DIMENSIONAL ANALYSIS AND SCALE-UP IN THEORY AND INDUSTRIAL APPLICATION*

A comparative study between archaeosomes, lipid lamellar vesicles made from archaea polar lipids, and conventional phospholipids liposomes was carried out, aiming at evaluating the properties and the potential of archaeosomes as novel colloidal carriers for effective drug delivery to the skin. Betamethasone dipropionate (BMD)–loaded archaeosomes and conventional liposomes were prepared by the thin-lipid film and sonication procedures, using, respectively, archaeal lipids extracted from archaea Halobacterium salinarum and enriched soy phosphatidylcholine. Vesicular formulations were characterized by assessing vesicle size, zeta potential, incorporation efficiency, and morphology. In order to investigate the effect of the incorporation in the two different colloidal carrier systems on the (trans)dermal delivery of BMD, in vitro drug permeation studies through full-thickness pig skin were carried out by using Franz diffusion vertical cells by testing both archaeal and liposomal dispersions. Interestingly, archaeosomes appeared to be the most effective carriers for the model drug, achieveing a major drug penetration and accumulation in the skin strata, especially in the epidermis. This can, presumably, be due to the enhanced archaeosomal bilayer fluidity, as indicated by the rheological studies that provided insight into the viscoelastic properties of all the studied systems. The available data suggest that suitably developed archaeosomes may hold great promise as delivery vehicles for topical applications.     

Safety of archaeosome adjuvants evaluated in a mouse model

Archaeosomes, liposomes prepared from the polar ether lipids extracted from Archaea, demonstrate great potential as immunomodulating carriers of soluble antigens, promoting humoral and cell mediated immunity in the vaccinated host. The safety of unilamellar archaeosomes prepared from the total polar lipids (TPL) of Halobacterium salinarum, Methanobrevibacter smithii or Thermoplasma acidophilum was evaluated in female BALB/c mice using ovalbumin (OVA) as the model antigen. Groups of 6-8 mice were injected (0.1 mL final volume) subcutaneously at 0 and 21 days, with phosphate buffered saline (PBS), 11 microg OVA in PBS, 1.25 mg of antigen-free archaeosomes in PBS (ca 70 mg/kg body wt), or PBS containing 11-20 microg OVA encapsulated in 1.25mg archaeosomes. Animals were monitored daily for injection site reactions, body weight,temperature and clinical signs of adverse reactions. Sera were collected on days 1, 2, 22, and 39 for analyses of creatine phosphokinase. Mice were sacrificed on 39 d, sera were collected for biochemical analyses, and major organs (liver, spleen, kidneys, heart, lungs) were weighed and examined macroscopically. There were no indications of adverse reactions or toxicity associated with any of the archaeosome adjuvants. None of the antigen-free archaeosomes elicited significant anti lipid antibodies when subcutaneously injected (1 mg each at 0, 1, 2, and 4 weeks) in mice, although anti H. salinarum lipid antibodies were detected. These antilipid antibodies cross-reacted with the TPL of T. acidophilum archaeosomes but not with the TPL of M. smithii archaeosomes nor with lipids of ester liposomes made from L-alpha-dimyristoylphosphatidylcholine (DMPC), L-alpha-dimyristoylphosphatidylglycerol (DMPG), and cholesterol (CHOL). In vitro hemolysis assay on mouse erythrocytes indicated no lysis with M. smithii or T. acidophilum archaeosomes at up to 2.5 mg/mL concentration. At this concentration, H. salinarum archaeosomes and DMPC/DMPG/CHOL ester liposomes caused about 2% and 4% hemolysis, respectively. Based on this mouse model evaluation, archaeosomes are well-tolerated and appear relatively safe for potential vaccine applications.     

Stability of Liposomes Prepared from the Total Polar Lipids of Methanosarcina Mazei is Affected by the Specific Salt form of the Lipids

