Cholesterol content of small unilamellar liposomes controls phospholipid loss to high density lipoproteins in the presence of serum

Liposomes for drug delivery: review of vesicular composition, factors affecting drug release and drug loading in liposomes

Liposomes are considered among the most versatile and advanced nanoparticle delivery systems used to target drugs to specific cells and tissues. Structurally, liposomes are sphere-like vesicles of phospholipid molecules that are surrounded by equal number of aqueous compartments. The spherical shell encapsulates an aqueous interior which contains substances such as peptides and proteins, hormones, enzymes, antibiotics, antifungal and anticancer agents. This structural property of liposomes makes it an important nano-carrier for drug delivery. Extrusion is one of the most frequently used technique for preparing monodisperse uni-lamellar liposomes as the technique is used to control vesicle size. The process involves passage of lipid suspension through polycarbonate membrane with a fixed pore size to produce vesicles with a diameter near the pore size of the membrane used in preparing them. An advantage of this technique is that there is no need to remove the organic solvent or detergent from the final preparation. This review focuses on composition of liposome formulation with special emphasis on factors affecting drug release and drug-loading.

Lipid-based nanocarriers challenging the ocular biological barriers: Current paradigm and future perspectives

Eye is the most specialized and sensory body organ and treating eye diseases efficiently is necessary. Despite various attempts, the design of a consummate ophthalmic drug delivery system remains unsolved because of anatomical and physiological barriers that hinder drug transport into the desired ocular tissues. It is important to advance new platforms to manage ocular disorders, whether they exist in the anterior or posterior cavities. Nanotechnology has piqued the interest of formulation scientists because of its capability to augment ocular bioavailability, control drug release, and minimize inefficacious drug absorption, with special attention to lipid-based nanocarriers (LBNs) because of their cellular safety profiles. LBNs have greatly improved medication availability at the targeted ocular site in the required concentration while causing minimal adverse effects on the eye tissues. Nevertheless, the exact mechanisms by which lipid-based nanocarriers can bypass different ocular barriers are still unclear and have not been discussed. Thus, to bridge this gap, the current work aims to highlight the applications of LBNs in the ocular drug delivery exploring the different ocular barriers and the mechanisms viz. adhesion, fusion, endocytosis, and lipid exchange, through which these platforms can overcome the barrier characteristics challenges.

Interaction of neutral and protonated Tamoxifen with the DPPC lipid bilayer using molecular dynamics simulation

Tamoxifen as an antiestrogen is successfully applied for the clinical treatment of breast cancer in pre- and post-menopausal women. Due to the side effects related to the oral administration of Tamoxifen (such as deep vein thrombosis, pulmonary embolism, hot flushes, ocular disturbances and some types of cancer), liposomal drug delivery is recommended for taking this drug. Drug encapsulation in a liposomal or lipid drug delivery system improves the pharmacokinetic and pharmacodynamic properties. In this regard, we carried out 200-ns molecular dynamics (MD) simulations for three systems (pure DPPC and neutral and protonated Tamoxifen-loaded DPPC). Here, DPPC is a model lipid bilayer to provide us with conditions like liposomal drug delivery systems to investigate the interactions between Tamoxifen and DPPC lipid bilayers and to estimate the preferred location and orientation of the drug molecule inside the bilayer membrane. Properties such as area per lipid, membrane thickness, lateral diffusion coefficient, order parameters and mass density, were surveyed. With insertion of neutral and protonated Tamoxifen inside the DPPC lipid bilayers, area per lipid and membrane thickness increased slightly. Also, Tamoxifen induce ordering of the hydrocarbon chains in DPPC bilayer. Analysis of MD trajectories shows that neutral Tamoxifen is predominantly found in the hydrophobic tail region, whereas protonated Tamoxifen is located at the lipid-water interface (polar region of DPPC lipid bilayers).

Beyond Formulation: Contributions of Nanotechnology for Translation of Anticancer Natural Products into New Drugs

Nature is the largest pharmacy in the world. Doxorubicin (DOX) and paclitaxel (PTX) are two examples of natural-product-derived drugs employed as first-line treatment of various cancer types due to their broad mechanisms of action. These drugs are marketed as conventional and nanotechnology-based formulations, which is quite curious since the research and development (R&D) course of nanoformulations are even more expensive and prone to failure than the conventional ones. Nonetheless, nanosystems are cost-effective and represent both novel and safer dosage forms with fewer side effects due to modification of pharmacokinetic properties and tissue targeting. In addition, nanotechnology-based drugs can contribute to dose modulation, reversion of multidrug resistance, and protection from degradation and early clearance; can influence the mechanism of action; and can enable drug administration by alternative routes and co-encapsulation of multiple active agents for combined chemotherapy. In this review, we discuss the contribution of nanotechnology as an enabling technology taking the clinical use of DOX and PTX as examples. We also present other nanoformulations approved for clinical practice containing different anticancer natural-product-derived drugs.

Multifunctional Nanoplatforms as a Novel Effective Approach in Photodynamic Therapy and Chemotherapy, to Overcome Multidrug Resistance in Cancer

It is more than sixty years since the era of modern photodynamic therapy (PDT) for cancer began. Enhanced selectivity for malignant cells with a reduced selectivity for non-malignant cells and good biocompatibility along with the limited occurrence of side effects are considered to be the most significant advantages of PDT in comparison with conventional therapeutic approaches, e.g., chemotherapy. The phenomenon of multidrug resistance, which is associated with drug efflux transporters, was originally identified in relation to the application of chemotherapy. Unfortunately, over the last thirty years, numerous papers have shown that many photosensitizers are the substrates of efflux transporters, significantly restricting the effectiveness of PDT. The concept of a dynamic nanoplatform offers a possible solution to minimize the multidrug resistance effect in cells affected by PDT. Indeed, recent findings have shown that the utilization of nanoparticles could significantly enhance the therapeutic efficacy of PDT. Additionally, multifunctional nanoplatforms could induce the synergistic effect of combined treatment regimens, such as PDT with chemotherapy. Moreover, the surface modifications that are associated with nanoparticle functionalization significantly improve the target potential of PDT or chemo-PDT in multidrug resistant and cancer stem cells.

