha-helical conformation. However, due to their positively charged character, such peptides often become bound to phospholipid head groups in membrane surfaces, which inhibits their transbilayer insertion and/or prevents their transport across cellular bilayers. We sought to develop more neutral peptides of membrane-permeable character by replacing most Lys residues with uncharged peptoid [N-(R)glycyl] residues, which might similarly confer water solubility while retaining membrane-interactive properties of the hydrophobic core. Several "peptoid-tagged" derivatives of the parent peptide were prepared with varying peptoid content, with five of the six Lys residues replaced with peptoids Nala and/or Nval. Conformations of these peptides measured by circular dichroism spectroscopy demonstrated that these water-soluble peptides retain the alpha-helix structure in micelles (lysophosphatidylcholine and sodium dodecyl sulfate) notwithstanding the known helix-breaking capacity of the peptoid tags. Blue shifts in Trp fluorescence spectra and quenching experiments with acrylamide confirmed that peptoid-tagged peptides insert spontaneously into micellar membranes. Results suggest that upon introduction of uncharged tags, the interaction between the membrane and the peptides is dominated by the hydrophobicity of the peptide core rather than the electrostatic interactions between the Lys and the head groups of the lipids. The overall findings indicate that peptoid residues are effective surrogates for Lys as uncharged water-solubilizing tags and, as such, provide a potentially valuable feature of design of membrane-interactive peptides.     

Interactions of the local anesthetic tetracaine with membranes containing phosphatidylcholine and cholesterol: a 2H NMR study

The interactions of the local anesthetic tetracaine with multilamellar dispersions of 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) and cholesterol have been investigated by deuterium nuclear magnetic resonance of specifically deuteriated tetracaines, DMPC and cholesterol. Experiments were performed at pH 5.5, when the anesthetic is primarily charged, and at pH 9.5, when it is primarily uncharged. The partition coefficients of the anesthetic in the membrane have been measured at both pH values for phosphatidylcholine bilayers with and without cholesterol. The higher partition coefficients obtained at pH 9.5 reflect the hydrophobic interactions between the uncharged form of the anesthetic and the hydrocarbon region of the bilayer. The lower partition coefficients for the DMPC/cholesterol system at both pH values suggest that cholesterol, which increases the order of the lipid chains, decreases the solubility of tetracaine into the bilayer. For phosphatidylcholine bilayers, it has been proposed [Boulanger, Y., Schreier, S., & Smith, I. C. P. (1981) Biochemistry 20, 6824-6830] that the charged tetracaine at low pH is located mostly at the phospholipid headgroup level while the uncharged tetracaine intercalates more deeply into the bilayer. The present study suggests that the location of tetracaine in the cholesterol-containing system is different from that in pure phosphatidylcholine bilayers: the anesthetic sits higher in the membrane. An increase in temperature results in a deeper penetration of the anesthetic into the bilayer. Moreover, the incorporation of the anesthetic into DMPC bilayers with or without cholesterol results in a reduction of the lipid order parameters both in the plateau and in the tail regions of the acyl chains, this effect being greater with the charged form of the anesthetic.     

The conformation of fusogenic B18 peptide in surfactant solutions.

The interaction of B18 peptide with surfactants has been studied by circular dichroism spectroscopy and fluorescence measurements. B18 is the fusogenic motif of the fertilization sea urchin protein. The peptide forms an alpha-helix structure when interacting with positively or negatively charged surfactants below and above the critical micellar concentration (CMC). The alpha-helix formation is due to binding of surfactant monomers rather than the formation of surfactant micelles on the peptide. Fluorescence measurements show that the CMC of the negatively charged surfactant increases in the presence of B18, supporting the fact that there is a strong interaction between the peptide and monomers. Nonionic surfactant monomers have no effect on the peptide structure, whereas the micelles induce an alpha-helical conformation. In this case the helix stabilization results from the formation of surfactant micelles on the peptide.     

Proton magnetic resonance and viscosity studies of the interaction of local anesthetics and micelles.

This paper reports the interesting physical phenomenon of the formation of a very high viscosity phase when sodium dodecyl sulfate (SDS) micelles interact with the local anesthetics tetracaine and lidocaine. Charge neutralization by mobile counterions or interaction of the neutral form of the local anesthetic molecule with SDS micelles does not lead to the formation of high viscosity phases. The hydrocarbon chains of the surfactant appear to become extremely immobilized, as detected by proton magnetic resonance; likewise, the chemical shift of the aromatic protons of the local anesthetics as well as the broadening of the CH₂ protons of the SDS suggest that charge neutralization and the hydrophobic contribution of the anesthetic are the factors responsible for estabilizing the micellar aggregates. The induction of high viscosity phases can be utilized as a simple and economical method to estimate hydrophobic contributions.     

Interaction of dipyridamole with micelles of lysophosphatidylcholine and with bovine serum albumin: fluorescence studies.

