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.     

Liposome,gel and lipogelosome formulations containing sodium hyaluronate

The moisture-imparting effect of sodium hyaluronate (Na-HA) was investigated in liposome, gel and lipogelosome topical formulations. Sixteen liposome formulations were prepared with or without Na-HA (45?kDa) using various ratios of dimyristoylphosphatidylcholine, 1,2-dimyristoyl-sn-glycero-3-phosphatidylglycerol, dipalmitoylphosphatidylcholine and phospholipon 100H. The liposomes were characterized in terms of their structure, composition, zeta potential, Na-HA-entrapment capacity and stability. In particular, scanning electron microscopy, polarized light microscopy, dynamic light scattering and atomic force microscopy were utilized to probe appearance, size and size distribution and lamellarity. The work was then extended to gels using the gelling agents poloxamer (PXM 188 or 407) and Carbopol or Ultrez 21 (U-21), yielding liposome-loaded gel formulations (i.e. lipogelosomes). The in vitro release kinetics of Na-HA from liposomes, lipogelosomes and commercial Na-HA reference formulations were studied via a flow-through cell method. Among the liposomal formulations tested, L6, comprising of Na-HA-loaded phospholipon 100H:stearylamine:cholesterol (7:1:2), displayed optimal traits. The mean particle size, zeta potential and entrapment capacity of L6 were determined as 1900?nm, ?20.9?mV and 15.0%. The optimum lipogelosome, LG4, was obtained by incorporating liposome L6 into a U-21 gel at a ratio of 1:1 (w/w). In clinical trials, in-house formulations were applied twice daily to 15 female volunteers. The two-week benefits were assessed against a commercial product; and in all cases, changes of skin humidity, sebum content, pH and wrinkle depth were promising. In particular, the LG4 lipogelosome-based formulation had significantly improved skin hydration and compliance, as evidenced by a moisture content gain of 30.4%.     

In vitro characterization of a novel polymeric-based pH-sensitive liposome system

This study demonstrates rapid and pH-sensitive release of a highly water-soluble fluorescent aqueous content marker, pyranine, from egg phosphatidylcholine liposomes following incorporation of N-isopropylacrylamide (NIPA) copolymers in liposomal membranes. The pH-sensitivity of this system correlates with the precipitation of the copolymers at acidic pH. In vitro release can be significantly improved by increasing the percentage of anchor in the copolymer and thus favoring its binding to the liposomal bilayer. In the case of liposomes containing a poly(ethylene glycol)-phospholipid conjugate, the insertion of the pH-sensitive copolymer in the liposomal membrane appears to be sterically inhibited. Dye release from these formulations at acidic pH can still be achieved by varying the anchor molar ratio and/or molecular mass of the polymers or by including the latter during the liposome preparation procedure. Removal of unbound polymer results in decreased leakage only when the copolymer is inserted by incubation with preformed liposomes, but can be overcome by preparing liposomes in the presence of polymer. Aqueous content and lipid mixing assays suggest contents release can occur without membrane fusion. The results of this study indicate that the addition of pH-sensitive copolymers of NIPA represents promising strategy for improving liposomal drug delivery.     

Aerosol Performance and Long-Term Stability of Surfactant-Associated Liposomal Ciprofloxacin Formulations with Modified Encapsulation and Release Properties

Previously, we showed that the encapsulation and release properties of a liposomal ciprofloxacin formulation could be modified post manufacture, by addition of surfactant in concert with osmotic swelling of the liposomes. This strategy may provide more flexibility and convenience than the alternative of manufacturing multiple batches of liposomes differing in composition to cover a wide range of release profiles. The goal of this study was to develop a surfactant-associated liposomal ciprofloxacin (CFI) formulation possessing good long-term stability which could be delivered as an inhaled aerosol. Preparations of 12.5 mg/ml CFI containing 0.4% polysorbate 20 were formulated between pH 4.7 and 5.5. These formulations, before and after mesh nebulization, and after refrigerated storage for up to 2 years, were characterized in terms of liposome structure by cryogenic transmission electron microscopy (cryo-TEM) imaging, vesicle size by dynamic light scattering, pH, drug encapsulation by centrifugation-filtration, and in vitro release (IVR) performance. Within the narrower pH range of 4.9 to 5.2, these formulations retained their physicochemical stability after 2-year refrigerated storage, were robust to mesh nebulization, and formed respirable aerosols with a volume mean diameter (VMD) of 3.7 μm and a geometric standard deviation (GSD) of 1.7. This study demonstrates that it may be possible to provide a range of release profiles by simple addition of surfactant to a liposomal formulation post manufacture, and that these formulations may retain their physicochemical properties after long-term refrigerated storage and following aerosolization by mesh nebulizer.KEY WORDS: ciprofloxacin, drug delivery, liposome, nebulized aerosol, surfactant     

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.     