Preparation, characterization, and evaluation of eosin B-loaded nano-liposomes for growth inhibition of Plasmodium falciparum

Malaria is a deadly disease in humans caused by the Plasmodium parasite. High prevalence of malaria and resistance of malaria parasite to currently proposed drugs have increased the need to introduce and use new and effective antimalarial agents. In this study, eosin B was used as an effective antimalarial agent, the efficacy of which has already been confirmed by in vitro models. Also, for efficacy and safety improvement of eosin B, liposomal nanocarrier was used because of diversity and adaptability in controlled drug delivery and targeting. Eosin B was trapped inside liposomal nanocarriers by thin layer hydration method and its optimization was performed based on size, polydispersity index, and drug entrapment efficiency. Finally, the eosin B-loaded liposomes were tested on Plasmodium falciparum in culture to evaluate its anti-plasmodial effect. According to the results, the formulation with DSPC:cholesterol 8:1 (molar ratio) and drug concentration of 3 mg/ml was selected as the optimal form. The optimal nano-liposomes showed a size of 163.3 nm, a polydispersity index of 0.250, and an encapsulation efficiency of 69.94%. The process of drug release from nanocarriers was also obtained about 63% at the end of 72 h. Stability studies over 2 months at 25 °C and 4 °C on the optimum sample showed that the samples stored in the refrigerator were more stable in terms of size characteristics, polydispersity index, and drug entrapment efficiency. The results indicate a greater effect of liposomal-formulated eosin B on inhibiting parasite growth compared to the free eosin B.

Biocatalytic self-assembled synthetic vesicles and coacervates: From single compartment to artificial cells

Compartmentalization is an intrinsic feature of living cells that allows spatiotemporal control over the biochemical pathways expressed in them. Over the years, a library of compartmentalized systems has been generated, which includes nano to micrometer sized biomimetic vesicles derived from lipids, amphiphilic block copolymers, peptides, and nanoparticles. Biocatalytic vesicles have been developed using a simple bag containing enzyme design of liposomes to multienzymes immobilized multi-vesicular compartments for artificial cell generation. Additionally, enzymes were also entrapped in membrane-less coacervate droplets to mimic the cytoplasmic macromolecular crowding mechanisms. Here, we have discussed different types of single and multicompartment systems, emphasizing their recent developments as biocatalytic self-assembled structures using recent examples. Importantly, we have summarized the strategies in the development of the self-assembled structure to improvise their adaptivity and flexibility for enzyme immobilization. Finally, we have presented the use of biocatalytic assemblies in mimicking different aspects of living cells, which further carves the path for the engineering of a minimal cell.

Liposomes and mRNA: Two technologies together create a COVID-19 vaccine

The urgency to understand and modify immune responses has never been as great universally as during the present Coronavirus time. It has been suggested that using established techniques, a small piece of the so-called spike protein of the Coronavirus injected into humans in the form of mRNA could raise an immune response against the expressed protein, in turn killing or inactivating the invading Coronavirus. Unfortunately, however, the mRNA was found to be too vulnerable to survive in the body long enough on injection to produce the spike protein and an immune response to it. But as it happens, a solution was to hand, one waiting to be discovered.

Improving the anti-inflammatory efficacy of dexamethasone in the treatment of rheumatoid arthritis with polymerized stealth liposomes as a delivery vehicle

Rheumatoid arthritis (RA) is an autoimmune disease that causes chronic inflammation of the joints of the body. Although liposomes are a promising drug delivery vehicle, there is still a challenge of using conventional liposomes for the treatment of RA due to their short circulation time and physicochemical instability in blood vessels. Here, we report the formation of polymerized stealth liposomes composed of 1,2-bis(10,12-tricosadiynoyl)-sn-glycero-3-phosphocholine (DC8,9PC) and 1,2-distearoyl-sn-glycero-3-phospho-ethanolamine-poly(ethyleneglycol) (DSPE-PEG2000) with a thin-film hydration method, in which DC8,9PC molecules are cross-linked in the bilayer of the liposomes by UV irradiation and the PEG chains present at the surface of the liposomes provide a stealth layer. We demonstrate that the polymerized stealth liposomes are stable and show long circulation time in blood vessels. They can be internalized by cells without significant toxicity. After being injected into arthritic rats, the polymerized stealth liposomes with loaded dexamethasone (Dex) show long blood circulation time and accumulate preferentially in inflamed joints, consequently suppressing the level of proinflammatory cytokines (TNF-α and IL-1β) in joint tissues, reducing the swelling of inflamed joints and alleviating the progression of RA. We believe that polymerized stealth liposomes can be used as a promising drug delivery vehicle for various therapeutic applications.

In vivo fate of liposomes after subconjunctival ocular delivery

Subconjunctival administration of nanocarriers presents an alternative drug delivery strategy to overcome blood-ocular barriers to enhance drug bioavailability to specific parts of the eye. Using fiberoptic Confocal Laser Microendoscopy (CLM) and radiotracing, we describe the effects of charge, size, cholesterol content and lipid saturation on the ocular and corporal distribution of liposome nanocarriers in live mouse models. Positively charged or large (>250 nm) liposomes exhibit sustained ocular residence times in and around the injection site; cholesterol loading slows down this clearance, whereas lipid saturation accelerates clearance. Neutral, negatively charged, or smaller sized liposomes distribute to the limbus, rich in stem cells and blood capillaries. Differential lymphatic and systemic clearance from the eye to corporeal tissues was also observed across formulations. These results demonstrate the need to optimize liposome design for control over temporal and spatial nanocarrier bioavailability and clearance from the eye for improved efficacy and safety of ocular therapeutics.

Cosm-nutraceutical nanovesicles for acne treatment: Physicochemical characterization and exploratory clinical experimentation

The full exploration of the 'nutraceuticals' therapeutic potential in cosmetics has been hindered by their poor stratum corneum permeation. Therefore, the aim of the present study was to formulate a nutraceutical; quercetin, in novel vitamin C based nanovesicles (aspasomes), and to explore their beneficial effects in the treatment of acne. Aspasomes were characterized for their particle size, zeta potential, entrapment efficiency (EE%), 3-months storage stability, skin deposition/permeation, antioxidant potential, and morphology. Aspasomes antibacterial efficacy on Propionibacterium acnes using the zone of inhibition assay was also tested, whilst their safety on skin fibroblastic cells was assessed in vitro using 3T3 CCL92 cell lines. An exploratory clinical trial was conducted in acne patients, and the percentage reduction of inflammatory, non-inflammatory and total acne lesions was taken as the evaluation criterion. Results revealed that quercetin-loaded aspasomes displayed a desirable nanometer size (125-184 nm), negative charge with good storage stability, and high skin deposition reaching 40%. Aspasomes managed to preserve the antioxidant activity of quercetin, and exhibited a significantly higher antibacterial effect (15 ± 1.53 mm) against Propionibacterium acnes than quercetin alone (8.25 ± 2.08 mm), and were safe on skin fibroblastic cells. Upon clinical examination in 20 acne patients (14 females, 6 males), quercetin aspasomes exhibited reduction percentages of 77.9%, 11.8% and 55.3% for inflammatory lesions, comedones and total lesions respectively. This opens vast applications of the presented formulation in the treatment of other oxidative skin diseases, and delineates the nutraceuticals and nanoformulations prepared from natural materials as promising dermatological treatment modes.

