Lung surfactant as a drug delivery system.

Lung surfactant is a complex mixture of mainly phospholipids and proteins. The composition leads to a unique spreading effect of the surfactant as well as spontaneous vesicle formation, which may be favourable characteristics of a drug delivery system for pulmonary delivery. The aim of study was to investigate the potential use of the surfactant extract, HL10 (LeoPharma, DK) as a drug delivery system. Studies involved incorporation of hydrophilic- and amphipathic model drugs (sucrose and acylated peptides) into HL10 and elucidation of the influence of surfactant proteins on the HL10 behaviour. Results showed that HL10 vesicles did not retain sucrose indicating formation of leaky vesicles. Studying the influence of surfactant proteins on release from DPPC-liposomes showed tendencies toward a protein-induced release. Hence, the surfactant proteins may influence the membrane lipid packing and characteristics resulting in leakiness of the membranes. Incorporation of acylated peptides into HL10 depended on the chain length rendering a successful incorporation of the peptide acylated with C14-acyl chains. This study suggests that HL10 may be a promising drug delivery system for the pulmonary delivery of amphipathic drug substances, e.g. therapeutically active acylated peptides (e.g. acylated insulin).

Increase in phospholipase A2 activity towards lipopolymer-containing liposomes.

Phospholipase A2 (PLA2)-catalyzed hydrolysis of dipalmitoylphosphatidylcholine (DPPC) liposomes incorporated with submicellar concentrations of polyethyleneoxide covalently attached to dipalmitoylphosphatidylethanolamine (DPPE-PEG2000) has been studied in the gel-to-fluid transition region of the host DPPC lipid bilayer matrix. By means of fluorescence and light-scattering measurements, the characteristic PLA2 lag time has been determined as a function of lipopolymer concentration and temperature. The degree of lipid hydrolysis was followed using radioactive labeled lipids. Differential scanning calorimetry has been applied to characterize the thermodynamic phase behavior of the lipopolymer-containing liposomes. A remarkable lipopolymer concentration-dependent decrease in the lag time was observed over broad temperature ranges. The radioactive measurements demonstrate an increase in catalytic activity for increasing amounts of lipopolymers in the bilayer. Hence, the lipopolymers act as a promoter of PLA2 lipid hydrolysis resulting in a degradation of the bilayer structure and a concomitant destabilization of the liposomes. This behavior is in contrast to the generally observed protective and stabilization effect in biological fluids exerted by lipopolymers in polymer-grafted liposomes. It is proposed that the enhanced activity of the small water soluble and interfacially active enzyme may involve a non-uniform distribution of the lipopolymers in the lipid matrix due to a coupling between local lipid bilayer curvature and composition of the non-bilayer-preferring lipopolymers.

Sustained elevated plasma aprotinin concentration in mice following intraperitoneal injections of w/o emulsions incorporating aprotinin.

This study was initiated to test the feasibility of w/o emulsions as a sustained release system for aprotinin following intraperitoneal injection in mice. The emulsion was well tolerated in mice and sustained release was observed over a period of 96 h. The time for maximum plasma concentration of aprotinin was 10 min and 12 h after injection of a control solution and the emulsion dosage form, respectively. Furthermore, the hemolytic activity of the emulsion constituents was low indicating a low acute toxicological potential of the emulsion. The present study also showed that the lipolytic activity in peritoneal exudate from mice is important for the clearance of oily vehicles from the peritoneal cavity with lipolytic rate constants ranging from 50 to 130 nmol free fatty acid released/min/mg exudate protein at 37 degrees C, pH 8.5. It was concluded that the w/o emulsion was well suited to provide sustained elevated plasma aprotinin concentrations in mice.

Enzymatic degradation of polymer covered SOPC-liposomes in relation to drug delivery.