Damage to liposomal lipids: protection by antioxidants and cholesterol-mediated dehydration

Liposomes composed of egg phosphatidylcholine (EPC) (13.4%, of the acyl chains being polyunsaturated fatty acids (PUFA)) and EPC/cholesterol (10:1 mol/mol) were studied for factors that affect liposomal lipid oxidative damage and hydrolysis upon long-term (16 months) storage. Factors studied include: (1) levels of lipid/water interface hydration, related to the presence of cholesterol in the lipid bilayer; (2) the membrane-associated antioxidant vitamin E; (3) the water-soluble antioxidant Tempol; and (4) exposure to light. Liposomal dispersions were stored at room temperature, either exposed to or protected from daylight, for a period of 16 months. Chemical and physical changes were monitored at several time points to assess oxidative and hydrolytic degradation of liposomal lipids. The conclusions of the study are: (1) PUFA are the most sensitive component of the liposome bilayer to oxidative degradation damage during long-term storage; (2) EPC liposomes are more sensitive to degradation during storage than EPC cholesterol liposomes, the presence of cholesterol in the lipid bilayer having a protective effect, probably due to its effect in decreasing the lipid-bilayer hydration; (3) oxidative degradation is the major process during long-term storage, having an earlier onset than the hydrolytic degradation: and (4) Tempol provided significantly better protection than vitamin E to EPC liposomal PUFA against oxidative damage during long-term storage. The relevance of cholesterol's presence, as a 'drying agent', in membranes containing PUFA to resistance of biological membranes to oxidative damage is discussed.     

Liposomes with Metronidazole for Topical Use: The Choice of Preparation Method and Vehicle

Abstract

Liposomes containing metronidazole were prepared for the treatment of skin disorder Rosacea. To optimize the composition and size of liposomes, natural and synthetic lipids were used in three different preparation methods. Optimal liposomal preparation was incorporated into five dermal vehicles (three O/W emulsion creams and two gels) and vehicles tested for the stability (at 20 and 40 °C) during a storage period of 4 weeks. The evaluation of the vehicles was based on the comparison between the original size distribution of liposomes and liposomes in vehicles (after 4 weeks) and on the rheological behaviour. The best vehicle appears to be the Carbopol? gel, in which the liposomal size stayed unchanged even at 40 °C during the 4 weeks period.     

Liposomal dry powders as aerosols for pulmonary delivery of proteins

The purpose of this research was to develop liposomal dry powder aerosols for protein delivery. The delivery of stable protein formulations is essential for protein subunit vaccine delivery, which requires local delivery to macrophages in the lungs. β-Glucuronidase (GUS) was used as a model protein to evaluate dry powder liposomes as inhaled delivery vehicles. Dimyristoyl phosphatylcholine:cholesterol (7∶3) was selected as the liposome composition. The lyophilization of liposomes, micronization of the powders, aerosolization using a dry powder inhaler (DPI), and in vitro aerodynamic fine particle fraction upon collection in a twinstage liquid impinger were evaluated. After lyophilization and jet-milling, the total amount of GUS and its activity, representing encapsulation efficiency and stability, were evaluated. The GUS amount and activity were measured and compared with freshly-prepared liposomes in the presence of mannitol, 43% of initial GUS amount, 29% of GUS activity after lyophilization and 36% of GUS amount, 22% of activity after micronization were obtained. Emitted doses from dry powder inhaler were 53%, 58%, 66%, and 73% for liposome powder:mannitol carrier ratios of 1∶0, 1∶4, 1∶9, and 1∶19. Fifteen percent of the liposome particles were less than 6.4 μm in aerodynamic diameter. The results demonstrate that milled liposome powders containing protein molecules can be aerosolized effectively at a fixed flow rate. Influences of different cryoprotectants on lyophilization of protein liposome formulations are reported. The feasibility of using liposomal dry powder aerosols for protein delivery has been demonstrated but further optimization is required in the context of specific therapeutic proteins. Published: December 21, 2005     

Mechanism of pH-triggered collapse of phosphatidylethanolamine liposomes stabilized by an ortho ester polyethyleneglycol lipid