Abstract

The total polar lipids (TPL) extracted from the archaeobacterium Metha-nosarcina mazei were predominantly in the form of sodium and potassium salts. Upon passage of this natural salt form of TPL (ns-TPL) through a silica gel G column (s-TPL), the molar ratio of the monovalent cations, sodium plus potassium, to that of the divalent cations, magnesium plus calcium, decreased from about 11:1 to 2:1. Liposomes (archaeosomes) made from ns-TPL were unable to efficiently retain low molecular weight aqueous markers such as 5(6)-carboxyfluorescein (CF). In phosphate buffered saline (PBS, pH 7.14), between 60-90% and 90-100% of entrapped CF leaked out during 21 h storage at room temperature (20-22°) and 3 h at 50°, respectively. However, archaeosomes made with the s-TPL, as well as from TPL converted to the salt forms of predominantly sodium, potassium, calcium or magnesium, were significantly less leaky. The archaeosomes made with s-TPL were the most stable, showing less than 7% leakage after 21 h at room temperature and only 14% leakage of CF after 3 h at 50°. The stability of s-TPL archaeosomes (21 h, 20-22°) was not affected when Tris-HCI buffer (pH 7.4) was used instead of PBS. However, the inclusion of 1 or 10 mM EGTA in the Tris-HCI buffer increased the amount of CF leaked, to about 25% and 100%, respectively. Except for some differences in phosphatidylserine and phosphati-dylglycerol, the lipid compositions of ns-TPL, s-TPL, and the magnesium form of TPL were similar, as determined by thin layer chromatography of labeled lipids. Archaeosomes prepared from s-TPL and ns-TPL had -“P NMR spectra that were similar to each other, but distinct from those of vesicles prepared from the ester lipid dimyristoylphosphatidylcholine. The types and relative proportions of cations associated with the lipids of M. mazei prior to their hydration and vesicle formation have a major influence, although other factors such as lipid composition may have an effect, on the permeability of the bilayer to low molecular weight compounds.     

Bipolar tetraether archaeosomes exhibit unusual stability against autoclaving as studied by dynamic light scattering and electron microscopy

The stability of liposomes made of the polar lipid fraction E (PLFE) isolated from the thermoacidophilic archaeon Sulfolobus acidocaldarius against autoclaving has been studied by using dynamic light scattering and transmission electron microscopy. PLFE lipids have structures distinctly different from those derived from eukaryotes and prokaryotes. PLFE lipids are bipolar tetraether molecules and may contain up to four cyclopentane rings in each of the two dibiphytanyl chains. In the pH range 4-10, PLFE-based archaeosomes, with and without polyethyleneglycol- and maleimide-lipids, are able to retain vesicle size, size distribution, and morphology through at least six autoclaving cycles. The cell growth temperature (65 °C vs. 78 °C), hence the number of cyclopentane rings in the hydrocarbon chains, does not affect this general conclusion. By contrast, at the same pH range, most conventional liposomes made of monopolar diester lipids and cholesterol or pegylated lipids cannot withhold vesicle size and size distribution against just one cycle of autoclaving. At pH < 4, the particle size and polydispersity of PLFE-based archaeosomes increase with autoclaving cycles, suggesting that aggregation or membrane disruption may have occurred at extreme acidic conditions during heat sterilization. Under high salt conditions, dye leakage from PLFE archaeosomes due to autoclaving is significantly less than that from pegylated liposomes composed of conventional lipids. The ability to maintain vesicle integrity after multiple autoclaving cycles indicates the potential usefulness of utilizing PLFE-based archaeosomes as autoclavable and durable drug (including genes, peptides, vaccines, siRNA) delivery vehicles.     

A structural comparison of the total polar lipids from the human archaea Methanobrevibacter smithii and Methanosphaera stadtmanae and its relevance to the adjuvant activities of their liposomes.

Mice were immunized with bovine serum albumin (BSA) entrapped within archaeosomes (i.e. liposomes) composed of the total polar lipids (TPL) from the two methanogenic archaea common to the human digestive tract. Methanobrevibacter smithii archaeosomes boosted serum anti-BSA antibody to titers comparable to those achieved with Freund's adjuvant, whereas Methanosphaera stadtmanae archaeosomes were relatively poor adjuvants. An explanation for this difference was sought by analysis of the polar lipid composition of each archaeobacterium. Fast atom bombardment mass spectrometry and NMR analyses of the purified lipids revealed a remarkable similarity in the ether lipid structures present in each TPL extract. However, the relative amounts of each lipid species varied dramatically. The phospholipid fraction in M. stadtmanae TPL was dominated by archaetidylinositol (50 mol% of TPL) and the glycolipid fraction by beta-Glcp-(1,6)-beta-Glcp-(1,1)-archaeol (36 mol%), whereas in M. smithii extracts, both caldarchaeol and archaeol lipids containing a phosphoserine head group were relatively abundant. Liposomes prepared from purified archaetidylinositol and from M. stadtmanae TPL supplemented with increasing amounts of phosphatidylserine elicited poor humoral responses to encapsulated BSA. A dramatic loss in the adjuvanticity of M. smithii archaeosomes was seen upon incorporation of 36 mol% of the uncharged lipid diglucosyl archaeol and, to a lesser extent, of 50 mol% of archaetidylinositol. Interestingly, the relative rates of uptake of M. smithii and M. stadtmanae archaeosomes by phagocytic cultures in vitro were similar. Thus, the lipid composition may influence archaeosome adjuvanticity, particularly a high diglucosyl archaeol and/or archaetidyl inositol content, resulting in a low adjuvant activity.     