Polyethylenoxide (PEG) covered liposomes are used as lipid-based drug-delivery systems. In comparison to conventional liposomes the polymer-covered liposomes display a long circulation half-life in the blood stream. We investigate the influence of polyethyleneoxide-distearoylphosphatidylethanolamine (DSPE-PEG750) lipopolymer concentration on phospholipase A2 (PLA2) catalyzed hydrolysis of liposomes composed of stearoyloleoylphosphatidylcholine (SOPC). The characteristic PLA2 lag-time was determined by fluorescence and the degree of lipid hydrolysis was followed by HPLC analysis. Particle size and zeta-potential were measured as a function of DSPE-PEG750 lipopolymer concentration. A significant decrease in the lag-time, and hence an increase in enzyme activity, was observed with increasing concentrations of the anionic DSPE-PEG750 lipopolymer lipids. The observed decrease in lag-time might be related to changes in the surface potential and the PLA2 lipid membrane affinity.

Influence of lipopolymer concentration on liposome degradation and blood clearance.

It is well known, that a prolonged liposome circulation time can be achieved by incorporation of lipopolymers into the lipid membrane thereby reducing interactions with destabilizing factors in the blood stream, e.g. phagocytic cells and lipoproteins. However, very little is known about the enzymatic degradation of steric hindered liposomes introduced into body fluids. In this study, the blood clearance and the PLA2 catalyzed degradation of unilamellar dipalmitoylphosphatidylcholine (DPPC) liposomes incorporated with increasing amounts of dipalmitoylphosphatidylethanolamine-polyethyleneglycol (DPPE-PEG), was investigated. The results demonstrated an increase in PLA2 activity for increasing amounts of lipopolymer in the lipid membrane, while the liposome blood clearance was prolonged by incorporation of DPPE-PEG into the liposomes. Hence, these results suggest that it may be possible for long circulating liposomes to obtain a site specific liposome degradation and release of drug substance in tissue with high levels of PLA2.

The effect of controlled osmotic stress on release and swelling properties of a water-in-oil emulsion.

The purpose of this study was to investigate the effect of osmotic gradients in a water-in-oil (w/o) emulsion on release properties in order to control the release of hydrophilic drugs. The magnitude and direction of the osmotic gradient was shown to have a pronounced effect on the apparent permeability of the hydrophilic marker, [3H]glucose. The apparent permeability coefficient of glucose could be varied between 1.0x10(-5) and 5.0x10(-8) cm s-1 using osmotic gradients. The release rate of glucose was related to the swelling properties. The larger the degree of swelling, the lower the release rate. Furthermore the present w/o emulsion has a low viscosity and a long-term physical stability. This makes the emulsion a promising parenteral drug delivery system in which the release of hydrophilic drugs such as peptides, can be controlled.

Interaction of a lipid-membrane destabilizing enzyme with PEG-liposomes.

Polymer grafted PEG-liposomes have come into use as drug-delivery systems with improved therapeutic profiles. However, very little is known about the morphological instability of PEG-liposomes due to enzymatic degradation. To gain further insight into the effect of PEG lipopolymer-concentration on the catalytic activity of a liposome-degrading enzyme, phospholipase A2 (PLA2)-catalyzed phospholipid hydrolysis of PEG-liposomes has been investigated. The temperature dependence of the PLA2 lag-time, denoting the time required before a sudden increase in enzymatic activity takes place, has been determined for submicellar amounts of dipalmitoylphosphatidylethanolaminyl-poly-(ethylene glycol) (DPPE-PEG2000) incorporated into unilamellar dipalmitoylphosphatidylcholine (DPPC)-liposomes. The measurements demonstrate a significant reduction in the lag-time over broad temperature ranges. The results suggest that a close relationship exists between PLA2 catalyzed lipid hydrolysis and lipid-membrane composition, which moreover is of major importance for the overall morphological stability and the release of encapsulated material from the polymer-grafted PEG-liposomes.

Formulation and evaluation of release and swelling mechanism of a water-in-oil emulsion using factorial design.