Effects of cholesterol concentration on the interaction of cytarabine with lipid membranes: a molecular dynamics simulation study

Liposomal cytarabine, DepoCyt, is a chemotherapy agent which is used in cancer treatment. This form of cytarabine has more efficacy and fewer side effects relative to the other forms. Since DepoCyt contains the cytarabine encapsulated within phosphatidylcholine and the sterol molecules, we modeled dioleoylphosphatidylcholine (DOPC)/cholesterol bilayer membrane as a carrier for cytarabine to study drug-bilayer interactions. For this purpose, we performed a series of united-atom molecular dynamics (MD) simulations for 25 ns to investigate the interactions between cytarabine and cholesterol-containing DOPC lipid bilayers. Only the uncharged form of cytarabine molecule was investigated. In this study, different levels of the cholesterol content (0, 20, and 40%) were used. MD simulations allowed us to determine dynamical and structural properties of the bilayer membrane and to estimate the preferred location and orientation of the cytarabine molecule inside the bilayer membrane. Properties such as membrane thickness, area per lipid, diffusion coefficient, mass density, bilayer packing, order parameters, and intermolecular interactions were examined. The results show that by increasing the cholesterol concentration in the lipid bilayers, the bilayer thickness increases and area per lipid decreases. Moreover, in accordance with the experiments, our calculations show that cholesterol molecules have ordering effect on the hydrocarbon acyl chains. Furthermore, the cytarabine molecule preferentially occupies the polar region of the lipid head groups to form specific interactions (hydrogen bonds). Our results fully support the experimental data. Our finding about drug-bilayer interaction is crucial for the liposomal drug design.

Antigen delivery by lipid-enveloped PLGA microparticle vaccines mediated by in situ vesicle shedding

Lipid-coated poly(lactide-co-glycolide) microparticles (LCMPs) consist of a solid polymer core wrapped by a surface lipid bilayer. Previous studies demonstrated that immunization with LCMPs surface-decorated with nanograms of antigen elicit potent humoral immune responses in mice. However, the mechanism of action for these vaccines remained unclear, as LCMPs are too large to drain efficiently to lymph nodes from the vaccination site. Here, we characterized the stability of the lipid envelope of LCMPs and discovered that in the presence of serum the lipid coating of the particles spontaneously delaminates, shedding antigen-displaying vesicles. Lipid delamination generated 180 nm liposomes in a temperature- and lipid/serum-dependent manner. Vesicle shedding was restricted by inclusion of high-T_M lipids or cholesterol in the LCMP coating. Administration of LCMPs bearing stabilized lipid envelopes generated weaker antibody responses than those of shedding-competent LCMPs, suggesting that in situ release of antigen-loaded vesicles plays a key role in the remarkable potency of LCMPs as vaccine adjuvants.

Effect of lipid composition of cationic SUV liposomes on materno-fetal transfer of warfarin across the perfused human term placenta

INTRODUCTION

Use of drugs that cross the placenta freely are currently avoided during pregnancy. We investigated whether cationic small unilamellar (SUV) liposomes of different lipid compositions could prevent the transfer and uptake of warfarin across human term placenta.

METHODS

Cationic liposomes encapsulated warfarin was prepared by using lecithin (F-SUV) or sterylamine (S-SUV) with cholesterol and stearylamine. The size distribution, encapsulation efficiency, and stability were determined in blood-based media. The transfer kinetics of free and liposomally encapsulated warfarin were studied in a dually perfused isolated lobule of human term placenta with creatinine. Concentrations of warfarin were measured by fluorimetry. Data are expressed as % of initial dose added and given as mean ± sd.

RESULTS

Warfarin crossed the placenta freely (14.9 ± 1.1%). Trans placental transfer of warfarin was significantly reduced by F-SUV (6.4 ± 0.6%; P < 0.001) and S-SUV liposomes (5.0 ± 0.8%; P < 0.001). Placental uptake of F-SUV (6.3 ± 1.7%; P < 0.001) was greater than that of S-SUV liposomes (2.2 ± 0.5%; P < 0.001).

CONCLUSION

Our data suggest that cationic liposomes reduce trans placental transfer of warfarin. If confirmed "in vivo", liposomes might provide an alternative non-invasive method of drug delivery to the mother.

Characterization of the pharmacokinetics of a liposomal formulation of eribulin mesylate (E7389) in mice

Eribulin mesylate (E7389), a tubulin and microtubule inhibitor, has been approved to treat metastatic breast cancer in certain patient populations. A liposomal formulation of E7389, E7389-LF, aims to increase the therapeutic profile of E7389. As determining the free drug concentration is crucial for the assessment of efficacy and toxicity of liposomal drug, in this study, an ultracentrifugation method coupled with LC-MS/MS was developed to separate the free E7389 from liposomal and protein bound E7389. The pharmacokinetics of the free E7389 after dosing either E7389 or E7389-LF was characterized. The concentration ratio of E7389 in ultracentrifuged mice plasma (UCM) vs E7389 in plasma after a 2mg/kg i.v. of E7389 ranged from 54.19% to 65.41%, which was similar to the free fraction in the mouse plasma. The respective concentration ratio of E7389 in UCM vs E7389 in plasma after a 2mg/kg i.v. of E7389-LF ranged from 0.07% to 0.59%, and the exposure, expressed as AUC, of UCM/plasma ratio was determined to be 0.2%. Pharmacokinetic modeling was performed to estimate the release kinetics of E7389 from E7389-LF, and the release was best described by a first order rate constant k(rel) 0.078 h(-1). Sensitivity analysis demonstrated that further decrease the release rate constant by adjusting liposome formulation would lead to decreased C(max) and much longer half-life of UCM E7389, which might result in better efficacy and lower toxicity.

Cholesterol--a biological compound as a building block in bionanotechnology

Cholesterol is a molecule with many tasks in nature but also a long history in science. This feature article highlights the contribution of this small compound to bionanotechnology. We discuss relevant chemical aspects in this context followed by an overview of its self-assembly capabilities both as a free molecule and when conjugated to a polymer. Further, cholesterol in the context of liposomes is reviewed and its impact ranging from biosensing to drug delivery is outlined. Cholesterol is and will be an indispensable player in bionanotechnology, contributing to the progress of this potent field of research.