The interaction of the coronary vasodilator dipyridamole with biological systems, protein and membranes has been studied through optical absorption and fluorescence spectroscopies. Using the analysis of the spectra and fluorescence intensity of dipyridamole (DIP) in solution, the interaction of this compound with the transport protein albumin (BSA) and with a model of cell membranes, namely micelles of lysophosphatidylcholine (L-PC), was investigated. Measurements were performed at pH 5.0 and pH 7.0 where the molecule of DIP is fully protonated and partially protonated, respectively. The quenching of fluorescence with nitroxide-stable radicals 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO) and 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPOL) as well as with acrylamide and iodide allowed the localization of the drug in the polar interface of micelles. Quenching by acrylamide and iodide in L-PC micelles demonstrated the effect of micelle protonation which increased the accessibility of iodide to the chromophore. An effective association constant was obtained both at pH 7.0 (7.5 x 10(3) M-1) and pH 5.0 (2.5 x 10(3) M-1) and a very good agreement with the proposed binding model was observed. The quantum yields of fluorescence data agree very well with the fluorescence lifetimes. The measurement of lifetimes was important to understand the kinetic data obtained from Stern-Volmer plots both of radical, acrylamide and iodide quenching of fluorescence. It was observed that, in the presence of micelles, the kq value increased for TEMPO while decreased for TEMPOL. This result, together with the vanishing solubility of DIP in saturated hydrocarbons and the preferential partition of TEMPO in micelles, suggested the localization of DIP in the polar micellar interface. This is also supported by the enhanced iodide quenching at pH 5.0, constancy of acrylamide quenching in the range of pH 7.0-5.0 and the partition of TEMPO and TEMPOL in SDS micelles. The association constant of DIP to BSA was also estimated both at pH 7.0 (2 x 10(4) M-1) and pH 5.0 (4 x 10(3) M-1). Quenching studies with nitroxide radicals, acrylamide and iodide also suggested the binding of the drug to a hydrophobic region of the protein. At pH 5.0, the protein undergo a conformational change which leads to a loosening of the overall structure so that the accessibility of the nitroxide radicals for DIP is increased at this pH. The differences in kq values at pH 7.0 and pH 5.0 suggested that at pH 7.0 the chromophore is protected in the protein site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Interactions of bovine serum albumin with ethylene oxide/butylene oxide copolymers in aqueous solution

The interactions of bovine serum albumin (BSA) with three ethylene oxide/butylene oxide (E/B) copolymers having different block lengths and varying molecular architectures is examined in this study in aqueous solutions. Dynamic light scattering (DLS) indicates the absence of BSA-polymer binding in micellar systems of copolymers with lengthy hydrophilic blocks. On the contrary, stable protein-polymer aggregates were observed in the case of E 18B 10 block copolymer. Results from DLS and SAXS suggest the dissociation of E/B copolymer micelles in the presence of protein and the absorption of polymer chains to BSA surface. At high protein loadings, bound BSA adopts a more compact conformation in solution. The secondary structure of the protein remains essentially unaffected even at high polymer concentrations. Raman spectroscopy was used to give insight to the configurations of the bound molecules in concentrated solutions. In the vicinity of the critical gel concentration of E 18B 10 introduction of BSA can dramatically modify the phase diagram, inducing a gel-sol-gel transition. The overall picture of the interaction diagram of the E 18B 10-BSA reflects the shrinkage of the suspended particles due to destabilization of micelles induced by BSA and the gelator nature of the globular protein. SAXS and rheology were used to further characterize the structure and flow behavior of the polymer-protein hybrid gels and sols.     

The effect of neutral and charged micelles on the acid-base dissociation of the local anesthetic tetracaine

The influence of surfactant micelles on the acid-base dissociation of the charged tertiary amino group of the local anesthetic, tetracaine, has been investigated. From measurements of tetracaine fluorescence as a function of bulk pH, apparent $\text{p}\text{K}$ values of 6.88, 7.58 and 9.92 were found in the presence of cationic, neutral and anionic micelles, respectively, in 10 mM NaCl. These values are considerably displaced with respect to the $\text{p}\text{K}$ in aqueous solution which is 8.26. Such large shifts can be attributed to the effect of the surface polarity and electrical potential on the dissociation behavior of the anesthetic bound to micelles. It can be expected that the acid-base dissociation of a local anesthetic adsorbed to nerve fibers will also be affected by the properties of the membrane surface. Thus, it is suggested that the influence of the interfacial region on the $\text{p}\text{K}$ of surface-bound molecules should not be disregarded when estimating the proportion of charged and uncharged forms of local anesthetics interacting with axonal membranes.     

Multiple binding sites for local anesthetics in membranes: characterization of the sites and their equilibria by deuterium NMR of specifically deuterated procaine and tetracaine

Anesthetics bound to model membranes were observed directly by means of deuterium nuclear magnetic resonance (NMR). The specifically deuterated local anesthetics procaine and tetracaine were synthesized, and their partition coefficients (water:phosphatidylcholine) and pKa values determined. The interaction of these anesthetics with lamellar dispersions of egg phosphatidylcholine was studied by 2H nuclear magnetic resonance and by electron spin resonance (ESR) of a spin-labelled phospholipid at low (5.5) and high (9.5) pH. The ESR experiments suggest that tetracaine intercalates in the membrane and that it equilibrates between water and the phospholipid bilayers of the multilamellar system. The NMR results are consistent with a model where the anesthetic is (1) free in water, (2) weakly bound, and (3) strongly bound to the membrane. A fast exchange exists between the two first sites, but exchange is slow with the third site. Binding of type 3 is observed only at high pH for procaine, whereas it is found both at low and high pH for tetracaine. Calculations of the partition coefficients for the charged and uncharged forms of tetracaine indicate that both sites, 2 and 3, are occupied by the charged form at low pH and by the uncharged form at high pH. The partition coefficient for the weakly bound species was estimated from an analysis of the dependence of line width on the lipid to water ratio. The NMR data suggest that the binding sites for the strongly bound charged and uncharged species are different, the former probably being closer to the membrane-water interface. Estimates of molecular order parameters for the strongly bound species indicate that it is located with its long molecular axis approximately parallel to the director for ordering of the fatty acyl chains. A small increase in lipid ordering by tetracaine is observed at low pH, as evidenced by 2H NMR of the deuterated N-methyl groups of phosphatidylcholine; the reverse occurs at high pH.