Sharma R. Minchey

Amphotericin B-phospholipid interactions responsible for reduced mammalian cell toxicity

When interacting with phospholipid in an aqueous environment, amphotericin B forms unusual structures of markedly reduced toxicity (Janoff et al. (1988) Proc. Natl. Acad. Sci. USA 85, 6122-6126). These structures, which appear ribbon-like by freeze-fracture electron microscopy (EM), are found exclusively at amphotericin B to lipid mole ratios of 1:3 to 1:1. At lower mole ratios they occur in combination with liposomes. Circular dichroism (CD) spectra revealed two distinct modes of lipid-amphotericin B interaction, one for liposomes and one for the ribbon-like structures. In isolated liposomes, amphotericin B which comprised 3-4 mole percent of the bulk lipid was monomeric and exhibited a hemolytic activity comparable to amphotericin B suspended in deoxycholate. Above 3-4 mole percent amphotericin B, ribbon-like structures emerged and CD spectra indicated drug-lipid complexation. Minimal inhibitory concentrations for Candida albicans of liposomal and complexed amphotericin B were comparable and could be attributed to amphotericin a release as a result of lipid breakdown within the ribbon-like material by a heat labile extracellular yeast product (lipase). Negative stain EM of the ribbon-like structures indicated that the ribbon-like appearance seen by freeze-fracture EM arises as a consequence of the cross-fracturing of what are aggregated, collapsed single lamellar, presumably interdigitated, membranes. Studies examining complexation of amphotericin B with either DMPC or DMPG demonstrated that headgroup interactions played little role in the formation of the ribbon-like structures. With these results we propose that ribbon-like structures result from phase separation of amphotericin B-phospholipid complexes within the phospholipid matrix such that amphotericin B release, and thus acute toxicity, is curtailed. Formation of amphotericin B-lipid structures such as those described here indicates a possible new role for lipid as a stabilizing matrix for drug delivery of lipophilic substances, specifically where a highly ordered packing arrangement between lipid and compound can be achieved.

Role of Lipid Polymorphism in Pulmonary Surfactant

The development of artificial surfactants for the treatment of respiratory distress syndrome (RDS) requires lipid systems that can spread rapidly from solution to the air-water interface. Because hydration-repulsion forces stabilize liposomal bilayers and oppose spreading, liposome systems that undergo geometric rearrangement from the bilayer (lamellar) phase to the hexagonal II (HII) phase could hasten lipid transfer to the air-water interface through unstable transition intermediates. A liposome system containing dipalmitoylphosphatidylcholine was designed; the system is stable at 23°C but undergoes transformation to the HII phase as the temperature increases to 37°C. The spreading of lipid from this system to the air-water interface was rapid at 37°C but slow at 23°C. When tested in vivo in a neonatal rabbit model, such systems elicited an onset of action equal to that of native human surfactant. These findings suggest that lipid polymorphic phase behavior may have a crucial role in the effective functioning of pulmonary surfactant.

The determination of liposome captured volume

Manipulating the process by which lipids assemble to form bilayer membranes has produced a myriad of protocol-dependent liposome types. For each of these systems the arrangement of bilayers is characteristic and can be described by parameters such as aqueous entrapment per mole lipid or captured volume, vesicle size distribution, the average number of lamellae per vesicle and shape. For specific applications as model systems or drug delivery systems specific characteristics are desired. Consequently over the years many techniques have evolved to better quantitate these parameters. Here we focus on and detail several methods to quantitate liposome captured volume. We also briefly describe the available methods to measure the other aforementioned physical properties and discuss their interdependency with captured volume.

A differential scanning calorimetry study of phosphocholines mixed with paclitaxel and its bromoacylated taxanes.