Preparation, properties and the effects of amikacin, netilmicin and tobramycin in free and liposomal formulations on Gram-negative and Gram-positive bacteria

The most common problems limiting the medical use of aminoglycosides have been the nephro- and oto-toxicities and the increasing bacterial resistance. It has been shown that encapsulation of drugs into liposomes enhances their efficacy while reducing their toxicities. The present in vitro study was designed to evaluate the antimicrobial activities of free and liposomal amikacin, netilmicin and tobramycin. We, therefore, encapsulated these drugs into liposomes prepared by sonication. The drug contained in liposomes was measured by enzyme multiplied immunoassay technique (EMIT) after lysis of the vesicles by 0.2% Triton X-100. The comparative encapsulation efficiency of the three antibiotic preparations was assessed. Aminoglycosides kinetic release from liposomes in presence of normal human sera was also studied in vitro over a 48 h period at 37 degrees C under 5% CO(2). The MICs of these encapsulated drugs to Pseudomonas aeruginosa, Xanthomonas maltophilia, Escherichia coli, Streptococcus faecalis and Staphylococcus aureus were determined and compared to those of respective free drugs using an agar dilution method. The amikacin and tobramycin encapsulation efficiencies were significantly (P </= 0.05) higher (5.36% +/- 0.17 and 5.06% +/- 0.10) than those of netilmicin (3% +/- 0.18). However, in presence of sera, liposomal retention of netilmicin was significantly (P </= 0.05) lower (61.88 +/- 0.14%) than that of amikacin (81.45 +/- 0.64%) and tobramycin (94.07 +/- 0.18%) after 1 h of incubation and then remained nearly constant over an 48 h period of the study. The MICs of liposomal netilmicin against all bacterial strains tested were reduced, compared to those of free netilmicin. However, liposomal amikacin and tobramycin MICs were nearly similar to those of free respective drugs. Overall, liposomal netilmicin appears to be a promising approach in the management of Gram-positive and Gram-negative bacterial infections and should be further evaluated in in vivo experiments.

Structural effects and translocation of doxorubicin in a DPPC/Chol bilayer: the role of cholesterol

We use molecular dynamics simulations to characterize the influence of cholesterol (Chol) on the interaction between the anticancer drug doxorubicin (DOX) and a dipalmitoyl phosphatidylcholine/Chol lipid bilayer. We calculate the potential of mean force, which gives us an estimate of the free energy barrier for DOX translocation across the membrane. We find free energy barriers of 23.1 ± 3.1 k(B)T, 36.8 ± 5.1 k(B)T, and 54.5 ± 4.7 k(B)T for systems composed of 0%, 15%, and 30% Chol, respectively. Our predictions agree with Arrhenius activation energies from experiments using phospholipid membranes, including 20 k(B)T for 0% Chol and 37.2 k(B)T for 20% Chol. The location of the free energy barrier for translocation across the bilayer is dependent on composition. As Chol concentration increases, this barrier changes from the release of DOX into the water to flip-flop over the membrane center. The drug greatly affects local membrane structure by attracting dipalmitoyl phosphatidylcholine headgroups, curving the membrane, and allowing water penetration. Despite its hydrophobicity, DOX facilitates water transport via its polar groups.

Inhibition of the Growth of Plasmodium falciparum in Culture by Stearylamine-Phosphatidylcholine Liposomes

We have examined the effect of stearylamine (SA) in liposomes on the viability of Plasmodium falciparum in culture by studying the inhibition of incorporation of [³H]-hypoxanthine in the nucleic acid of parasites. Stearylamine in liposomes significantly inhibits the growth of the parasites depending on the phospholipids composition. The maximum inhibition was observed when SA was delivered through Soya phosphatidylcholine (SPC) liposomes. The chain length of alkyl group and density of SA in liposomes play a significant role in inhibiting the growth of the parasites. Incorporation of either cholesterol or Distearylphosphatidylethanolamine−Methoxy-Polyethylene glycol-2000 (DSPE-mPEG-2000) in Soya phosphatidylcholine-stearylamine (SPC-SA) liposomes improves the efficacy. Intraerythrocytic entry of intact SPC-SA liposomes into infected erythrocytes was visualized using fluorescent microscopy. No hemolysis was observed in uninfected erythrocytes, and slight hemolysis was noted in infected erythrocytes at high concentrations of SPC-SA liposomes. Overall, our data suggested SA in SPC-liposomes might have potential application in malaria chemotherapy.

A novel class of photo-triggerable liposomes containing DPPC:DC(8,9)PC as vehicles for delivery of doxorubcin to cells

Success of nanoparticle-mediated drug delivery is subject to development of optimal drug release strategies within defined space and time (triggered release). Recently, we reported a novel class of photo-triggerable liposomes prepared from dipalmitoyl phosphatidylcholine (DPPC) and photopolymerizable diacetylene phospholipid (DC(8),(9)PC), that efficiently released entrapped calcein (a water soluble fluorescent dye) upon UV (254nm) treatment. To develop these formulations for in vivo applications, we have examined phototriggering of these liposomes by visible light, and the effect of released anticancer drugs on cellular toxicity. Sonicated liposomes containing various ratios of DPPC:DC(8),(9)PC and 4mol% DSPE-PEG2000 were loaded with calcein (Ex/Em, 485/517nm) or a chemotherapy drug, Doxorubicin (DOX, Ex/Em 490/590nm). Our initial experiments showed that 514nm laser treatment of liposomes containing 10 or 20mol% DC(8,9)PC for 1-3min resulted in significant release of calcein. Based on these results, we performed studies with DOX-loaded liposomes. First, biophysical properties (including liposome size and stability) and DOX encapsulation efficiency of the liposomes were determined. Subsequently, the effect of 514nm laser on DOX release, and cellular toxicity by released DOX were examined. Since liposomes using the 86:10:04 mole ratio of DPPC:DC(8),(9)PC:DSPE-PEG2000, showed highest encapsulation of DOX, these formulations were investigated further. We report that (i) liposomes retained about 70% of entrapped DOX at 37°C in the presence of 0-50% serum. (ii) 514nm laser treatment resulted in DOX release from liposomes in a wavelength-specific manner. (iii) Laser treatment of co-cultures containing DOX-loaded liposomes and cells (Raji and MCF-7) resulted in at least 2-3 fold improved cell killing as compared to untreated samples. Taken together, the photo-triggerable liposomes described here may provide a platform for future drug delivery applications. To our knowledge, this is the first report demonstrating improved cell killing following light-triggered release of an encapsulated anticancer agent from photosensitive liposomes.