Isopranoid- and dipalmitoyl-aminophospholipid adjuvants impact differently on longevity of CTL immune responses

The success of lipid membranes as cytotoxic T-cell (CTL) adjuvants requires targeted uptake by antigen-presenting cells (APCs) and delivery of the antigen cargo to the cytosol for processing. To target the phosphatidylserine (PS) receptor of APCs, we prepared antigen-loaded liposomes containing dipalmitoylphosphatidylserine and archaeal lipid liposomes (archaeosomes), containing an equivalent amount of archaetidylserine, and compared their ability to promote short and long-term CTL activity in animals. CTL responses were enhanced by the incorporation of PS into phosphatidylcholine/cholesterol liposomes and, to a lesser extent, into phosphatidylglycerol/cholesterol liposomes, that correlated to the amount of surface amino groups reactive with trinitrobenzoyl sulfonate. Archaeosomes contrasted to the liposome adjuvants by exhibiting higher amounts of surface amino groups and inducing superior shorter and, especially, longer-term CTL responses. The incorporation of dipalmitoyl lipids into archaeosomes induced instability and prevented long-term, but not short-term, CTL responses in mice. The importance of glycero-lipid cores (isopranoid versus dipalmitoyl) to the longevity of the CTL response achieved was shown further by incorporating dipalmitoyl phosphatidylethanolamine (DPPE) or equivalent amounts of synthetic archaetidylethanolamine (AE) into archaeosome adjuvants. Both DPPE and AE at equivalent (5 mol%) concentrations enhanced the rapidity of CTL responses in mice, indicating the importance of the head group in the short term. In the longer term, 5% of DPPE (but not 5% of AE) was detrimental. In addition to head-group effects critical to the potency of short-term CTL responses, the longer term CTL adjuvant properties of archaeosomes may be ascribed to stability imparted by the archaeal isopranoid core lipids.     

Archaeosomes varying in lipid composition differ in receptor-mediated endocytosis and differentially adjuvant immune responses to entrapped antigen

Archaeosomes prepared from total polar lipids extracted from six archaeal species with divergent lipid compositions had the capacity to deliver antigen for presentation via both MHC class I and class II pathways. Lipid extracts from Halobacterium halobium and from Halococcus morrhuae strains 14039 and 16008 contained archaetidylglycerol methylphosphate and sulfated glycolipids rich in mannose residues, and lacked archaetidylserine, whereas the opposite was found in Methanobrevibacter smithii, Methanosarcina mazei and Methanococcus jannaschii. Annexin V labeling revealed a surface orientation of phosphoserine head groups in M. smithii, M. mazei and M. jannaschii archaeosomes. Uptake of rhodamine-labeled M. smithii or M. jannaschii archaeosomes by murine peritoneal macrophages was inhibited by unlabeled liposomes containing phosphatidylserine, by the sulfhydryl inhibitor N-ethylmaleimide, and by ATP depletion using azide plus fluoride, but not by H. halobium archaeosomes. In contrast, N-ethylmaleimide failed to inhibit uptake of the four other rhodamine-labeled archaeosome types, and azide plus fluoride did not inhibit uptake of H. halobium or H. morrhuae archaeosomes. These results suggest endocytosis of archaeosomes rich in surface-exposed phosphoserine head groups via a phosphatidylserine receptor, and energy-independent surface adsorption of certain other archaeosome composition classes. Lipid composition affected not only the endocytic mechanism, but also served to differentially modulate the activation of dendritic cells. The induction of IL-12 secretion from dendritic cells exposed to H. morrhuae 14039 archaeosomes was striking compared with cells exposed to archaeosomes from 16008. Thus, archaeosome types uniquely modulate antigen delivery and dendritic cell activation.     