The mechanism of pH-triggered destabilization of liposomes composed of a polyethyleneglycol-orthoester-distearoylglycerol lipid (POD) and phosphatidyl ethanolamine (PE) has been studied using an ANTS/DPX leakage and a lipid-mixing assay. We developed a kinetic model that relates POD hydrolysis to liposome collapse. This minimum-surface-shielding model describes the kinetics of the pH-triggered release of POD/PE liposomes. In the model, when acid-catalyzed hydrolysis lowers the mole percentage of POD on the liposome surface to a critical level, intervesicular lipid mixing is initiated, resulting in a burst of contents release. Two phases of content leakage are observed: a lag phase and a burst phase. During the lag phase, less than 20% of liposomal contents are released and the leakage begins to accelerate when approaching to the transition point. During the burst phase, the leakage rate is dependent on interbilayer contact. The burst phase occurs when the surface density of the PEG lipid is 2.3 +/- 0.6 mol%, regardless of the pH. Vesicles containing 4 mol% of a pH-insensitive PEG-lipid conjugate and 10% POD did not leak contents or collapse at any pH. These data are consistent with the stalk theory to describe the lamellar-to-inverted hexagonal phase transition and set a lower bound of approximately 16 PE lipids on the external monolayer as the contact site required for lipid mixing between two bilayers.     

Improved Encapsulation of DNA in pH-Sensitive Liposomes for Transfection

Abstract

A simple method has been developed to prepare liposomes containing large amounts of DNA. The procedure consisted of three cycles of freeze-thawing a mixture of sonicated liposomes and DNA. The encapsulation efficiency depended on the size of DNA. For a small plasmid (2.7 kb), approximately 40% of input DNA was entrapped with an efficiency of 16 μgDNA/μmol lipid. For larger plasmids, the encapsulation efficiency decreased considerably. Transfection of cultured mouse L929 cells mediated by the DNA-containing liposomes was assayed with a plasmid containing the E. coli chloramphenicol acetyl transferase gene. The transfection activity of the liposome was primarily determined by its pH sensitivity. Acid-sensitive liposomes transfected cells efficiently, whereas pH-insensitive liposomes were much less active. The level of the expression of the exogenous gene in the treated cells could be further modulated by protein kinase C (PKC) activators that were incorporated into the liposomal membrane as a minor lipid component. Transfection conditions were optimized with respect to DNA, lipid, and PKC activator concentrations. The results of the current study may help the use of liposomal delivery system for applications in gene therapy.     

Liposomal Delivery Systems for Encapsulation of Ferrous Sulfate: Preparation and Characterization

Liposomal delivery systems for water-soluble bioactives were prepared using the pro-liposome and the microfluidization technologies. Iron, an essential micronutrient as ferrous sulfate and ascorbic acid, as an antioxidant for iron were encapsulated in the liposomes. Liposomes prepared by the microfluidization technology using 6% (w/w) concentration of the lipid encapsulated with ferrous sulfate and ascorbic acid had particle size distributions around 150 to 200 nm, whereas liposomes from the pro-liposome technology resulted in particle sizes of about 5 μm. The encapsulation efficiency of ferrous sulfate was 58% for the liposomes prepared by the microfluidization using 6% (w/w) lipid and 7.5% of ferrous sulfate concentrations, and it was 11% for the liposomes from pro-liposome technology using 1.5% (w/v) lipid and 15% of ferrous-sulfate concentration. Both the liposomes exhibited similar levels of oxidative stability, demonstrating the feasibility of microfluidization-based liposomal delivery systems for large-scale food/nutraceutical applications.     

