Kinetics and thermodynamics of emulsion delivery of lipophilic antioxidants to cells in culture

Modeling the release kinetics of poorly water-soluble drug molecules from liposomal nanocarriers

Liposomes are frequently used as pharmaceutical nanocarriers to deliver poorly water-soluble drugs such as temoporfin, cyclosporine A, amphotericin B, and paclitaxel to their target site. Optimal drug delivery depends on understanding the release kinetics of the drug molecules from the host liposomes during the journey to the target site and at the target site. Transfer of drugs in model systems consisting of donor liposomes and acceptor liposomes is known from experimental work to typically exhibit a first-order kinetics with a simple exponential behavior. In some cases, a fast component in the initial transfer is present, in other cases the transfer is sigmoidal. We present and analyze a theoretical model for the transfer that accounts for two physical mechanisms, collisions between liposomes and diffusion of the drug molecules through the aqueous phase. Starting with the detailed distribution of drug molecules among the individual liposomes, we specify the conditions that lead to an apparent first-order kinetic behavior. We also discuss possible implications on the transfer kinetics of (1) high drug loading of donor liposomes, (2) attractive interactions between drug molecules within the liposomes, and (3) slow transfer of drugs between the inner and outer leaflets of the liposomes.

Formulation of multifunctional oil-in-water nanosized emulsions for active and passive targeting of drugs to otherwise inaccessible internal organs of the human body

Oil-in-water (o/w) type nanosized emulsions (NE) have been widely investigated as vehicles/carrier for the formulation and delivery of drugs with a broad range of applications. A comprehensive summary is presented on how to formulate the multifunctional o/w NE for active and passive targeting of drugs to otherwise inaccessible internal organs of the human body. The NE is classified into three generations based on its development over the last couple of decades to make ultimately a better colloidal carrier for a target site within the internal and external organs/parts of the body, thus allowing site-specific drug delivery and/or enhanced drug absorption. The third generation NE has tremendous application for drug absorption enhancement and for 'ferrying' compounds across cell membranes in comparison to its first and second generation counterparts. Furthermore, the third generation NE provides an interesting opportunity for use as drug delivery vehicles for numerous therapeutics that can range in size from small molecules to macromolecules.

Lipophilic drug transfer between liposomal and biological membranes: what does it mean for parenteral and oral drug delivery?

This review presents the current knowledge on the interaction of lipophilic, poorly water soluble drugs with liposomal and biological membranes. The center of attention will be on drugs having the potential to dissolve in a lipid membrane without perturbing them too much. The degree of interaction is described as solubility of a drug in phospholipid membranes and the kinetics of transfer of a lipophilic drug between membranes. Finally, the consequences of these two factors on the design of lipid-based carriers for oral, as well as parenteral use, for lipophilic drugs and lead selection of oral lipophilic drugs is described. Since liposomes serve as model-membranes for natural membranes, the assessment of lipid solubility and transfer kinetics of lipophilic drug using liposome formulations may additionally have predictive value for bioavailability and biodistribution and the pharmacokinetics of lipophilic drugs after parenteral as well as oral administration.

Oil-in-water lipid emulsions: implications for parenteral and ocular delivering systems

Lipid emulsions (LEs) are heterogenous dispersions of two immiscible liquids (oil-in-water or water-in-oil) and they are subjected to various instability processes like aggregation, flocculation, coalescence and hence eventual phase separation according to the second law of thermodynamics. However, the physical stability of the LE can substantially be improved with help of suitable emulsifiers that are capable of forming a mono- or multi-layer coating film around the dispersed liquid droplets in such a way to reduce interfacial tension or to increase droplet-droplet repulsion. Depending on the concentrations of these three components (oil-water-emulsifier) and the efficiency of the emulsification equipments used to reduce droplet size, the final LE may be in the form of oil-in-water (o/w), water-in-oil (w/o), micron, submicron and double or multiple emulsions (o/w/o and w/o/w). The o/w type LEs (LE) are colloidal drug carriers, which have various therapeutic applications. As an intravenous delivery system it incorporates lipophilic water non-soluble drugs, stabilize drugs that tend to undergo hydrolysis and reduce side effects of various potent drugs. When the LE is used as an ocular delivery systems they increase local bioavailability, sustain the pharmacological effect of drugs and decrease systemic side effects of the drugs. Thus, the rationale of using LE as an integral part of effective treatment is clear. Following administration of LE through these routes, the biofate of LE associated bioactive molecules are somehow related to the vehicles disposition kinetics inside blood or eyeball. However, the LE is not devoid from undergoing various bio-process while exerting their efficacious actions. The purpose of this review is therefore to give an implication of LE for parenteral and ocular delivering systems.