Uptake of Archaeobacterial Liposomes and Conventional Liposomes by Phagocytic Cells

Abstract

Liposomes in the 200 nm size range were prepared from the ether lipids extracted from various Archaeobacteria (coined archaeosomes), and from conventional lipids. The entrapment of peroxidase or carboxyfluorescein was used to compare the in vitro uptake of various liposomes by murine peritoneal macrophages, J774A.1 macrophages and several non phagocytic cell lines. While liposomes composed of ester lipids dipalmitoylphosphatidylcholine, or dimyristoylphosphatidylcholine: dimyristoylphosphatidylglycerol: cholesterol (1.8:0.2:1.5, molar ratio) were taken up by macrophage species, the uptake of archaeosomes was 3 to 53 times greater. Uptake by non phagocytic HEp-2, HeLa, and EJ/28 cells was considerably less. Evidence from time-course studies using cytochalasins B+D, sub-optimal temperature or formaldehyde treatments of macrophages, indicated that the archaeosomes lost structural integrity following internalization within the J774A. 1 phagocytic cells. No cytotoxicity was observed in viability or growth assays with J774A. 1 cells, using high doses of three representative types of archaeosomes and one type of conventional-liposome. Therefore, archaeosomes may be well suited to applications where phagocytic cells are a target site.     

Synthesis of archaeal glycolipid adjuvants-what is the optimum number of sugars?

As part of a programme to optimize the use of archaeal-lipid liposomes (archaeosomes) as vaccine adjuvants, we present the synthesis and immunological testing of an oligomeric series of mannose glycolipids (Manp(1-5)). To generate the parent archaeol alcohol precursor, the polar lipids extracted from the archaeon Halobacterium salinarum were hydrolyzed to remove polar head groups, and the archaeol so generated partitioned into diethyl ether. This alcohol was then iteratively glycosylated with the donor 2-O-acetyl-3,4,6-tri-O-benzyl-alpha/beta-d-mannopyranosyl trichloroacetimidate to yield alpha-Manp-(1-->2) oligomers. A starch-derived trimer was also synthesized as a control. To promote hydration and form stable archaeosomes, an archaeal anionic lipid archaetidylglycerol (AG) was included in a 4:1 molar ratio. Archaeosomes prepared from Manp(1-2)-AG were recovered at only 34-37%, whereas Manp(3-4)-AG recoveries were 72-77%. Lipid recovery following hydration of Manp(5)-AG archaeosomes declined to 34%, indicating an optimum of 3-4 Manp units for bilayer formation. The CD8(+) T cell response in mice immunized with Manp(3-5) archaeosomes containing ovalbumin was highest for Manp(4) and declined for Manp(3) and Manp(5), revealing an optimum length of four unbranched units. The starch-derived trimer was more active than the Manp oligomers, suggesting the involvement of either a general binding lectin on antigen-presenting cells with highest affinity for triglucose or multiple lectin receptors.     

Archaeobacterial Ether Lipid Liposomes (Archaeosomes) as Novel Vaccine and Drug Delivery Systems

ABSTRACT:?

Liposomes are artificial, spherical, closed vesicles consisting of one or more lipid bilayer(s). Liposomes made from ester phospholipids have been studied extensively over the last 3 decades as artificial membrane models. Considerable interest has been generated for applications of liposomes in medicine, including their use as diagnostic reagents, as carrier vehicles in vaccine formulations, or as delivery systems for drugs, genes, or cancer imaging agents. The objective of this article is to review the properties and potential applications of novel liposomes made from the membrane lipids of Archaeo-bacteria (Archaea). These lipids are unique and distinct from those encountered in Eukarya and Bacteria. Polar glycerolipids make up the bulk of the membrane lipids, with the remaining neutral lipids being primarily squalenes and other hydrocarbons. The polar lipids consist of regularly branched, and usually fully saturated, phytanyl chains of 20, 25, or 40 carbon length, with the 20 and 40 being most common. The phytanyl chains are attached via ether bonds to the sn-2,3 carbons of the glycerol backbone(s). It has been shown only recently that total polar lipids of archaeobacteria, and purified lipid fractions therefrom, can form liposomes. We refer to liposomes made with any lipid composition that includes ether lipids characteristic of Archaeobacteria as archaeosomes to distinguish them from vesicles made from the conventional lipids obtained from eukaryotic or eubacterial sources or their synthetic analogs. In general, archaeosomes demonstrate relatively higher stabilities to oxidative stress, high temperature, alkaline pH, action of phospholipases, bile salts, and serum proteins. Some archaeosome formulations can be sterilized by autoclaving, without problems such as fusion or aggregation of the vesicles. The uptake of archaeosomes by phagocytic cells can be up to 50-fold greater than that of conventional liposome formulations. Studies in mice have indicated that systemic administration of several test antigens entrapped within certain archaeosome compositions give humoral immune responses that are comparable to those obtained with the potent but toxic Freund's adjuvant. Archaeosome compositions can be selected to give a prolonged, sustained immune response, and the generation of a memory response. Tissue distribution studies of archaeosomes administered via various systemic and peroral routes indicate potential for targeting to specific organs. All in vitro and in vivo studies performed to date indicate that archaeosomes are safe and do not invoke any noticeable toxicity in mice. The stability, tissue distribution profiles, and adjuvant activity of archaeosome formulations indicate that they may offer a superior alternative to the use of conventional liposomes, at least for some biotechnology applications.     

