Repeated injection of pegylated liposomal antitumour drugs induces the disappearance of the rapid distribution phase

Upon repeated administration, empty pegylated liposomes lose their long‐circulating characteristics, referred to as the accelerated blood clearance (ABC) phenomenon. To investigate whether cytotoxic drug‐containing pegylated liposomes could also elicit a similar phenomenon, two pegylated liposomal antitumour drugs (doxorubicin and mitoxantrone) were prepared, and they were administrated twice in the same animals with a 10‐day interval at a dose level of 8 mg kg^?1 (pegylated liposomal doxorubicin) and 4 mg kg^?1 (pegylated liposomal mitoxantrone). By comparing the overall pharmacokinetics after a single‐dose injection with that in animals treated with two doses, it was surprising to find that repeated administration of pegylated liposomal antitumour drugs caused the disappearance of rapid distribution phase instead of the ABC phenomenon, resulting in the conversion of a two‐compartment model to a one‐compartment model. Further investigation revealed that repeated injection induced the decreased uptake of liposomal antitumour drugs by the spleen at the early time point of 0.5–8 h after injection. In contrast, the deposition of liposomal antitumour drugs into liver was not affected. Therefore, the disappearance of the rapid distribution phase might be related to the reduced spleen uptake at the early time point.     

Liposomal topotecan formulation with a low polyethylene glycol grafting density: pharmacokinetics and antitumour activity

Objectives PEGylated liposomes could evade recognition by the reticulo‐endothelial system and prolong the circulation time of vesicles, resulting in enhanced targeting efficiency and antitumour effect. Typically, vesicles are modified with distearoylphosphatidylethanolamine (DSPE)‐polyethylene glycol (PEG) at a high PEG grafting density. However, long circulation time and slow drug release rate might induce severe hand‐foot syndrome in clinical practice. In this study, a liposomal topotecan formulation with a low PEG grafting density was prepared and its pharmacokinetics, acute toxicity and antitumour effect were investigated. Methods Topotecan was loaded into liposomes using an ammonium sulfate gradient. The resulting formulation was injected to healthy Wistar rats at different dose levels to investigate whether its clearance followed linear kinetics. Biodistribution was performed in Lewis lung cancer‐bearing mice. The acute toxicity was evaluated in healthy mice and beagle dogs. To compare the antitumour effects of different formulations and dose schedule, RM‐1 prostate, Lewis lung, H446 and L1210 cancer models were used. Key findings Topotecan could be encapsulated into low DSPE‐PEG liposomes with ～100% loading efficiency. The clearance of the liposomal formulation followed linear kinetics at a dose level ranging from 0.5 to 4 mg/kg despite the fact that the vesicles were coated at a low PEG density. Compared with free topotecan the liposomal formulation preferentially accumulated into tumour zones instead of normal tissues. Both formulations could rapidly accumulate into liver and tumour, but the liposomal formulation was cleared from tissues at a slow rate relative to the conventional formulation. In rats and beagle dogs, liposomal formulations could not induce skin toxicity. In all the tumour models, smaller split doses were more therapeutically active than larger doses when the overall dose intensity was equivalent. Conclusions This has been the first report that plasma kinetics of a liposomal formulation with a low PEG density followed linear kinetics. Moreover, due to its short circulation half‐life, the formulation did not induce skin toxicity. Our data revealed that the dose schedule of liposomal drugs should be adjusted in accordance with the biophysical and biological properties of the formulations to achieve the optimal therapeutic efficacy.     

Use of polyglycerol (PG), instead of polyethylene glycol (PEG), prevents induction of the accelerated blood clearance phenomenon against long-circulating liposomes upon repeated administration

The accelerated blood clearance (ABC) phenomenon accounts for the rapid systemic clearance of PEGylated nanocarriers upon repeated administrations. IgM production against the polyethylene glycol (PEG) coating in PEGylated liposomes is now known to be responsible for such unexpected pharmacokinetical alterations. The ABC phenomenon poses a remarkable clinical challenge by reducing the therapeutic efficacy of encapsulated drugs and causing harmful effects due to the altered tissue distribution pattern of the drugs. In this study, we investigated the in vivo performance of liposomes modified with polyglycerol (PG) upon repeated injection, and the in vivo therapeutic efficacy of such liposomes when they encapsulated a cytotoxic agent, doxorubicin (DXR). Repeated injection of PEG-coated liposomes in rats induced the ABC phenomenon, while repeated injection of PG-coated liposomes did not. In addition, DXR-containing PG-coated liposomes showed antitumor activity that was superior to that of free DXR and similar to that of DXR-containing PEG-coated liposomes upon repeated administration. These results indicate that polyglycerol (PG) might represent a promising alternative to PEG via enhancing the in vivo performance of liposomes by not eliciting the ABC phenomenon upon repeated administration.     

Encapsulation of vinorelbine into cholesterol-polyethylene glycol coated vesicles: drug loading and pharmacokinetic studies