Lipid-quantum dot bilayer vesicles enhance tumor cell uptake and retention in vitro and in vivo

We report the construction of lipid-quantum dot (L-QD) bilayer vesicles by incorporation of the smallest (2 nm core size) commercially available CdSe/ZnS QD within zwitterionic dioleoylphosphatidylcholine and cationic 1,2-dioleoyl-3-trimethylammonium-propane lipid bilayers, self-assembling into small unilamellar vesicles. The incorporation of QD in the acyl environment of the lipid bilayer led to significant enhancement of their optical stability during storage and exposure to UV irradiation compared to that of QD alone in toluene. Moreover, structural characterization of L-QD hybrid bilayer vesicles using cryogenic electron microscopy revealed that the incorporation of QD takes place by hydrophobic self-association within the biomembranes. The L-QD vesicles bound and internalized in human epithelial lung cells (A549), and confocal laser scanning microscopy studies indicated that the L-QD were able to intracellularly traffick inside the cells. Moreover, cationic L-QD vesicles were injected in vivo intratumorally, leading to enhanced retention within human cervical carcinoma (C33a) xenografts. The hybrid L-QD bilayer vesicles presented here are thought to constitute a novel delivery system that offers the potential for transport of combinatory therapeutic and diagnostic modalities to cancer cells in vitro and in vivo.

Preparation, characterization, and biological analysis of liposomal formulations of vincristine

Vincristine is a dimeric Catharanthus alkaloid derived from the Madagascan periwinkle that acts by binding to tubulin and blocking metaphase in actively dividing cells. While vincristine is widely used in the treatment of a number of human carcinomas, its use is associated with dose-limiting neurotoxicity, manifested mainly as peripheral neuropathy. It is known that the therapeutic activity of vincristine can be significantly enhanced after its encapsulation in appropriately designed liposomal systems. Enhanced efficacy is also associated with a slight decrease in drug toxicity. Thus, the therapeutic index of vincristine can be enhanced significantly through the use of a liposomal delivery system. Vincristine may be encapsulated into liposomes of varying lipid composition by several techniques, including passive loading, pH gradient loading, and ionophore-assisted loading. However, most research has focused on the encapsulation of vincristine in response to a transbilayer pH gradient, which actively concentrates the drug within the aqueous interior of the liposome. This chapter details the preparation and evaluation of liposomal vincristine. Specifically, we elaborate on the components (choice of lipids, molar proportions, etc.), methods (preparation of liposomes, drug loading methods, etc.), critical design features (size, surface charge, etc.), and key biological endpoints (circulation lifetime, bioavailability, efficacy measurements) important to the development of a formulation of vincristine with enhanced therapeutic properties.

Novel temperature-sensitive liposomes with prolonged circulation time

Hyperthermia increases the efficiency of various chemotherapeutic drugs and is administered as an adjunct to chemotherapy for the treatment of cancer patients. The temperature-dependent effect can be strongly increased by the use of temperature-sensitive liposomes in combination with regional hyperthermia, which specifically releases the entrapped drug in the heated tumor tissue. The novel lipid 1.2-dipalmitoyl-sn-glycero-3-phosphoglyceroglycerol (DPPGOG), which is closely related to the naturally occurring 1.2-dipalmitoyl-sn-glycero-3-phosphoglycerol, in combination with 1.2-dipalmitoyl-sn-glycero-3-phosphocholine and 1.2-distearoyl-sn-glycero-3-phosphocholine provides long-circulating temperature-sensitive liposomes with favorable properties under mildly hyperthermic conditions (41-42 degrees C). DPPGOG facilitates temperature-triggered drug release from these liposomes (diameter, 175 nm) and leads to a substantially prolonged plasma half-life for the encapsulated drug with t(1/2) = 9.6 h in hamsters and t(1/2) = 5.0 h in rats. Quantitative fluorescence microscopy of amelanotic melanoma grown in the transparent dorsal skin fold chamber of hamsters demonstrated a favorable drug accumulation in heated tissue after i.v. application of these liposomes (42 degrees C for 1 h). The mean area under the curve for tissue drug concentration was increased by more than sixfold by application of the new liposomes compared with nonliposomal drug delivery. In summary, we present a new DPPGOG-based liposomal formulation enabling long circulation time combined with fast and efficient drug release under mild hyperthermia. This adds positively to the results with lipid-grafted polyethylenglycol used thus far in temperature sensitive liposomes and widens the possibilities for clinical applications.

Prednisolone retention in integrated liposomes by chemical approach and pharmaceutical approach

The purpose of this study is to demonstrate a stable retention of prednisolone (PLS) in the unique liposomes integrated by lipophilic derivative approach and PEGylation approach. Palmitoyl prednisolone (Pal-PLS) was newly synthesized and used as a lipophilic derivative. The liposomes were composed of egg phosphatidylcholine (EggPC)/cholesterol (Chol) and L-alpha-distearoylphosphatidylcholine (DSPC)/Chol with or without L-alpha-distearoylphosphatidylethanolamine-polyethylene glycol 2000 (DSPE-PEG 2000) or -PEG 5000 (DSPE-PEG 5000). The retentions of PLS and Pal-PLS in the various liposomes were examined by ultrafiltration and gel filtration. Although PLS showed high trapping efficiency by all liposomes after ultrafiltration, low incorporation efficiency was observed in gel filtration. It indicates that PLS was released from the liposomes by a dilution with elution medium in gel filtration. Pal-PLS showed high incorporation into all liposomes after both ultrafiltration and gel filtration. The high incorporation of Pal-PLS into EggPC/Chol liposomes, however, was reduced by incubation with rat plasma in gel filtration. The reducing effect of rat plasma on drug incorporation into liposomes was inhibited by using DSPC and DSPE-PEGs. Thus, we systemically examined the drug retention in various liposomes and demonstrated the high retention of PLS in the liposomes integrated by lipophilic derivative approach and pharmaceutical approach using special lipids.

Pretreatment of serum containing hemoglobin vesicles (oxygen carriers) to prevent their interference in laboratory tests

Hemoglobin vesicles (HbV, diameter: 251 +/- 81 nm) are artificial oxygen (O2) carriers encapsulating concentrated hemoglobin (Hb) solution with phospholipid bilayer membrane, and their O2 transporting ability in vivo has been extensively studied. It is important to clarify the interference of the HbV suspension in clinical laboratory tests performed on serum and to establish a pretreatment method to avoid such an interference. The HbV suspension, acellular Hb solution ([Hb] = 10 g/dl) or saline, was mixed with a pooled human serum at various ratios up to 50 vol% ([Hb] = 5 g/dl), and the magnitude of the interference effect of HbV and Hb on 30 analytes was studied. The mixture of the HbV suspension and serum was ultracentrifuged (50,000 g, 20 min) to remove the HbV particles as precipitate, and the supernatant was analyzed and compared with the saline control group. The HbV particles were also removed by centrifugation (2,700 g, 30 min) in the presence of dextran (Mw 200 kDa). The HbV suspension showed considerable interference effects in most analytes. The majority of these effects was more serious than those of the acellular Hb solution. These findings are thought to be due to the light absorption of Hb in HbV and/or the light scattering generated in the suspension that interferes with the colorimetric and turbidimetric measurements. The components of HbV may also interfere with the chemical reactions of the studied assays. However, removal of the HbV from the supernatant diminished the interference in most of the assays: this is an advantage of HbV in comparison with acellular chemically modified Hb solutions.