Formation of homogeneous unilamellar liposomes from an interdigitated matrix

Phospholipid-ethanol-aqueous mixtures containing bilayer-forming lipids and 20-50 wt.% of water form viscous gels. Further hydration of these gels results in the formation of liposomes whose morphology depends upon the lipid type. Upon hydration of gels containing mixtures of the lipids 1-palmitoyl-2-oleoyl-phosphatidylcholine (POPC) and 1-palmitoyl-2-oleoyl-phosphatidylglycerol (POPG), small homogeneous and unilamellar liposomes were produced. In contrast, hydration of gels containing only POPC resulted in formation of large multilamellar liposomes. Likewise, mulitlamellar liposomes resulted when this method was applied to form highly fusogenic liposomes comprised of the novel negatively charged N-acyl-phosphatidylethanolamine (NAPE) mixed with di-oleoyl-phosphatidylcholine (DOPC) (7:3) [T. Shangguan, C.C. Pak, S. Ali, A.S. Janoff, P. Meers, Cation-dependent fusogenicity of an N-acyl phosphatidylethanolamine, Biochim. Biophys. Acta 1368 (1998) 171-183]. In all cases, the measured aqueous entrapment efficiencies were relatively high. To better understand how the molecular organization of these various gels affects liposome morphology, we examined samples by freeze-fracture transmission electron microscopy and X-ray diffraction. We found that phospholipid-ethanol-water gels are comprised of highly organized stacks of lamellae. A distinct feature of the gel samples that result in small unilamellar liposomes is the combination of acyl chain interdigitation and net electrostatic charge. We speculate that the mechanism of unilamellar liposome formation proceeds via formation of stalk contacts between neighboring layers similar to membrane hemifusion intermediates, and the high aqueous entrapment efficiencies make this liposome formation process attractive for use in drug delivery applications.     

Formation of homogeneous unilamellar liposomes from an interdigitated matrix

Phospholipid-ethanol-aqueous mixtures containing bilayer-forming lipids and 20-50 wt.% of water form viscous gels. Further hydration of these gels results in the formation of liposomes whose morphology depends upon the lipid type. Upon hydration of gels containing mixtures of the lipids 1-palmitoyl-2-oleoyl-phosphatidylcholine (POPC) and 1-palmitoyl-2-oleoyl-phosphatidylglycerol (POPG), small homogeneous and unilamellar liposomes were produced. In contrast, hydration of gels containing only POPC resulted in formation of large multilamellar liposomes. Likewise, mulitlamellar liposomes resulted when this method was applied to form highly fusogenic liposomes comprised of the novel negatively charged N-acyl-phosphatidylethanolamine (NAPE) mixed with di-oleoyl-phosphatidylcholine (DOPC) (7:3) [T. Shangguan, C.C. Pak, S. Ali, A.S. Janoff, P. Meers, Cation-dependent fusogenicity of an N-acyl phosphatidylethanolamine, Biochim. Biophys. Acta 1368 (1998) 171-183]. In all cases, the measured aqueous entrapment efficiencies were relatively high. To better understand how the molecular organization of these various gels affects liposome morphology, we examined samples by freeze-fracture transmission electron microscopy and X-ray diffraction. We found that phospholipid-ethanol-water gels are comprised of highly organized stacks of lamellae. A distinct feature of the gel samples that result in small unilamellar liposomes is the combination of acyl chain interdigitation and net electrostatic charge. We speculate that the mechanism of unilamellar liposome formation proceeds via formation of stalk contacts between neighboring layers similar to membrane hemifusion intermediates, and the high aqueous entrapment efficiencies make this liposome formation process attractive for use in drug delivery applications.     

Liposomal delivery systems for encapsulation of ferrous sulfate: Preparation and characterization

Liposomal delivery systems for water-soluble bioactives were prepared using the pro-liposome and the microfluidization technologies. Iron, an essential micronutrient as ferrous sulfate and ascorbic acid, as an antioxidant for iron were encapsulated in the liposomes. Liposomes prepared by the microfluidization technology using 6% (w/w) concentration of the lipid encapsulated with ferrous sulfate and ascorbic acid had particle size distributions around 150 to 200 nm, whereas liposomes from the pro-liposome technology resulted in particle sizes of about 5 microm. The encapsulation efficiency of ferrous sulfate was 58% for the liposomes prepared by the microfluidization using 6% (w/w) lipid and 7.5% of ferrous sulfate concentrations, and it was 11% for the liposomes from pro-liposome technology using 1.5% (w/v) lipid and 15% of ferrous-sulfate concentration. Both the liposomes exhibited similar levels of oxidative stability, demonstrating the feasibility of microfluidization-based liposomal delivery systems for large-scale food/nutraceutical applications.     