High sensitivity differential scanning calorimetry (DSC) was used to investigate the thermotropic phase properties of binary mixtures of disaturated phosphocholines (PCs) and alpha-bromoacyl taxane derivatives. The alpha-bromoacyl taxanes were synthesized as hydrolyzable hydrophobic prodrugs of paclitaxel. The PCs used were 1, 2-dimyristoyl-sn-glycero-3-phosphatidyl-choline (DMPC), 1, 2-dipalmitoyl-sn-glycero-3-phosphatidylcholine (DPPC) and 1, 2-distearoyl-sn-glycero-3-phosphatidylcholine (DSPC). The bromoacyl chain lengths of the taxane prodrugs were varied from 6 to 12 or 16 carbons. For comparison, paclitaxel and PC mixtures were also examined. DSC data from DPPC and bromoacyl taxane mixtures showed a complete abolition of the pretransition and significant broadening of the main phase transition with increasing amounts of bromoacyl taxane prodrugs. The effects were more pronounced with the long-chain compared to the short-chain prodrugs. Under equivalent DSC conditions, the short-chain DMPC showed greater changes in thermotropic phase behavior than with DPPC on taxane addition, suggesting an enhanced degree of association with the fluid-type bilayers. Under similar conditions, the long-chain DSPC bilayers showed a far less significant change in phase behavior on taxane addition than DPPC. These changes were also chain length-dependent for both the PCs and the taxane prodrugs. In contrast, PC and paclitaxel (lacking the acyl chain) mixtures under similar conditions showed insignificant changes in the endotherms, suggesting only slight insertion of the molecule into the PC bilayers. From the DSC data it is apparent that taxane prodrugs solvated in DMPC bilayers more than in DPPC and DSPC bilayers, and taxane prodrugs with longer acyl chains were able to associate with PCs better than those with shorter chain prodrugs. DSC data also suggest that paclitaxel was poorly associated with any of the PCs. In general, the amount of taxane association with bilayers decreased in order: DMPC > DPPC >> DSPC. In contrast, the transition enthalpy (DeltaH) of DMPC, DPPC, and DSPC mixtures with paclitaxel showed significantly lower enthalpies than with taxane prodrugs. Taken together, the DSC data suggest that the acyl chains of paclitaxel prodrugs have some access into the bilayers via alignment with the acyl chain of the PC component.

Interdigitation-fusion: a new method for producing lipid vesicles of high internal volume

Previously we demonstrated that fused phospholipid sheets can be formed from small unilamellar vesicles (SUVs) comprised of saturated symmetric chain lipids by exposing them to concentrations of ethanol sufficient to cause bilayer interdigitation (Boni et al. (1993) Biochim. Biophys. Acta 1146, 247-257). Here we report that these sheets spontaneously form large, predominately unilamellar vesicles, when exposed to temperatures above their main phase transition temperature (Tm). These vesicles, termed interdigitation-fusion vesicles (IFVs), have mean diameters between 1 and 6 microns, and, once produced, are stable both above and below the Tm of the lipid. The average captured volume of IFVs is dependent upon lipid chain length, the concentration of ethanol used to induce interdigitation-fusion, and size of the precursor liposomes. IFVs comprised of DPPC and DSPC had averaged captured volumes of 20-25 microliters/mumol lipid. IFVs produced from SUVs containing only DPPG or DPPC/DPPG mixtures had captured volumes equivalent to those made from pure DPPC SUVs indicating that charge can be introduced without consequence to the IFV process. Inclusion of cholesterol in precursor vesicles reduced IFV captured volume in a concentration dependent fashion by interfering with interdigitation. Cholesterol could be incorporated, however, into IFVs through admixture with the already formed phospholipid sheets producing far less comprise to captured volume. IFVs are useful as model systems or drug carriers, since their large internal volume allows for efficient encapsulation particularly with regard to compounds such as iodinated radiocontrast agents which otherwise interfere with vesicularization.

Curvature dependent induction of the interdigitated gel phase in DPPC vesicles

Ethanol causes biphasic melting behavior in saturated lecithins (Rowe (1983) Biochemistry 22, 3299-3305), a consequence of the formation of the stable interdigitated phase (Simon, S.A. and McIntosh, T.J. (1984) Biochim. Biophys. Acta 773, 169-172). The membrane systems studied to date have been large vesicle systems in which the membrane surface can be assumed to be locally planar. An immediate question arises as to whether surfaces of higher curvature interdigitate. To address this question we have prepared DPPC vesicles of varying diameters which we employed to determine the limiting size at which interdigitation occurs using ethanol as the inducer. We find that with decreasing vesicle size the concentration of ethanol necessary for the onset of interdigitation increases. Small isolated vesicles, at inducing concentrations of ethanol, do not stably interdigitate but rupture and coalesce into a viscous gel comprised of interdigitated lipid sheets. As discussed elsewhere (Ahl et al. (1992) Biophys. J. 243a) these sheets can be used as precursors for producing liposomes of large size and high internal volumes useful in drug delivery or modeling applications.

Hydrolyzable hydrophobic taxanes: synthesis and anti-cancer activities.