Improved retention of idarubicin after intravenous injection obtained for cholesterol-free liposomes

To date there has been a focus on the application of sterically stabilized liposomes, composed of saturated diacylphospholipid, polyethylene glycol (PEG) conjugated lipids (5-10 mole%) and cholesterol (CH) (>30 mole%), for the systemic delivery of drugs. However, we are now exploring the utility of liposome formulations composed of diacylphospholipid conjugated PEG mixtures prepared in the absence of added cholesterol, with the primary objective of developing formulations that retain encapsulated drug better than comparable formulations prepared with cholesterol. In this report the stability of cholesterol-free distearoylphosphatidylcholine (DSPC):distearoylphosphatidylethanolamine (DSPE)-PEG(2000) (95:5 mol/mol) liposomes was characterized in comparison to cholesterol-containing formulations DSPC:CH (55:45 mol/mol) and DSPC:CH:DSPE-PEG(2000) (50:45:5 mol/mol/mol), in vivo. Circulation longevity of these formulations was determined in consideration of variables that included varying phospholipid acyl chain length, PEG content and molecular weight. The application of cholesterol-free liposomes as carriers for the hydrophobic anthracycline antibiotic, idarubicin (IDA), was assessed. IDA was encapsulated using a transmembrane pH gradient driven process. To determine stability in vivo, pharmacokinetic studies were performed using 'empty' and drug-loaded [(3)H]cholesteryl hexadecyl ether radiolabeled liposomes administered intravenously to Balb/c mice. Inclusion of 5 mole% of DSPE-PEG(2000) or 45 mole% cholesterol to DSPC liposomes increased the mean plasma area under the curve (AUC(0-24h)) 19-fold and 10-fold, respectively. Cryo-transmission electron micrographs of IDA loaded liposomes indicated that the drug formed a precipitate within liposomes. The mean AUC(0-4h) for free IDA was 0.030 micromole h/ml as compared to 1.38 micromole h/ml determined for the DSPC:DSPE-PEG(2000) formulation, a 45-fold increase, demonstrating that IDA was retained better in cholesterol-free compared to cholesterol-containing liposomes.

A comparison of liposomal formulations of doxorubicin with drug administered in free form: changing toxicity profiles

The anthracycline antibiotic doxorubicin has wide activity against a number of human neoplasms and is used extensively both as a single agent and in combination regimens. In addition to the use of free, unencapsulated doxorubicin, there are two US Food and Drug Administration approved liposomal formulations of doxorubicin currently available, with several additional liposomal formulations being researched either in the laboratory or in clinical trials. The two approved liposomal formulations of doxorubicin have significantly different lipid compositions and loading techniques, which lead to both unique pharmacokinetic and toxicity profiles, distinct from those of the unencapsulated form. This article discusses the toxicities associated with the free form of doxorubicin, as well as those associated with the two most common liposomal formulations, namely Doxil and Myocet. One of the key toxicity issues linked to the use of free doxorubicin is that of both an acute and a chronic form of cardiomyopathy. This is circumvented by the use of liposomal formulations, as these systems tend to sequester the drug away from organs such as the heart, with greater accumulation in liver, spleen and tumours. However, as will be discussed, the liposomal formulations of doxorubicin are not without their own related toxicities, and, in the case of Doxil, may be associated with the unique toxicity of palmar-plantar erythrodysaesthesia. Overall, the use of liposomal doxorubicin allows for a greater lifetime cumulative dose of doxorubicin to be administered, however acute maximal tolerated doses differ significantly, with that of Myocet being essentially equivalent to free doxorubicin, while higher doses of Doxil may be safely administered. This review highlights the differences in both toxicity and pharmacokinetic properties between free doxorubicin and the different liposomal formulations, as have been determined in pre-clinical and clinical testing against a number of different human neoplasms. The need for further testing of the liposomal formulations prior to the replacement of free doxorubicin with liposomal doxorubicin in any established combination therapy regimens, as well as in combination with the newer therapeutics such as monoclonal antibodies is also discussed.

Chemical degradation of liposomes by serum components detected by NMR

Interaction between serum components and liposomes is an oxygen-dependent exothermic process. We studied the interaction of 100 nm extruded liposomes (bearing positive, negative or no charge) with foetal calf serum by 1H NMR and 13C NMR, in order to further our understanding of these reactions. Studies of aqueous or organic extracts obtained after 2 h, 1 day or 1 week, showed hydrolysis to be a degradation process concomitant with the interaction with serum. Oxidation was identified as additional to hydrolysis in the process of degradation. Oxidation produced aldehydes, acids and alcohols, although aldehydes and alcohols were prone to further decomposition and only appeared transiently. Alkenes and other oxidized compounds predominated in those products derived from oxidation. In stearylamine-containing liposomes some aldehydes and a nitroderivative were found as degradation products. Such metabolites are apolar and their presence might explain the intrinsic toxicity of this kind of liposome in cell cultures. The work described in the present study revealed the chemical degradation of liposomes in the serum used. In all cases the results obtained were compared with liposomes not incubated with serum.

To fuse or not to fuse: the effects of electrostatic interactions, hydrophobic forces, and structural amphiphilicity on protein-mediated membrane destabilization

The development of lipid-based delivery vehicles for therapeutic molecules has become a topic of intense research. Recently, much of this effort has been directed towards mimicking the characteristics of viruses that give them an advantage for the delivery of genetic medicines. One of the most desirable properties of viral-based vectors is the ability to promote the destabilization of the host cell membrane to allow the entry of the genetic medicine into the target cell. This has been found to be largely controlled by the coat proteins on the surface of enveloped viruses. Although the exact mechanism by which proteins involved in the fusion process are able to promote the destabilization of membranes has yet to be elucidated, much understanding based upon information gained from a wide variety of studies is advancing the state of knowledge in this area. Parameters such as hydrophobic and electrostatic interactions as well as structural amphiphilicity, control to a large extent, the nature of the interaction of proteins with membranes. Thus, membrane fusion is mediated primarily by these forces acting in concert with one another. Ultimately, the knowledge gained from these studies will help to develop the ideal delivery system for the next generation of therapeutics.

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.

