γ-Irradiation Damage to Liposomes Differing in Composition and Their Protection by Nitroxides

The present study aims to determine the effect of bilayer composition on oxidative damage and the protection against it in lipid multicomponent membranes. Irradiation damage in 200-nm liposomes and the protection provided by the nitroxide radicals, 2,2,6,6-tetramethylpiperidine-1-oxyl (Tempo) and 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl (Tempol) were assessed by monitoring several chemical and physical parameters. Liposomes were prepared in four different lipid compositions (mole ratios), DPPC:DPPG 10:1; DPPC:DPPG:cholesterol 10:1:4; EPC:EPG 10:1; and EPC:EPG:cholesterol 10:1:4, and γ-irradiated with a dose of 32 kGy. Lipid degradation was determined by HPLC and GC analyses, whereas size and differential scanning calorimetry measurements were used to monitor physical changes in the liposomal dispersions. The results indicate that: (1) addition of 5 mM Tempo or Tempol, or freezing of the sample inhibited radiation-induced lipid degradation; (2) Tempo and Tempol caused neither physical nor chemical changes in the liposomal dispersions; and (3) both nitroxides prevented or reduced some of the radiation-induced changes in thermotropic characteristics of the liposomes, preventing a shift in the temperature of the maximum of the main phase transition (T_m).     

Ph-Sensitive Liposomes: Structural Characterization and Possible Therapeutic Applications

Abstract

The definition of liposomal preparations where sensitivity to moderate drops of pH (i.e. from 7.4 to 6.8) can be induced by the presence of plasma itself has been investigated. Liposome stability was monitored using 5,6-carboxyfluorescein (CF). We used sulfatide as the pH sensitive molecule on the basis of our previous studies in which we demonstrated an enhanced anti-tumor activity against a transplantable metastatic tumor model for ADM entrapped liposomes containing sulfatide. The amount of CF released at pH 6.8 in the presence of 50% plasma from small unilamellar vesicles (SUV), composed of egg phosphatidylcholine (EPC) and bovine brain sulfatide (CS) (4:1 m/m), was 3-fold that at pH 7.4, whereas no significant differences were observed when the same liposomes were incubated in buffer at 7.4 and 6.8 respectively. The plasma dependent pH sensitivity of these liposomes seems to specifically depend on the presence of sulfatide in the bilayer since neither cholesterol 3 sulfate (Choi 3S) nor galactocerebroside, are able to induce pH sensitivity in EPC liposomes. Of all the plasma components considered, VLDL seemed preferentially involved in the pH sensitivity induced by CS since they promoted an almost complete release of CF from EPC-CS liposomes at pH 6.8.     

Interaction of digitonin and its analogs with membrane cholesterol

The interaction of digitonin with membrane cholesterol was studied by using various digitonin analogs, and radioactive desglucodigitonin. The following results were obtained concerning the effect of digitonin on erythrocytes, granulocytes and liposomes. Digitonin and its analogs showed activity to induce hemolysis, granulocyte activation and liposomal membrane damage. The activity was affected by change of the carbohydrate residue of the molecule; the order of hemolytic activity was digitonin greater than or equal to desglucodigitonin much greater than glucosyl-galactosyl-digitogenin greater than galactosyl-digitogenin, digitogenin. The relative activities of these compounds to induce granulocyte activation and liposomal membrane damage were similar to those observed in the hemolysis. [3H]Desglucodigitonin could bind to cholesterol in liposomes. The binding was stoichiometric and the ratio of desglucodigitonin bound to liposomes/cholesterol in liposomes was close to 1, irrespective of the cholesterol content in liposome. Damage to liposomes was, however, induced by desglucodigitonin only when they contained more than 0.2 molar ratio of cholesterol to phospholipid. Addition of digitonin as well as desglucodigitonin to preformed liposomes deprived of cholesterol affected the anisotropic molecular motion of spin-labeled phosphatidylcholine incorporated into the liposomes, suggesting that the molecules could be inserted into the lipid bilayer free of cholesterol. Molecules of desglucodigitonin in the lipid phase may, however, be equilibrated with those in the aqueous phase, unless they form a complex with cholesterol, since no appreciable amount of [3H]desglucodigitonin could be detected in the liposome fraction after separation by column chromatography. Digitonin decreased the order parameter of spin-labeled phosphatidylcholine when liposomes contained equimolar cholesterol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stabilization of liposome bilayers to freezing and thawing: Effects of cryoprotective agents and membrane proteins