Topical delivery and in vivo antileishmanial activity of paromomycin-loaded liposomes for treatment of cutaneous leishmaniasis

The present study aimed to evaluate the potential of liposomes loaded with paromomycin (PA), an aminoglycoside antibiotic associated with poor skin penetration, for the topical treatment of cutaneous leishmaniasis (CL). Fluid liposomes were prepared and characterized for particle size, zeta potential, and drug entrapment. Permeation studies were performed with two in vitro models: intact and stripped skin. The antileishmanial activity of free and liposomal PA was evaluated in BALB/c mice infected by Leishmania (L.) major. Drug entrapment ranged from 10 to 14%, and the type of vesicle had little influence on this parameter. Particle size and polydispersity index of the vesicles composed by phosphatidylcholine (PC) and PC/cholesterol (Chol) ranged from of 516 to 362?nm and 0.7 to 0.4, respectively. PA permeation across intact skin was low, regardless of the formulation tested, while drug penetration into skin (percent of the applied dose) from PC (7.2?±?0.2%) and PC/Chol (4.8?±?0.2%) liposomes was higher than solution (1.9?±?0.1%). PA-loaded liposomes enhanced in vitro drug permeation across stripped skin and improved the in vivo antileishmanial activity in experimentally infected mice. Our findings suggest that the liposomes represent a promising alternative for the topical treatment of CL using PA.     

Archaeosomes made of Halorubrum tebenquichense total polar lipids: a new source of adjuvancy

Background  

Archaeosomes (ARC), vesicles prepared from total polar lipids (TPL) extracted from selected genera and species from the Archaea domain, elicit both antibody and cell-mediated immunity to the entrapped antigen, as well as efficient cross priming of exogenous antigens, evoking a profound memory response. Screening for unexplored Archaea genus as new sources of adjuvancy, here we report the presence of two new Halorubrum tebenquichense strains isolated from grey crystals (GC) and black mood (BM) strata from a littoral Argentinean Patagonia salt flat. Cytotoxicity, intracellular transit and immune response induced by two subcutaneous (sc) administrations (days 0 and 21) with BSA entrapped in ARC made of TPL either form BM (ARC-BM) and from GC (ARC-GC) at 2% w/w (BSA/lipids), to C3H/HeN mice (25 μg BSA, 1.3 mg of archaeal lipids per mouse) and boosted on day 180 with 25 μg of bare BSA, were determined.     

Structural characterization of archaeal lipid mucosal vaccine adjuvant and delivery (AMVAD) formulations prepared by different protocols and their efficacy upon intranasal immunization of mice

Intranasal administration of ovalbumin (OVA) formulated in an archaeal lipid mucosal vaccine adjuvant and delivery (AMVAD) system prepared by the addition of CaCl2 to small unilamellar archaeosomes (liposomes made from archaeal polar lipids) containing encapsulated OVA, was recently shown to elicit strong and sustained OVA-specific mucosal and systemic immune responses. In this study, we show that the centrifugation/washing and antigen quantization steps required in the standard protocol for obtaining OVA/AMVAD model vaccine formulations can be eliminated by using simpler protocols such as admixing OVA with preformed empty archaeosomes, or by changing the starting ratio (w/w) of archaeal lipid to antigen at the archaeosome preparation stage, prior to the addition of CaCl2 to convert to the AMVAD structures. Irrespective of the vaccine preparation protocol, the AMVAD particle typically comprised of larger spherical structures that had aggregated like a bunch of grapes, and it contained aqueous compartment(s). The anti-OVA IgA antibody responses in vaginal wash, nasal wash, serum, and bile samples, and the anti-OVA IgG antibody responses in sera, in mice intranasally immunized with the OVA/AMVAD formulations prepared by the simplified or the standard protocols, were comparable.     