A novel stable supersaturated submicron lipid emulsion of tirilazad

This paper describes a novel supersaturated submicron lipid emulsion for parenteral drug delivery. Tirilazad was used as an amphiphilic model drug for the preparation and characterization of the supersaturated emulsions with concentrations more than two times higher than the drug solubility in the emulsion. Analysis of particle size distribution using photon correlation spectroscopy indicated that the mean particle diameters of the supersaturated 10 and 20% lipid emulsions of tirilazad were approximately 210 and 240 nm, respectively, and that the mean particle size and size distribution of the supersaturated tirilazad emulsions were not different from those of the non-supersaturated tirilazad emulsions. The apparent viscosity of the supersaturated tirilazad emulsions, as measured by continuous rheometry, was similar to that of the non-supersaturated tirilazad emulsions. However, the zeta potential of the supersaturated tirilazad emulsions, as determined by the electrophoretic light-scattering technique, was found to be dependent on drug load and was lower than that of the non-supersaturated tirilazad emulsion. Fractionation by ultracentrifugation showed that at low drug loads, the amount of drug associated with the emulsion particles and the infranatant fraction appeared to increase linearly with increasing concentration of the drug. By contrast, the amount of drug associated with the emulsion particles increased rapidly, whereas the amount of drug associated with the infranatant fraction remained constant for emulsions with a high drug load. These results suggest that the excess drug in the supersaturated emulsions is largely associated with the lipid phase. Accelerated stability studies under stress conditions (i.e., autoclaving and shaking) and long-term storage stability tests demonstrated that the supersaturated tirilazad emulsions had excellent physical stability over the study period of 16 months.

Analytical and numerical techniques for the evaluation of free radical damage in cultured cells using scanning laser microscopy

Scanning laser microscopy (SLM) was used to develop an assay to visualize the generation of intracellular reactive oxygen species (ROS) and to evaluate the effect of the lipophilic antioxidant U-87,663 on ROS formation. Cultured N18 neuroglioma cells were challenged by extracellular addition of cumene hydroperoxide, and subsequent intracellular generation of ROS was characterized by measuring the fluorescence intensity of the ROS indicator 2',7'-dichlorofluorescein (DCF). The kinetics of the reaction between ROS and the indicator DCF, or the antioxidant U-87,663, can be most accurately assessed if results from individual cell clusters are analyzed independently. It is possible and necessary to account for the these experimental and analytical properties in order to characterize the properties of the antioxidant activity precisely. We determined that the temporal increase in DCF fluorescence was consistent with the reaction of DCF with free radicals generated from cumene hydroperoxide, as was the loss of fluorescence from U-87,663. The rate constants for the free radical reactions revealed that ROS reaction with DCF is 10 times faster than with U-87,663. These differences in reaction rates combined with differences in the cellular distribution of the ROS indicator DCF, the antioxidant U-87,663, and the bulk of the ROS prevented detection of any protection of U-87,663 may offer.

Efficacy of lipid soluble, membrane-protective agents against hydrogen peroxide cytotoxicity in cardiac myocytes

We examined the efficacy of a group of drugs that stabilize the cell membrane and can potentially prevent cytotoxicity in cultured fetal chick cardiac myocytes exposed to hydrogen peroxide (H2O2). The effects of various membrane-protective agents were determined by analysis of the kinetics of lactic dehydrogenase (LDH) release. The kinetic parameters calculated from the data include a rate constant for release of LDH (kb) and the fraction of total LDH that is released from the cells (CIIMax). The CIIMaxs derived from a range of H2O2 concentrations reveal that the mean toxic concentration of H2O2 is 1.1 mM and that the pattern of toxicity is consistent with the damage being directly proportional to the concentration of the free radicals generated from the H2O2. Maximum nontoxic concentrations of three amphiphilic membrane protective agents had no effect upon cytotoxicity from H2O2. The slightly polar lipophilic agent, Trolox C, a vitamin E derivative, was also without protective effect at a maximum nontoxic concentration. The highly lipophilic agent, probucol, had a small protective effect at 50 microM, the maximum concentration we succeeded in solubilizing in the culture medium. However, the lipophilic 21-aminosteroid U74500, delivered to the cells in an emulsion, markedly reduced cytotoxicity from H2O2. The CII Max was significantly reduced and the protection was concentration dependent over a range of concentrations from 50-400 nmol/ml. Furthermore, the inhibition by U74500 was fully consistent with a mechanism of scavenging of free radicals formed during lipid peroxidation. In support of this hypothesis, a dose of 400 nmoles/ml completely prevented an increase in lipid peroxides due to H2O2 exposure, whereas there was a sixfold increase during exposure to H2O2 in untreated myocytes. Thus, a lipid soluble 21-aminosteroid prevented lipid peroxidation and reduced cardiac myocyte injury during exposure to H2O2, probably by scavenging of free radicals formed during lipid peroxidation in the cell membrane, whereas amphiphilic agents, which probably altered the physicochemical structure of the cell membrane but did not scavenge free radicals, were not protective.