Lipid bilayer vesicles (liposomes) with and without glycoprotein incorporated into the membranes were tested for stability during freezing and thawing, in presence and absence of the cryoprotective agents (CPA) glycerol and dimethyl sulfoxide. Changes in turbidity and loss of energy transfer between fluorescent probes present in the bilayers were used to estimate membrane integrity.Freezing caused a 30 to 40% destruction of protein-free liposomes, in absence of CPA. CPA at 10 to 20% concentration prevented such losses, but at higher concentrations destabilized liposomes even without freezing. Protein-containing liposomes suffered no loss on freezing in absence or presence of CPA at moderate concentrations.Lowering of the storage temperature of frozen samples within the range of ?5 to ?27 °C increased the freeze damage. Slower rates of cooling and warming caused a slightly greater loss.The results are interpreted in terms of the liquid mosaic model for lipid bilayers. CPA at higher concentrations destabilize bilayers by dissolving phospholipids. At moderate concentrations, however, they prevent the damaging effect of dehydration of the lipid on freezing. Proteins appear to stabilize bilayers by providing increased hydration at the membrane surface, and by additional hydrophobic binding in the membrane interior.     

The Effect of Cholesterol in the Liposome Bilayer on the Stabilization of Incorporated Retinol

The effect of cholesterol in the liposome bilayer on the stability of incorporated retinol was studied. Retinol was incorporated into liposomes containing soybean phosphatidylcholine (PC) and cholesterol (CH) at various ratios, and the liposomes were prepared as multilamellar vesicles by the dehydration–rehydration method. Retinol readily incorporated into liposomes at a ratio of 0.01:1 (w/w) retinol:lipid, with over 94.52% being incorporated in all conditions studied. The incorporation efficiency of retinol increased slightly with increasing CH content in the liposome and with increasing pH of the hydration buffer. Average particle size increased as the CH content increased, and mean particle sizes at pH 5, 7, and 9 were 30.27, 89.53, and 41.42 µm, respectively. The time course of retinol degradation in aqueous solution in liposomes with various ratios of PC to CH was determined under a variety of pH conditions (pH 5, 7, and 9), and temperatures (4, 25, 37, and 50°C). The stability of incorporated retinol was enhanced by increasing the CH content. At pH 7.0 and 4°C, for example, 90.17% of the retinol in liposomes containing 50:50 (PC:CH) remained after 10 days of storage, whereas 51.46% remained at 100:0 (PC:CH). These results indicate that CH in liposomes greatly increases the incorporation efficiency of retinol and the stability of incorporated retinol.     

The effect of cholesterol in the liposome bilayer on the stabilization of incorporated Retinol

The effect of cholesterol in the liposome bilayer on the stability of incorporated retinol was studied. Retinol was incorporated into liposomes containing soybean phosphatidylcholine (PC) and cholesterol (CH) at various ratios, and the liposomes were prepared as multilamellar vesicles by the dehydration-rehydration method. Retinol readily incorporated into liposomes at a ratio of 0.01:1 (w/w) retinol:lipid, with over 94.52% being incorporated in all conditions studied. The incorporation efficiency of retinol increased slightly with increasing CH content in the liposome and with increasing pH of the hydration buffer. Average particle size increased as the CH content increased, and mean particle sizes at pH 5, 7, and 9 were 30.27, 89.53, and 41.42 microm, respectively. The time course of retinol degradation in aqueous solution in liposomes with various ratios of PC to CH was determined under a variety of pH conditions (pH 5, 7, and 9), and temperatures (4, 25, 37, and 50 degrees C). The stability of incorporated retinol was enhanced by increasing the CH content. At pH 7.0 and 4 degrees C, for example, 90.17% of the retinol in liposomes containing 50:50 (PC:CH) remained after 10 days of storage, whereas 51.46% remained at 100:0 (PC:CH). These results indicate that CH in liposomes greatly increases the incorporation efficiency of retinol and the stability of incorporated retinol.     