Erratum to: “Effects of Gamma Irradiation on the Physical Stability of Liposomal Phospholipids” [J. Lipos. Res. 7, (1997) 503-528]

Abstract

The effects of liposome composition and gamma irradiation on the phase transition, size, zeta potential and pH were investigated using factorial designs. In addition, the effect of irradiation on the leak-in rate of calcein was evaluated for one of the liposome composition. The liposomes were stored for 6 months in order to reveal any possible long term effects. The phospholipids used were dipalmitoyl phosphatidyl choline (DPPC) or egg phosphatidyl choline (egg PC). Charge was introduced to the liposomal bilayers by the addition of 10% dipalmitoyl phosphatidyl glycerol (DPPG) or egg phosphatidyl glycerol (egg PG). The liposome-suspensions were obtained by the extrusion method. After gamma irradiation changes in the phase transition, zeta potential and pH of the liposomes were observed. The size of the liposomes was not affected by the irradiation, but the irradiation prevented the neutral DPPC-liposomes from aggregation. This was confirmed by cryo-electron microscopy. No change in the leak-in rate was observed. During storage, a significant increase in size was observed only for the non-irradiated egg PC-liposomes. For all the liposome-suspensions composed of unsaturated phospholipids, a significant drop in pH and an increased zeta potential (more negative) was measured. Changes in the phase transition for the neutral DPPC-liposomes (non-irradiated and irradiated) were observed during gamma irradiation.     

Novel vaginal drug delivery system: deformable propylene glycol liposomes-in-hydrogel

Deformable propylene glycol-containing liposomes (DPGLs) incorporating metronidazole or clotrimazole were prepared and evaluated as an efficient drug delivery system to improve the treatment of vaginal microbial infections. The liposome formulations were optimized based on sufficient trapping efficiencies for both drugs and membrane elasticity as a prerequisite for successful permeability and therapy. An appropriate viscosity for vaginal administration was achieved by incorporating the liposomes into Carbopol hydrogel. DPGLs were able to penetrate through the hydrogel network more rapidly than conventional liposomes. In vitro studies of drug release from the liposomal hydrogel under conditions simulating human treatment confirmed sustained and diffusion-based drug release. Characterization of the rheological and textural properties of the DPGL-containing liposomal hydrogels demonstrated that the incorporation of DPGLs alone had no significant influence on mechanical properties of hydrogels compared to controls. These results support the great potential of DPGL-in-hydrogel as an efficient delivery system for the controlled and sustained release of antimicrobial drugs in the vagina.     

Oral ingestion of insulin liposomes: Effects of the administration route

We prepared an insulin liposome suspension by hot dispersion (50 °C) of a lipid mixture comprising dipalmitoyl phosphatidylcholine (DPPC) and cholesterol (7:2 molar ratio) in an 80 UI/ml acid bovine insulin solution, followed by two minutes of cold sonification (4 °C). Free insulin was removed by ultracentrifugation and the washed insulin liposomes were resuspended in a 1% aqueous saline solution (pH 3). Administration of these liposomes in the buccal cavity of normal rats caused clear hypoglycemia (?37% of the initial glycemia after one hour and ?44% after $\text{2}\text{1}\text{2}$ hours), but the solution was inactive when introduced by a strictly intragastric route. Hypoglycemic effects were also obtained when a mixture containing a liposome suspension devoid of insulin and 10 UI/100 g b.w. of free insulin was given by the buccal route (?56% of initial glycemia one hour later and ?55% after $\text{2}\text{1}\text{2}$ hours). These results show that the route of liposomal insulin administration strongly influences its biological effects.     

Sendai virus induced leakage of liposomes containing gangliosides

Sendai virus induced liposome leakage has been studied by using liposomes containing a self-quenching fluorescent dye, calcein. The liposomes used in this study were prepared by a freeze and thaw method and were composed of phosphatidylcholine, phosphatidylserine, and phosphatidylethanolamine (1:2.60:1.48 molar ratio) as well as various amounts of gangliosides and cholesterol. The leakage rate was calculated from the fluorescence increment as the entrapped calcein leaked out of the liposomal compartment and was diluted into the media. It was shown that the target liposome leakage was virus dose dependent. Trypsin-treated Sendai virus in which the F protein had been quantitatively removed did not induce liposome leakage, indicating that the leakage was a direct result of F-protein interaction with the target bilayer membrane. The activation energy of this process was approximately 12 kcal/mol below 17 degrees C and approximately 25 kcal/mol above 17 degrees C. Gangliosides GM1, GD1a, and GT1b could serve as viral receptor under appropriate conditions. Liposome leakage showed a bell-shaped curve dependence on the concentration of ganglioside in the liposomes. No leakage was observed if the ganglioside content was too low or too high. Inclusion of cholesterol in the liposome bilayer suppressed the leakage rate of liposomes containing GD1a. It is speculated that the liposome leakage is a consequence of fusion between Sendai virus and liposomes.