Ligand-targeted liposomes

Liposomes have gained increased attention as systemic drug delivery vehicles following recent regulatory approvals of several vesicle-formulated drugs. These products have demonstrated improved therapeutic indices over their corresponding conventional drugs by avoiding sensitive tissues and/or increasing delivery to specific targets in vivo. They have achieved these improvements primarily through physical means: (1) by retaining drug within vesicles while in the circulation, thus avoiding or minimizing uptake by sensitive normal tissues; and (2) by selectively extravasating into target tissues, releasing active drug. In order to improve upon these therapies in the future, clinically active liposome delivery systems most likely will need to include site-directed surface ligands to further enhance their selective delivery. This may be crucial for the in vivo transport and delivery of macromolecules, including antisense, oligonucleotide aptamers, and genes, which-unlike most conventional drugs-do not circulate well and often require cellular uptake by fusion, endocytosis, or other processes to reach their active sites. This manuscript reviews technologies applicable to directing liposomes and their contents to selected in vivo targets using surface-bound, site-specific ligands. Presented are the biological barriers to be overcome, criteria for selecting the determinants to be targeted, various targeting ligands and overall delivery system design considerations. Several novel targets as well as novel ligand constructs for site-directed therapy are reviewed and discussed. Systemic liposome therapy, which currently must be administered by the intravenous route, is the principal focus of this analysis.

Effect of surface charge of small unilamellar liposomes on uptake and transfer of carboxyfluorescein across the perfused human term placenta

We aim to investigate the effect of surface charge of small unilamellar liposomes on transfer and uptake of a low molecular weight, hydrophilic and polar molecule carboxyfluorescein in an in vitro model of perfused human term placenta. Carboxyfluorescein-encapsulated neutral liposomes were prepared by using an equimolar concentration of lecithin and cholesterol. Anionic and cationic liposomes were prepared by adding dicetylcholine and stearylamine, respectively. Size distribution, encapsulation efficiency, and stability of liposomes in blood-based medium were determined. The transfer kinetics of free carboxyfluorescein and liposomally encapsulated carboxyfluorescein were studied in a dually perfused isolated lobule of human term placenta. The concentration of carboxyfluorescein was measured fluorometrically. The maternal to fetal transfer and placental uptake of free carboxyfluorescein was 1.6 +/- 0.1% and 4.2 +/- 0.1% of the initial dose, respectively. This constitutes the control data. The placental transfer of carboxyfluorescein was significantly increased by neutral (2.5 +/- 0.1%; p < 0.01) and anionic liposomes (3.1 +/- 0.2%; p < 0.001), whereas cationic liposomes prevented its transfer (0.4 +/- 0.1%; p < 0.001). The placental uptake of neutral (14.9 +/- 2.3%; p < 0.001) and anionic liposomes (21.1 +/- 1.2%; p < 0.001) were significantly higher than the cationic liposomes (2.3 +/- 0.6%) and control group (p < 0.001). The placental uptake of cationic liposomes was comparable with the control data. These results indicate that placental uptake of small unilamellar liposomes depends upon their surface charge, and transfer of carboxyfluorescein is enhanced by anionic and impeded by cationic liposomes.

Effect of liposome-encapsulated hemoglobin on triglyceride, total cholesterol, low-density lipoprotein, and high-density lipoprotein cholesterol measurements

The present study investigated the effect of liposome-encapsulated hemoglobin (LEH), an experimental oxygen-carrying resuscitation fluid, on triglyceride, total cholesterol, and low density lipoprotein (LDL), and high density lipoprotein (HDL) cholesterol measurements. In vivo, the intravenous infusion of LEH (5.6 mL/kg, n = 6) elevated serum triglycerides (+92% vs. baseline, P < .05), total cholesterol (+25% vs. baseline, P < .01), LDL cholesterol (+72% vs. baseline, P < .01) and had no effect on serum HDL cholesterol. In addition, LEH did not alter the elevation in serum triglycerides (+302% vs. baseline, P < .01) and LDL cholesterol (+86% vs. baseline, P < .01) induced by lipopolysaccharide (3.6 mg/kg, i.v., n = 6. Ex vivo, measurements of triglycerides and total cholesterol as well as LDL and HDL cholesterol in whole blood from naive rats were not changed by the addition of LEH (0-50%, n = 6). In vitro, the addition of a fixed concentration of LEH (50%, n = 6) to varying concentrations of cholesterol solution (0-50%), or vice versa, had no effect on cholesterol determination. It is therefore concluded that LEH only minimally affects serum levels of triglycerides, total cholesterol, LDL cholesterol, and HDL cholesterol and does not interfere with their measurement.

Serum-liposome interaction is an oxygen-dependent process

Measurements of heat dissipation, oxygen concentration and average vesicle size were correlated to study the effect of serum components on different types of liposome. The results indicate that the interaction between serum components and liposomes is exothermic and oxygen dependent, and leads to disruption of vesicles. The dependence of this effect on serum concentration, vesicle surface charge and type of liposome was also evaluated. Serum components did not produce any effect on conventional liposomes in the absence of oxygen. Moreover, in hypoxic conditions the serum-liposome interaction was delayed. Both results suggest that this interaction is an oxygen-dependent event. Finally, we confirmed that sterically stabilised liposomes remain unalterated in the presence of serum.

Liposomal doxorubicin

Doxorubicin is a potent antineoplastic agent with activity against numerous human cancers. Encapsulation of doxorubicin inside a liposome alters bioavailability, biodistribution and thus its biological activity significantly. The physical properties of the liposome (size, lipid components and lipid dose) play a major role in determining drug retention and pharmacokinetics. The therapeutic benefits of liposomal doxorubicin will therefore depend on these physical characteristics. Here we review the toxicity and efficacy of liposomal doxorubicin determined for various liposome compositions (size, lipid composition and drug-to-lipid ratio). These physical properties can be independently varied using the transmembrane pH gradient-dependent drug encapsulation procedure. The results show that the toxicity of the formulation is related to drug retention in the circulation. The antitumor activity is more sensitive to the size of the liposomes. By optimizing these parameters, liposomal doxorubicin formulations can be optimized for improved therapeutic activity.

Preparation and characterization of liposomes as therapeutic delivery systems: a review

Liposome drug delivery systems are being developed for a variety of drugs. Scale-up process to larger size batches is often a monumental task for the process development scientists. This article reviews various aspects of process development work pertinent to aseptic process techniques for liposomes. This article also has discussed the bilayer properties of liposomes and showed the nomenclature used to classify the liposomes. Discussed is the pH gradient method to load liposomes. Issues and challenges involved in prolonging the shelf-life of liposomes is presented. This review covered the importance of complete removal of organic solvent that is used in the process. Finally the authors presented an HPLC method for quick identification and assay of various phospholipids in a mixture of phospholipids.