Drug-Carrier and Stability Properties of the Long-Lived Lipid Vesicles. Cryptosomes,in Vitro and in Vivo

Abstract

Lipid vesicles composed of phosphatidylcholine and suitable polyoxyethylene-derivat-ives of phosphatidylethanolamine (cryptosomes) remain in circulation 8–10 times longer than standard liposomes after an i.v. administration in mice. In contrast to previous belief, this longevity is not destroyed by the net charges on the lipid vesicle surface and is not a direct consequence of the high surface hydrophilicity; also bilayer fluidity is not an obstacle for the attainment of long circulation times. All these three factors, however, can affect the effectiveness of the drug encapsulation into lipid vesicles and the stability of the resulting carrier suspensions. Terminal head-group modifications, moreover, can affect the final carrier and drug distribution after vesicle applications in vivo and lead to accumulation in certain body subsites, such as the gut.     

Incorporation of the Lipopolysaccharide and Polysaccharide from Aeromonas Salmonicida Into Liposomes

Abstract

Incorporation of the lipopolysaccharide (LPS) and polysaccharide (PS) from Aeromonas salmonicida into liposomes of varying lipid composition and lamellarity as a function of the LPS and PS concentration was investigated. Positively-charged multilamellar vesicles (MLV) composed of phosphatidylcholine (PC): cholesterol (CH): stearylamine (SA) (6:3:1, mole: mole: mole) incorporated the LPS more readily than negatively-charged liposomes composed of PC: CH: phosphatidylglycerol (PG) in the same molar ratios. Regardless of surface charge, more LPS was incorporated into MLV than into vesicles prepared by relatively mild sonication (SV) or large unilamellar vesicles prepared via extrusion through 200 nm pore size filters (LUVET₂₀₀). In contrast, SV and LUVET₂₀₀ incorporated more PS than did MLV. The total amount of liposomally-incorporated LPS or PS among the three vesicle types was proportional to the concentration of antigen in the hydrating solutions.     

Liposomes for (trans)dermal drug delivery: the skin-PVPA as a novel in vitro stratum corneum model in formulation development

Penetration potential of vesicles destined for trans(dermal) administration remains to be of great interests both in respect to drug therapy and cosmetic treatment. This study investigated the applicability of the phospholipid vesicle-based permeation assay (PVPA) as a novel in vitro skin barrier model for screening purposes in preformulation studies. Various classes of liposomes containing hydrophilic model drug were examined, including conventional liposomes (CLs), deformable liposomes (DLs) and propylene glycol liposomes (PGLs). The size, surface charge, membrane deformability and entrapment efficiency were found to be affected by the vesicle lipid concentration, the presence of the surfactant and propylene glycol. All liposomes exhibited prolonged drug release profiles with an initial burst effect followed by a slower release phase. The permeation of the drug from all of the tested liposomes, as assessed with the mimicked stratum corneum – PVPA model, was significantly enhanced as compared to the permeability of the drug in solution form. Although the DLs and the PGLs exhibited almost the same membrane elasticity, the permeability of the drug delivered by PGLs was higher (6.2?×?10^?6?cm/s) than DLs (5.5?×?10^?6?cm/s). Therefore, this study confirmed both the potential of liposomes as vesicles in trans(dermal) delivery and potential of the newly developed skin-PVPA for the screening and optimization of liposomes at the early preformulation stage.     

Effects of plasmenylethanolamine on the dynamic properties of the hydrocarbon region of mixed phosphatidylcholine-phosphatidylethanolamine aqueous dispersions. A spin label study