Water-in-oil emulsions have a potential as a parenteral prolonged release system for hydrophilic drugs. A consistent challenge when developing an emulsion drug delivery system is to obtain a proper release characteristic of the entrapped drug. The aim of the present study was to study the release mechanism from water-in-oil emulsions. Secondly, to study the effects of droplet size, phase ratio and osmotic pressure on the release rate of glucose from water-in-oil emulsions in a factorial experimental design. The release mechanism of glucose was deduced from the release kinetics of two coentrapped marker molecules, glucose and inulin, with a molecule weight of 180 and 5000 g/mol, respectively. The results indicate that release of glucose was dominated by diffusion through the oily barrier as opposed to membrane rupture. Using statistical methodology, the release rate of glucose could be varied 8 fold in a controlled manner with osmotic pressure as the most important parameter. The osmotic behaviour of the emulsions was further studied in a dynamic swelling study. These results show that the release of entrapped hydrophilic drug can be controlled within certain limits using pharmaceutical formulation principles.

Activity of mammalian secreted phospholipase A(2) from inflammatory peritoneal fluid towards PEG-liposomes. Early indications.

Due to an increase in the activity of phospholipase A(2) (PLA(2)) in various inflammatory diseases, this enzyme may play a key role in the degradation of liposomes and the subsequent release of drug when PEG-liposomes passively target inflammatory tissue. The activity of mammalian secreted phospholipase A(2) (sPLA(2)) in casein stimulated peritoneal fluid was tested toward liposomes of different compositions. Early results indicate only a slight degradation of conventional dipalmitoylphosphatidylcholine (DPPC) liposomes as well as DPPC liposomes incorporated with different concentrations of PEG(2000). However, the DPPC degradation increased to 7% when inclusion of 30 mol% phosphatidylethanolamine (PE) in the lipid bilayer. The increase in degradation may be due to an improvement of the substrate - as it is well known, that PE is a better substrate for the mammalian sPLA(2) than PC. Incorporation of PE into the bilayer may increase the binding properties of the bilayer resulting in improved conditions for the enzymatic attack by sPLA(2). In addition, inhibitory zones of Staphylococcus aureus in an agar diffusion test showed that PLA(2) from Crotalus atrox venom was able to catalyze the release of gentamicin from PEG-liposomes. In conclusion, this study suggest that degradation of the lipid bilayer of PEG-liposomes by PLA(2) result in release of incapsulated drug, e.g. gentamicin and inclusion of PE in the liposomal bilayer, may enhance the activity of the mammalian sPLA(2) toward liposomes composed of DPPC.

Drug delivery by phospholipase A(2) degradable liposomes.

The effect of poly(ethylene glycol)-phospholipid (PE-PEG) lipopolymers on phospholipase A(2) (PLA(2)) hydrolysis of liposomes composed of stearoyl-oleoylphosphatidylcholine (SOPC) was investigated. The PLA(2) lag-time, which is inversely related to the enzymatic activity, was determined by fluorescence, and the zeta-potentials of the liposomes were measured as a function of PE-PEG lipopolymer concentration. A significant decrease in the lag-time, and hence an increase in enzymatic activity, was observed with increasing amounts of the negatively charged PE-PEG lipopolymers incorporated into the SOPC liposomes. The enhancement of the PLA(2) enzymatic activity might involve a stronger PLA(2) binding affinity towards the negatively charged and polymer covered PEG liposomes.

Parenteral water/oil emulsions containing hydrophilic compounds with enhanced in vivo retention: formulation, rheological characterisation and study of in vivo fate using whole body gamma-scintigraphy.

The preparation and characterization of parenteral water-in-oil (w/o) emulsions with a potential for sustained release of hydrophilic drugs was described with emphasis on rheological behaviour and spreading phenomenon after intramuscular (i.m.) injection in rabbit thigh muscle. Both steady state and dynamic rheological parameters were investigated showing Newtonian behaviour at low fraction of disperse phase ratio as opposed to viscoelastic and pseudoplastic behaviour at high fraction of disperse phase. Disappearance and spreading behaviour of hydrophilic radioactive markers, aprotinin (6512 g/mol) and pertechnetate (193 g/mol) entrapped in w/o emulsions from an i.m. injection site was studied by whole body gamma-scintigraphy. The retention of entrapped aprotinin 24 h postinjection was 83 +/- 5% for a low spreading emulsion and 76 +/- 6% for a high spreading emulsion. The corresponding values for pertechnetate were 50 +/- 11 and 23 +/- 2%, respectively. The relatively long retention times were suggested to be related to the good physical stability properties of the present emulsions. It was concluded that the presented w/o emulsions are promising vehicles for sustained release of hydrophilic drugs from an i.m. injection site.