The potential of pectin as a stabilizer for liposomal drug delivery systems

The aim of the present study was to investigate the potential of different types of pectin as stabilizers for liposomal drug delivery systems. Positively charged liposomes were coated with commercially available and purified low-methoxylated (LM), high-methoxylated (HM) and amidated (AM) pectins. The samples were stored for up to 12 weeks at 4°C, at room temperature and at 35°C. The change in liposomal size and size distribution, zeta potential, pH, leakage of encapsulated carboxyfluorescein (CF), and lipid degradation were studied. All the types of pectin were found to protect the liposomes against aggregation during storage. The pectin coat did not affect the permeability of the liposome membrane. HM and LM pectin seemed to be the most promising types of pectin due to minimal changes in the zeta potentials during storage for these samples and no detectable lipid degradation. It is concluded that pectin may be used for stabilizing liposomal drug delivery systems.     

Liposomes composed of unsaturated lipids for membrane modification of human erythrocytes

Previous studies have shown that certain saturated lipids protect red blood cells (RBCs) during hypothermic storage but provide little protection during freezing or freeze-drying, whereas various unsaturated lipids destabilize RBCs during hypothermic storage but protect during freezing and freeze-drying. The protective effect of liposomes has been attributed to membrane modifications. We have previously shown that cholesterol exchange and lipid transfer between liposomes composed of saturated lipids and RBCs critically depends on the length of the lipid acyl chains. In this study the effect of unsaturated lipids with differences in their number of unsaturated bonds (18:0/18:1, 18:1/18:1, 18:2/18:2) on RBC membrane properties has been studied. RBCs were incubated in the presence of liposomes and both the liposomal and RBC fraction were analyzed by Fourier transform infrared spectroscopy (FTIR) after incubation. The liposomes caused an increase in RBC membrane conformational disorder at suprazero temperatures. The fluidizing effect of the liposomes on the RBC membranes, however, was found to be similar for the different lipids irrespective of their unsaturation level. The gel to liquid crystalline phase transition temperature of the liposomes increased after incubation with RBCs. RBC membrane fluidity increased linearly during the first 8 hours of incubation in the presence of liposomes. The increase in RBC membrane fluidity was found to be temperature dependent and displayed Arrhenius behaviour between 20 and 40°C, with an activation energy of 88 kJ mol?1. Taken together, liposomes composed of unsaturated lipids increase RBC membrane conformational disorder, which could explain their cryoprotective action.     

Effect of cholesterol in various liposomal compositions on the in vivo toxicity, therapeutic efficacy, and tissue distribution of amphotericin B

The effect of cholesterol in neutral, positively and negatively charged liposomes on the toxicity, therapeutic efficacy, and alteration in the tissue distribution pattern of amphotericin B (Amp-B) in normal and infected mice was studied. It was observed that inclusion of cholesterol (CHOL) into egg phosphatidylcholine (EPC) liposomes increased the LD50 of Amp-B from 5.3 to 8.5 mg/kg body weight. In the case of phosphatidylserine (PS) liposomes as well as stearylamine (SA) liposomes, cholesterol incorporation had no effect in altering the toxicity of the drug. The survival pattern of animals with all types of liposomal formulation of Amp-B was similar. The tissue distribution studies indicated that in the case of normal mice, cholesterol inclusion in all types of liposomes increased the organ concentration of the drug in various tissues. In infected animals, the concentration of Amp-B in all organs was increased when cholesterol was included in EPC and EPC/PS liposomes. The organ concentration of Amp-B in lung and liver after 1 h of injection was the same in the case of EPC/SA and EPC/SA/CHOL liposomes. Considering the observations on toxicity, therapeutic efficacy, and tissue distribution, it was suggested that cholesterol had a beneficial therapeutic effect on neutral EPC liposomes.     