Spin-labeled aqueous dispersions of total phospholipid extracts from whole brains of hibernating hamsters and rats chronically consuming ethanol were compared with dispersions from control animals. Order parameter values and approximate rotational correlation times for the nitroxide spin labels indicated that ethanol consumption results in an adaptive decrease in bilayer membrane fluidity, while hibernation produces increases in fluidity. Since it has been proposed that changes in plasmenylethanolamine such as those seen with hibernation play a role in the homeoviscous adaptation of brain membranes, electron spin resonance studies using aqueous phospholipid dispersions containing equimolar mixtures of rat brain phosphatidylethanolamine and phosphatidylcholine, or synthetic dioleylphosphatidylcholine and dioleylphosphatidylethanolamine, and brain plasmenylethanolamine were performed. The molar amount of plasmenylethanolamine was varied within the ethanolamineglycerophospholipid fraction of each dispersion. Order parameter values of spin labels in liposomes containing brain phosphatidylcholine and phosphatidylethanolamine increased in parallel with increases in plasmenylethanolamine concentrations, indicating that fluidity was decreasing. Liposomes composed of synthetic dioleyl phospholipids exhibited biphasic changes in order parameter (S) values as plasmenylethanolamine replaced the diacyl form. Below 30% (mol%) plasmenylethanolamine, S values decreased, while above 30%, S values were seen to increase; indicating an initial fluidization, followed by a decrease in fluidity.     

Enhancement of Galantamine HBr Skin Permeation Using Sonophoresis and Limonene-Containing PEGylated Liposomes

This study aimed to investigate the effect of low-frequency sonophoresis (SN) and limonene-containing PEGylated liposomes (PL) on the transdermal delivery of galantamine HBr (GLT). To evaluate the skin penetration mechanism, confocal laser scanning microscopy (CLSM), Fourier transform infrared spectroscopy (FTIR), and differential scanning calorimetry (DSC) were employed. The application of SN led to more GLT penetration into and through the skin than GLT solution alone. The liposomes also improved GLT permeation, and 2% limonene-containing PL (PL-LI2%) exhibited the highest GLT permeation, followed by PL-LI1%, PL-LI0.1%, and PL. The CLSM images of PL-LI2% resulted in the highest fluorescence intensity of fluorescent hydrophilic molecules in the deep skin layer, and the rhodamine PE-labeled liposome membrane was distributed in the intercellular region of the stratum corneum (SC). PL-LI2% induced significant changes in intercellular lipids in the SC, whereas SN had no effect on intercellular lipids of the SC. DSC thermograms showed that the greatest decrease in the lipid transition temperature occurred in PL-LI2%-treated SC. SN might improve drug permeation through an intracellular pathway, while limonene-containing liposomes play an important role in delivering GLT through an intercellular pathway by increasing the fluidity of intercellular lipids in the SC. Moreover, a small vesicle size and high membrane fluidity might enhance the transportation of intact vesicles through the skin.     

Threshold effects on the lectin-mediated aggregation of liposomes: Influence of the diameter of the liposomes

Summary It had previously been found that small unilamellar liposomes of ca. 0.03 m diameter which bear synthetic cholesterol-containing glycolipids may be aggregated by an appropriate lectin [8]. Where studied, threshold effects have been observed in that the amount of glycolipid incorporated in the liposomes must exceed a certain minimum concentration in order for aggregation to occur [3, 8, 9, 13, 14]. Threshold effects of this type may be important in mediating cell-cell and virus-cell interactions. However, before studies with small unilamellar liposomes are useful as a model for these recognition and binding phenomena, it must be shown that the observed threshold effects are not associated with the very small radius of curvature of these liposomes. This article reports that larger liposomes of average diameter 0.26 and 0.45 m which contain the synthetic glycolipidl also show threshold effects when aggregated with the galactose binding lectin ricin agglutinin. Under conditions where more than 1% (mole) glycolipid is required to support the aggregation of the smallest liposomes, those of intermediate size require only 0.18% (mole) while the largest liposomes examined require between 0.095 and 0.15% (mole) depending on the method of preparation.     

Modified in vivo behavior of liposomes containing synthetic glycolipids

Liposomes with synthetic saccharide determinants were prepared from synthetic cholesterol conjugates of D-mannose and 6-amino-6-deoxy-D-mannose and labeled with [⁵¹Cr]chromate. The kinetics and tissue distribution of label in mice were determined after footpad and subcutaneous injection. Liposomes bearing either of these saccharide determinants greatly increased retention of label at the injection sites compared to control liposomes, which contain no glycolipid, and to free [⁵¹Cr]chromate. Draining lymph nodes contained small fractions of the injected radioactivity but in some cases this retention was saccharide-dependent and highly concentrated. These results show that incorporation of synthetic glycolipids can substantially alter the in vivo lifetime and distribution of liposomes outside the bloodstream. Such surface-modified liposomes may be useful for sustained release or selective delivery of therapeutic or diagnostic agents.