A series of taxane prodrugs with 2-bromoacyl chains attached at the 2′-position of the paclitaxel side chain, varying from six, eight, 12, 14 to 16 carbons in length, were synthesized, characterized and evaluated against human breast MCF-7 cancer cell line for their growth inhibitory (GI50) activities. The GI50 is the drug concentration required to inhibit cell growth by 50%. For comparison, hydrophobic taxanes varying in acyl chain lengths from six to 16 carbons were also synthesized and compared for their G050s with taxanes having equivalent bromoacyl chain lengths. The bromoacyl taxanes bearing six, eight and 12 carbon acyl chain lengths had GI50 values very similar to parent paclitaxel. The GI50 was 3 nM for three taxanes versus 1 nM for paclitaxel on the MCF-7 cell line. Increasing the acyl chain length to 14 or 16 carbons resulted in a significant decrease in cytotoxicity and an increase in the GI50 to 20 or 70 nM, respectively. In general, the GI50 values were directly related to the bromoacyl chain lengths in cultured tumor cells. Unlike bromoacyl taxanes, the taxanes lacking bromine in their acyl chain composition were 50- to 250-fold less active, suggesting that the heteroatom facilitated the hydrolysis of acyl chains to yield free paclitaxel. These differences in growth inhibitory activities may indirectly reflect differences in the susceptibility of the acyl chain to bromine-induced hydrolysis after association of the derivative with cell membranes. Liposome formulations of 2-bromoacyl taxanes bearing six, eight, 12 and 16 carbons were prepared and tested in SCID mice against a xenografted human ovcar-3 ovarian tumor. In vivo results showed that bromoacyl taxanes with a longer chain were therapeutically more efficacious than those with a short chain, presumably due to slow hydrolysis of the prodrug followed by sustained delivery of paclitaxel to the tumor.

Characterization of cholesterol hemisuccinate and α-tocopherol hemisucccinate vesicles

Abstract Cholesterol hemisuccinate (CHS) and α-tocopherol hemisuccinate (α-THS) were found to be capable of forming liposomes of multi- or single lamellar character. Such veiscles formed spontaneously, did not require the use of organic solvents and yielded high trapping efficiencies and captured volumes. Both CHS and α-THS systems greatly restricted the motion of intercalated spin labelled fatty acids, yet were more osmotically responsive than similar vesicle types comprised of phosphatidylcholine. Small angle X-ray diffraction measurements were consistent with veiscles possessing extremely weak interlamellar forces. CHS vesicles were found to remain intact in vivo, yet followed a pattern of distribution dissimilar to phosphatidylcholine vesicles.

ASSOCIATION AND RELEASE OF PROSTAGLANDIN E1 FROM LIPOSOMES

PGE1-lipid interactions were studied in several liposome systems. Data from both circular dichroic (CD) measurements and differential scanning calorimetry (DSC) indicated that PGE1 in the protonated form seeks the less polar environment of the lipid bilayer. CD measurements made on PGE1 in solution showed that the wavelength of maximum absorbance red shifted approximately 8 nm with decreasing solvent polarity. The CD spectrum of liposomal PGE1 prepared in pH 4.5 but not pH 7.2 buffer was also red shifted. There was no red shift in the CD spectrum of PGE1 detected at pH 4.5 in the absence of phospholipid. DSC measurements on DSPC bilayers prepared with 5 mol% PGE1 at pH 4.5 but not pH 7.2 revealed an almost complete loss of the pre-transition as well as broadening of the main phase transition. The amount of 3H-PGE1 initially associated with EPC, POPC or DSPC liposomes was determined using size exclusion filters and centrifugation. This amount was found to be dependent on the pH of the buffer (pH 4.5 >> pH 7.2) and fluidity of the bilayer (EPC = POPC > DSPC), but independent of the lamellarity of the liposome. In all cases, addition of cholesterol reduced the amount of PGE1 associated with the liposome. The time-dependent release of PGE1 from the liposomes was determined by rapidly diluting the sample 100-fold into pH 7.2 buffer. Lipid saturation was a key factor influencing this release. Gel-phase liposomes of DSPC showed a rapid initial release (t(1/2) < 2 min) of PGE1, corresponding to the amount in the outer monolayer, followed by a very slow, almost negligible release of the remaining PGE1. A rapid initial release also occurred in fluid-phase membranes, followed by a more gradual release of the remaining PGE1 over several hours. This release rate could be slowed by increasing the lamellarity of these liposomes, or adding cholesterol to decrease the fluidity of the membrane.

Polymorphic phase behavior of alpha-tocopherol hemisuccinate

Abstract From freeze-fracture electron microscopy and x-ray diffraction we show that α-tocopherol hemisuccinate (α-THS) is capable of polymorphic phase behavior, including the formation of the hexagonal II phase. The transition from bilayer to hexagonal phase was induced by changes in pH, the addition of Ca 2+ , or the inclusion tocopherol. Non-bilayer phases were found to begin below pH 7.5 with hexagonal phase predominating at pH 6.0 and below. The presence of tocopherol at 30 mol% at pH values otherwise favoring the bilayer phase was marked by the appearance of lipidic particles which gave way to purely hexagonal phase at 50 mol%. Ca 2+ added at pH 7.5 induced a complex mixture of dehydrated lamellar and hexagonal II phases. The kinetics of the pH induced transition, as determined by NBD-PE fluorescence and freeze-fracture electron microscopy, were rapid and increased with increasing temperature and decreasing vesicle size.