Effects of PEG-lipids on permeability of phosphatidylcholine/cholesterol liposomes in buffer and in human serum

The permeability of liposomal membranes was studied as a function of the amount of incorporated PEG-lipid. The fluorescent dyes ethidium, propidium and 5(6)-carboxy fluorescein were used as markers for measurements of spontaneous leakage. The results show that addition of up to 8 mol% of PEG(2000)-DSPE into liposomal membranes of DSPC/Cho and EPC/Cho reduces the permeability of carboxyfluorescein in buffer solution. In contrast, the leakage of the more amphiphilic dye ethidium was not to any measurable extent affected by PEG-lipid inclusion. Another important difference was that ethidum leakage showed a clear dependence on temperature whereas leakage of carboxyfluorescein from pegylated liposomes did not. We conclude that the mechanisms by which the two dyes permeate the liposomal bilayer are qualitatively different. Both ethidium and carboxyfluorescein did interact with human serum components in a way that made measurements in serum unreliable. The more hydrophilic ethidium analogue propidium was shown not to interact with human serum components to any detectable extent. This made propidium suitable for permeability determinations in human serum. It was found that liposomes composed of pure EPC or EPC with 5 mol% DSPE-PEG, displayed a dramatic increase in permeability when subjected to a medium composed of 20% human serum in buffer. Addition of 40 mol% cholesterol to the EPC bilayers reduced the observed release rate in human serum substantially, whereas no stabilizing effect was observed upon PEG-lipid inclusion.     

Stable Nitroxide Radicals Protect Lipid Acyl Chains From Radiation Damage

The present study focused on protective activity of two six-membered-ring nitroxide radicals, 2,2,6,6-tetramethylpiperidine-1-oxyl (Tempo) and 4-hydroxy-Tempo (Tempol), against radiation damage to acyl chain residues of egg phosphatidylcholine (EPC) of small unilamellar vesicles (SUV). SUV were -irradiated (10–12 kGy) under air at ambient temperature in the absence and presence of nitroxides. Acyl chain composition of the phospholipids before and after irradiation was determined by gas chromatography. Both Tempo and Tempol effectively and similarly protected the acyl chains of EPC SUV, including the highly sensitive polyunsaturated acyl chains, C20:4, C22:5, and C22:6. The conclusions of the study are: (a) The higher the degree of unsaturation in the acyl chain, the greater is the degradation caused by irradiation. (b) The fully saturated fatty acids palmitic acid (C16) and stearic acid (C18) showed no significant change in their levels. (c) Both Tempo and Tempol provided similar protection to acyl chain residues. (d) Nitroxides' lipid-bilayer/aqueous distribution is not validly represented by their n-octanol/saline partition coefficient. (e) The lipid-bilayer/aqueous partition coefficient of Tempo and Tempol cannot be correlated with their protective effect. (f) The nitroxides appear to protect via a catalytic mode. Unlike common antioxidants, such as -tocopherol, which are consumed under irradiation and are, therefore, less effective against high radiation dose, nitroxide radicals are restored and terminate radical chain reactions in a catalytic manner. Furthermore, nitroxides neither yield secondary radicals upon their reaction with radicals nor act as prooxidants. Not only are nitroxides self-replenished, but also their reduction products are effective antioxidants. Therefore, the use of nitroxides offers a powerful strategy to protect liposomes, membranes, and other lipid-based assemblies from radiation damage. © 1997 Elsevier Science Inc.     