An in vitro assay based on surface plasmon resonance to predict the in vivo circulation kinetics of liposomes.

The adsorption of blood proteins onto liposomes and other colloidal particles is an important process influencing the circulation time. Proteins adsorbed to the surface of liposomes can mediate recognition of the liposomes by macrophages of the reticuloendothelial system (RES) facilitating their clearance from the circulation. Coating liposomes with poly(ethylene glycol) (PEG) decreases the blood clearance considerably, most likely due to reduced protein adsorption and/or liposome aggregation. By using the relation between clearance and protein binding, the present study introduces an in vitro assay measuring interactions of liposomes with proteins to predict their blood clearance in vivo. Such assay is valuable since it limits time and costs, and importantly reduces the number of animals required for pharmacokinetic investigations of new formulations. In the current study, Surface Plasmon Resonance (SPR) and fluorescence Single Particle Tracking (fSPT) were used to study liposome-protein interactions and blood induced liposome aggregation in vitro. By means of SPR the interactions between proteins and liposomes coated with PEG of different molecular weights and at different densities (PEG(2000) in 2.5%, 5% and 7%; PEG(5000) in 0.5%, 1.5% and 2.5%), were measured for several plasma proteins: human serum albumin (HSA), apolipoprotein E (ApoE), α2-macroglobulin (α2-M), ß2-glycoprotein (ß2-G) and fibronectin (Fn). Liposomes coated with PEG interacted less with all proteins, an effect which increased with the PEG surface density. In parallel, fSPT analysis showed that the exposure of liposomes to full blood did not change the liposome size, indicating that aggregation is not a strong attributive factor in the clearance of these liposomes. In addition, the SPR measurements of the interactions between liposomes and proteins were correlated with the blood clearance of the liposomes. For each protein, the degree of protein-liposome interaction as determined by SPR showed a moderate to strong positive correlation with the clearance of the liposome type.

Absorption and metabolism of the absorption enhancer didecanoylphosphatidylcholine in rabbit nasal epithelium in vivo.

The absorption enhancer, didecanoylphosphatidylcholine (DDPC), improves the nasal absorption of human growth hormone in rabbits. We elucidated the uptake and the metabolism of 1,2-di[1-14C]decanoyl-L-3-phosphatidylcholine and 1,2-didecanoyl-L-3-phosphatidyl[N-methyl-3H]choline in rabbit nasal mucosa in vivo. One minute after nasal application of DDPC, 4.4-7.5% of the applied dose was found absorbed into the mucosa. The retained radioactivity left the tissue in <2 hr. The lipophilic tissue extract revealed that, at t = 1 min, only 1.1-1.4% of the applied dose was found as intact DDPC in the nasal mucosa. The other labeled compounds were decanoic acid, DDPC reacylated with endogenous fatty acids, a neutral lipid, and very small amounts of lyso-DDPC and phosphatidylethanolamine. The water-soluble metabolites revealed formation of phosphorylcholine, glycerophosphorylcholine, cytidinediphosphatecholine, and a slight amount of choline. The detection of these metabolites suggests that DDPC was rapidly cleared from the nasal mucosa, partly by degradation by phospholipases. In addition, data illustrated reutilization of DDPC metabolites in the formation of cytidinediphosphatecholine and phosphatidylethanolamine, together with DDPC being reacylated with endogenous fatty acids. The rapid formation of decanoic acid raises the possibility that this acid may contribute significantly to the drug-enhancing properties of DDPC.