Size dependent liposome degradation in blood: in vivo/in vitro correlation by kinetic modeling

The degradation of liposomes in blood circulation is important in regulating the releasing rate of encapsulated compounds. In this study, the effect of liposome size--one of the principal determining factors in liposome disposition--on their degradation in serum/blood was evaluated quantitatively both in vitro and in vivo. In the in vitro study, the time courses of the degradation of liposomes in fresh rat serum were measured continuously using 5(6)-carboxyfluorescein (CF) as an aqueous phase marker and were described by the kinetic model with the lag time (tau), first order degradation rate constant (k), and the maximum degradation (alpha). Both k and alpha increased with the increase of liposome size, which indicated a higher affinity of larger liposomes for complement activation. In the in vivo study, the degradation of liposomes was evaluated sensitively by a first order degradation rate constant (kd) in blood circulation. The kd was obtained by kinetically modeling the liposome degradation in vivo using 3H-inulin as an aqueous phase marker. The size dependent kd correlated well with the hepatic uptake clearance, which suggests an underlying complement activation mechanism common to both degradation and hepatic uptake of liposomes. There was a good correlation in the degradation rate constant between in vitro and in vivo trials. These kinetic analyses validate the quantitative evaluation of liposome degradation in blood circulation and provide a useful way to predict the degradation of liposomes in vivo from in vitro experiments.

Incorporation of alpha-tocopherol in liposomes promotes the retention of liposome-encapsulated glutathione in the rat lung

The present study was undertaken to investigate whether alpha-tocopherol incorporated in liposomes could improve the retention of entrapped glutathione (GSH) in the lung following intratracheal instillation in rats. Rats were treated with a single dose of [3H]GSH entrapped in liposomes with or without 30 mol% alpha-tocopherol and killed 0, 24 or 48 h later. The retention of GSH in the lung was assessed by measuring the recovery of either 3H-label or GSH in the lung. Animals instilled with free [3H]GSH were found to retain only 2% of the administered dose at 24 h after treatment and no detectable radioactivity at 48 h. Liposome encapsulation altered the pulmonary retention of GSH with 18 and 10% of radioactivity remaining in the lung at 24 and 48 h post-treatment, respectively. The instillation of GSH encapsulated in alpha-tocopherol-containing liposomes resulted in the highest level of GSH retention in the lung, namely 37 and 30% of the administered GSH dose at 24 and 48 h, respectively. Results from Sepharose 4B column chromatography revealed that lung homogenates, obtained from rats instilled with GSH entrapped in alpha-tocopherol-containing liposomes, 24 and 48 h earlier, contained 2 eluted GSH-related components--one associated with the liposomal lipid marker in the void volume and the other as free GSH tripeptide, suggesting a slow sustained release effect mediated by the liposomal formulation. The same liposome preparation containing both alpha-tocopherol and GSH also conferred better protection against FeADP-induced lipid peroxidation than liposomes containing either alpha-tocopherol or GSH alone, indicative of a potentially effective antioxidant formulation for treating oxidative lung injury.

Coupling of ligands to liposomes independently of solute entrapment: observations on the formed vesicles

Bovine serum albumin (BSA), employed as a model ligand, was covalently linked (about 16% of the amount used) to small unilamellar vesicles (SUV) composed of phospholipid, cholesterol and N-(p-aminophenyl)stearylamide (APSA) (molar ratios 1:1:0.05). SUV with bound BSA were then used to generate dehydration-rehydration vesicles (DRV) in the presence of tetanus toxoid and/or carboxyfluorescein (CF). Nearly all of the SUV-bound BSA (about 15% of the original amount) was recovered in the multilamellar DRV formed, with a considerable proportion (42-62%) of the ligand becoming available on the outer bilayers. This apparent spatial reorientation of BSA within DRV also caused the entrapped toxoid to shift to some extent to the liposomal surface. There was no significant difference in the z average mean size between DRV with and without coupled BSA (543 and 555 nm diameter, respectively). Percent number diameter distribution data revealed that 71.2 (BSA-free) and 76.4% (BSA-containing DRV) of the vesicles had diameters of about 300-440 and 330-420 nm, respectively. However, in terms of percent mass diameter distribution, 69.5% (BSA-free) and 65.2% (BSA-containing DRV) of the mass was in vesicles with corresponding ranges of diameter of 1381-2975 and 1086-2840 nm. Vesicle size heterogeneity in both preparations was confirmed by freeze-fracture electron microscopy which also indicated that structures with or without bound BSA, were mostly vesicular of the multilamellar type. Judging from CF latency values, ligand-bearing DRV were stable on incubation with blood plasma at 37 degrees C for 24 h. Stability was, however, reduced significantly when the amount of ligand bound was excessive. The present approach allows for the coupling of ligands to and the entrapment of antigens and other labile solutes in liposomes independently, thus avoiding potential damage of such solutes by the coupling reagents.

Influence of liposome charge and composition on their interaction with human blood serum proteins

Lipid composition and specially their electrostatic properties, were found to greatly influence the stability of liposomes in human blood serum. The amount and type of serum proteins bound to the liposomes were also clearly influenced by lipid composition and charge of liposomes. A good correlation was found between the amount of serum proteins adsorbed to a given type of liposome and its instability as measured by the release of an encapsulated fluorescent probe. Liposomes that bind the highest amount of protein were the least stable, except for the case of liposomes containing gangliosides, which were fairly stable even at a high amount of bound protein. Liposomes with neutral charge containing phosphatidylcholine were the most stable and bound the lowest amount of protein. Liposomes with positive charge behaved similarly to those with neutral charge. However, the stability of negatively charged liposomes was very dependent on their composition. Those liposomes containing only one class of negatively charged phospholipids bound a great amount of protein and were very unstable. However, those liposomes containing also phosphatidylcholine bound less protein and were more stable. The examination of the electrophoresis patterns of serum proteins bound to the different types of liposomes indicated the presence of specific proteins which correlated with liposome instability.

Reduced kallikrein excretion by liposome-encapsulated cyclosporin in the rat

Different phospholipids and methods of preparation were used to produce cyclosporin encapsulated in liposomes. The optimal formulation of cyclosporin-liposome was compared to the oily cyclosporin after intraperitoneal administration of 25 mg kg-1 body weight to rats. Urinary kallikrein excretion was significantly reduced with the liposomal form. The abrupt increase of kallikrein excretion after the tenth day with the control oil preparation suggests that cyclosporin toxicity could be present at the tubular level, and the encapsulation of cyclosporin in liposomes reduces tubular damage.