Radiation-induced changes in permeability in unilamellar phospholipid liposomes

Gamma-radiation-induced oxidative damage in unilamellar dipalmitoylphosphatidylcholine liposomes was investigated using a fluorescence technique. Liposomal changes in permeability induced by gamma radiation were monitored by measuring the leakage of pre-encapsulated 6-carboxyfluorescein, and alterations in lipid bilayer fluidity were determined by 1,6-diphenyl-1,3,5-hexatriene fluorescence polarization. The changes in permeability and fluidity in the bilayer were found to be dependent on the radiation dose in a biphasic fashion. The results are interpreted in terms of lipid bilayer fluidization after exposure to doses up to 1 kGy, but rigidization of the bilayer at higher doses. These results indicate a relationship between alterations in permeability and fluidity in the lipid bilayer after irradiation. The vesicles were protected significantly against radiation-induced oxidative damage in the presence of alpha-tocopherol and ascorbic acid. Radiation-induced changes in the permeability of the liposomes after exposure to gamma radiation and their modification by antioxidants indicate the involvement of a free radical mechanism in the production of damage, which may offer new insights in to the modification of cellular radiosensitivity by modulation of membrane damage.     

Interaction of Sindbis virus with liposomal model membranes.

Radiolabeled Sindbis virus was found to bind to protein-free lipid model membranes (liposomes) derived from extracts of sheep erythrocytes. The virus interaction was dependent on initial pH, and the range of pH dependence (pH 6.0 to 6.8) was the same as the observed with virus-dependent hemagglutination. After the initial interaction, pH changes no longer influenced the virus binding to liposomes. Virus bound to liposomes prepared from a mixture of erythrocyte phospholipids, but the binding was greatly diminished when either cholesterol or phosphatidylethanolamine was omitted from the liposomal lipid mixture. It was concluded that phospholipids and cholesterol, in a bilayer configuration, may be sufficient for specific virus binding in the absence of membrane protein.     

Liposomes composed of unsaturated lipids for membrane modification of human erythrocytes

Abstract

Previous studies have shown that certain saturated lipids protect red blood cells (RBCs) during hypothermic storage but provide little protection during freezing or freeze-drying, whereas various unsaturated lipids destabilize RBCs during hypothermic storage but protect during freezing and freeze-drying. The protective effect of liposomes has been attributed to membrane modifications. We have previously shown that cholesterol exchange and lipid transfer between liposomes composed of saturated lipids and RBCs critically depends on the length of the lipid acyl chains. In this study the effect of unsaturated lipids with differences in their number of unsaturated bonds (18:0/18:1, 18:1/18:1, 18:2/18:2) on RBC membrane properties has been studied. RBCs were incubated in the presence of liposomes and both the liposomal and RBC fraction were analyzed by Fourier transform infrared spectroscopy (FTIR) after incubation. The liposomes caused an increase in RBC membrane conformational disorder at suprazero temperatures. The fluidizing effect of the liposomes on the RBC membranes, however, was found to be similar for the different lipids irrespective of their unsaturation level. The gel to liquid crystalline phase transition temperature of the liposomes increased after incubation with RBCs. RBC membrane fluidity increased linearly during the first 8 hours of incubation in the presence of liposomes. The increase in RBC membrane fluidity was found to be temperature dependent and displayed Arrhenius behaviour between 20 and 40°C, with an activation energy of 88 kJ mol^-1. Taken together, liposomes composed of unsaturated lipids increase RBC membrane conformational disorder, which could explain their cryoprotective action.     

Lipid composition determines the effects of arbutin on the stability of membranes.

Arbutin (hydroquinone-beta-D-glucopyranoside) is an abundant solute in the leaves of many freezing- or desiccation-tolerant plants. Its physiological role in plants, however, is not known. Here we show that arbutin protects isolated spinach (Spinacia oleracea L.) thylakoid membranes from freeze-thaw damage. During freezing of liposomes, the presence of only 20 mM arbutin led to complete leakage of a soluble marker from egg PC (EPC) liposomes. When the nonbilayer-forming chloroplast lipid monogalactosyldiacylglycerol (MGDG) was included in the membranes, this leakage was prevented. Inclusion of more than 15% MGDG into the membranes led to a strong destabilization of liposomes during freezing. Under these conditions arbutin became a cryoprotectant, as only 5 mM arbutin reduced leakage from 75% to 20%. The nonbilayer lipid egg phosphatidylethanolamine (EPE) had an effect similar to that of MGDG, but was much less effective, even at concentrations up to 80% in EPC membranes. Arbutin-induced leakage during freezing was accompanied by massive bilayer fusion in EPC and EPC/EPE membranes. Twenty percent MGDG in EPC bilayers completely inhibited the fusogenic effect of arbutin. The membrane surface probes merocyanine 540 and 2-(6-(7-nitrobenz-2-oxa-1, 3-diazol-4-yl)amino)hexanoyl-1-hexadecanoyl-sn-glycero-3-phosph ocholi ne (NBD-C(6)-HPC) revealed that arbutin reduced the ability of both probes to partition into the membranes. Steady-state anisotropy measurements with probes that localize at different positions in the membranes showed that headgroup mobility was increased in the presence of arbutin, whereas the mobility of the fatty acyl chains close to the glycerol backbone was reduced. This reduction, however, was not seen in membranes containing 20% MGDG. The effect of arbutin on lipid order was limited to the interfacial region of the membranes and was not evident in the hydrophobic core region. From these data we were able to derive a physical model of the perturbing or nonperturbing interactions of arbutin with lipid bilayers.     

Modulation of the interbilayer hydration pressure by the addition of dipoles at the hydrocarbon/water interface.

The effects of the cholesterol analog 5 alpha-cholestan-3 beta-ol-6-one (6-ketocholestanol) on bilayer structure, bilayer cohesive properties, and interbilayer repulsive pressures have been studied by a combination of x-ray diffraction, pipette aspiration, and dipole potential experiments. It is found that 6-ketocholestanol, which has a similar structure to cholesterol except with a keto moiety at the 6 position of the B ring, has quite different effects than cholesterol on bilayer organization and cohesive properties. Unlike cholesterol, 6-ketocholestanol does not appreciably modify the thickness of liquid-crystalline egg phosphatidylcholine (EPC) bilayers, and causes a much smaller increase in bilayer compressibility modulus than does cholesterol. These data imply that 6-ketocholestanol has both its hydroxyl and keto moieties situated near the water-hydrocarbon interface, thus making its orientation in the bilayer different from cholesterol's. The addition of equimolar 6-ketocholestanol into EPC bilayers increases the magnitude, but not the decay length, of the exponentially decaying repulsive hydration pressure between adjacent bilayers. Incorporation of equimolar 6-ketocholestanol into EPC monolayers increases the dipole potential by approximately 300 mV. These data are consistent with our previous observation that the magnitude of the hydration pressure is proportional to the square of the dipole potential. These results mean that 6-ketocholestanol, despite its location in the bilayer hydrocarbon region, approximately 10 A from the physical edge of the bilayer, modifies the organization of interlamellar water. We argue that the incorporation of 6-ketocholestanol into EPC bilayers increases the hydration pressure, at least in part, by increasing the electric field strength in the polar head group region.     

Stabilization of large multilamellar liposomes by human serum in vitro

The leakage of 5,6-carboxyfluorescein from large multilamellar liposomes prepared from dipalmitoylphosphatidylcholine (without or with cholesterol) was investigated in vitro in the presence of human serum. Below the phospholipid phase transition temperature, the rate of dye release is retarted 3–8-fold in the presence of up to 25% human serum in the incubation medium, as compared to the release in isotonic phosphate-buffered saline. This effect is significantly augmented by incorporation of 50 mol% cholesterol into the lipid bilayer. At and above the phase transition temperature, the initial rapid dye leakage in the presence of serum is followed by a slow long-term release. Incubation of the liposomes with serum is assumed to result in the association of serum proteins with the outermost lipid bilayer which in turn will lead to their stabilization, while the inner lamellae are not immediately accessible to the serum proteins. The permeability of the outer protein-rich lipid bilayer appears to be restricted, as concluded from the decreased dye release in the presence of serum. Massive leakage from multilamellar liposomes appears to be primarily due to bilayer defects occurring in the lipid transition region rather than being caused by protein-lipid interactions. The results of our in vitro experiments are discussed in terms of the potential usefulness of multilamellar liposomes as drug carriers in vivo for local and topical applications.     

Optimization of drug loading to improve physical stability of paclitaxel-loaded long-circulating liposomes

Abstract

The effect of formulation and process parameters on drug loading and physical stability of paclitaxel-loaded long-circulating liposomes was evaluated. The liposomes were prepared by hydration–extrusion method. The formulation parameters such as total lipid content, cholesterol content, saturated–unsaturated lipid ratio, drug–lipid ratio and process parameters such as extrusion pressure and number of extrusion cycles were studied and their impact on drug loading and physical stability was evaluated. A proportionate increase in drug loading was observed with increase in the total phospholipid content. Cholesterol content and saturated lipid content in the bilayer showed a negative influence on drug loading. The short-term stability evaluation of liposomes prepared with different drug–lipid ratios demonstrated that 1:60 as the optimum drug–lipid ratio to achieve a loading of 1–1.3?mg/mL without the risk of physical instability. The vesicle size decreased with an increase in the extrusion pressure and number of extrusion cycles, but no significant trends were observed for drug loading with changes in process pressure or number of cycles. The optimization of formulation and process parameters led to a physically stable formulation of paclitaxel-loaded long-circulating liposomes that maintain size, charge and integrity during storage.     

Synergistic interaction between vitamin E and the bile pigments bilirubin and biliverdin

The oxidation of soybean phosphatidylcholine (PC) liposomes initiated with a lipid-soluble azo compound within the liposomal membranes has been studied in the absence and presence of membrane-bound vitamin E and water-soluble bile pigments. In the absence of vitamin E, lipid peroxidation proceeded linearly and without delay. Low micromolar amounts of bilirubin ditaurine (BR-DT, a model compound of conjugated bilirubin) or biliverdin (BV) inhibited the oxidation of PC significantly and in a concentration-dependent way. In contrast, neither taurine, ascorbic acid nor reduced glutathione inhibited significantly under these conditions. Both bile pigments were consumed during their protective action. Vitamin E incorporated into the liposomal membranes suppressed the oxidation initially almost completely, thereby producing an induction period. In the combined presence of vitamin E and either of the two bile pigments at 10 microM each, this induction period was increased by at least 200%. In contrast, when 10 microM vitamin E was combined with an equimolar concentration of reduced glutathione, the induction period increased by only about 30%. BR-DT and BV both spared the consumption of vitamin E during the oxidation of PC liposomes. These results demonstrate that conjugated bilirubin and BV located in the aqueous phase can directly scavenge lipid radicals to some extent. Furthermore, both bile pigments can act synergistically with membrane-bound vitamin E to prevent lipid peroxidation initiated in the lipid phase, most likely through regeneration of the vitamin from its chromanoxyl radical.     

Structure of planar membrane formed from liposomes

Lipid vesicles with incorporated ion channels from polyene antibiotic amphotericin B were used to investigate structures of planar membranes formed by Shindler's techniques. A planar membrane assembled on the aperture in a lavsan film from two layers generated at the air-aqueous liposome suspension interface is not a simple bilayer but a bimolecular membrane containing numerous partly fused liposomes. A complete fusion of liposomal membranes with the planar bilayer is an unlikely event during membrane formation. A planar bimolecular lipid membrane without incorporated liposomes can be made by a method consisting of three stages: formation of a lipid layer on the air-water interface of a suspension containing liposomes, transfer of this layer along the surface of the solution into a chamber containing a solution without liposomes where a lipid monomolecular layer forms gradually (within about 20 min) at the air-water interface, assembling of the planar bilayer membrane from this monolayer. The knowledge of the planar membrane structure may be useful in experiments on incorporation of membrane proteins into a planar lipid bilayer.