Objectives Pegylated liposome formulations of vinorelbine with prolonged circulation half‐life (t½) are desirable. However, DSPE‐PEG could affect vinorelbine loading into vesicles due to electrostatic interactions. To resolve this problem, chol‐PEG was used to prepare pegylated liposomal vinorelbine and the factors affecting drug loading and plasma pharmacokinetics were investigated. Methods Vinorelbine was loaded into liposomes using a novel triethylamine 5‐sulfosalicylate gradient. The effects of cholesterol and chol‐PEG on drug loading were investigated. Pharmacokinetic studies were performed in normal KunMing mice treated with different liposomal vinorelbine formulations. To clarify the effects of chol‐PEG on membrane permeability, drug release experiments were performed based on the fluorescence dequenching phenomenon of a fluorescence marker. Key findings In contrast to DSPE‐PEG, even at high PEG grafting density (～8.3 mol%), chol‐PEG had no effect on vinorelbine loading into HSPC/cholesterol (3 : 1, mass ratio) vesicles. However, for the formulations with low cholesterol content (HSPC/cholesterol 4 : 1), loading efficiency decreased with increasing chol‐PEG content. In vivo, the vinorelbine t½ of low cholesterol formulations decreased with increasing chol‐PEG content, but for high cholesterol liposomes, the maximum vinorelbine t½ was achieved at ～3 mol% chol‐PEG grafting density. The resulting vinorelbine circulation t½ was ～9.47 h, which was greater than that of non‐pegylated liposomes (～5.55 h). Drug release experiments revealed that chol‐PEG might induce membrane defects and concomitant release of entrapped marker, especially at high chol‐PEG density. Conclusions Through the investigation of the effects of chol‐PEG and cholesterol, an optimum pegylated liposomal vinorelbine formulation with prolonged t½ was achieved. In plasma, the membrane defect induced by chol‐PEG may counteract the long circulation characteristics that chol‐PEG afforded. When these two opposite effects reached equilibrium, the maximum vinorelbine t½ was achieved.     

Repeated injections of PEGylated liposomal topotecan induces accelerated blood clearance phenomenon in rats

The "accelerated blood clearance (ABC) phenomenon" of PEGylated liposomes following multiple injections has been reported recently. This immunogenicity poses a problem for research into liposomes and hinders their clinical application. However, since doxorubicin liposomes and mitoxantrone liposomes have been reported to fail to induce the ABC phenomenon, some people believe that cytotoxic drugs loaded liposomes will not produce this ABC phenomenon under multiple-dosing regimens. Nevertheless, in the present study, we report that a first injection of the PEGylated liposomal topotecan (a cell cycle-specific drug for the S phase) still produced a strong ABC phenomenon. Likewise, when the first dose of "empty" PEGylated liposomes or topotecan liposomes was increased, the ABC phenomenon of the subsequent dose was accordingly attenuated. Unlike doxorubicin and mitoxantrone, the blood clearance rate of topotecan was dramatically rapid, and the hepatic and splenic accumulations of topotecan liposomes were anomalous because of the ABC phenomenon. These findings may present new challenges to the clinical application of formulations of cytotoxic drugs loaded liposomes that require repeated administrations.     

Accelerated blood clearance (ABC) phenomenon upon repeated injection of PEGylated liposomes

We and a Dutch group reported that "empty" PEGylated liposomes (approximately 100 nm) lose their long-circulating characteristic when they are administrated twice in the same animal with certain intervals (referred to as the accelerated blood clearance (ABC) phenomenon). Very recently, we showed that anti-PEG IgM, induced by the first dose of "empty" PEGylated liposomes, is responsible for inducing the phenomenon, based on the observation that IgM thus produced selectively binds to the surface of subsequently injected PEGylated liposomes, leading to substantial complement activation. It is generally believed that nanocarriers coated with a polymer, such as PEG, have no or lower immunogenicity. However, the results indicated evidence that unexpected immune responses occur even to such polymer-coated liposomes. Such immunogenicity of "empty" liposomes presents a serious concern in the development of liposomal formulations and their use in the clinic. In addition, through series of our studies, it was demonstrated that the magnitude of the ABC phenomenon depends on the physicochemical property of injected liposomes as a first dose, time interval between injection, lipid dose and drug-encapsulation.     

Accelerated blood clearance of PEGylated liposomes containing doxorubicin upon repeated administration to dogs

The accelerated blood clearance phenomenon involving anti-PEG IgM production has been recognized as an important issue for the design and development of PEGylated liposomes. Here, we show that empty PEGylated liposomes and Doxil, PEGylated liposomes containing doxorubicin, both caused anti-PEG IgM production and thereby a rapid clearance of the second and/or third dose of Doxil in Beagle dogs in a lipid-dose, inverse-dependent manner. It appears that the pharmacokinetic profile of the second and third administration of Doxil reflected the presence of anti-PEG IgM circulating in the blood. Doxil plus an excess amount of empty PEGylated liposomes rather enhanced the production of anti-PEG IgM compared to Doxil of the same doxorubicin dose. During sequential administration, increasing the lipid dose of Doxil in each dose by the addition of empty PEGylated liposomes strongly attenuated the magnitude of the ABC phenomenon during the effectuation phase of a second and third dose of Doxil. Our results suggest that the pre-clinical study of anti-cancer drug-containing PEGylated liposomes with dogs must be carefully designed and performed with monitoring of the anti-PEG IgM and liposomal drugs circulating in the blood.     

Accelerated blood clearance (ABC) phenomenon induced by administration of PEGylated liposome

PEGylated liposomes (approximately 100 nm in diameter) lose their long-circulating characteristic upon repeated injection at certain intervals in the same animal (referred to as the "accelerated blood clearance (ABC) phenomenon"), as described by our group and by researchers in the Netherlands. Recently, it was demonstrated by our group that anti-PEG IgM, induced by the first dose of PEGylated liposomes, is responsible for the ABC phenomenon. The IgM produced in this manner then selectively bound to the surface of subsequently injected PEGylated liposomes, leading to substantial complement activation. It is generally believed that nanocarriers coated with a polymer, such as PEG, have no immunogenicity. However, unexpected immune responses occurred even in response to polymer-coated liposomes. This immunogenicity to PEGylated liposomes presents a serious concern in the development and clinical use of liposomal formulations. In this review, we demonstrate our recent observations regarding with the ABC phenomenon against liposomes.     

Time Interval of Two Injections and First-Dose Dependent of Accelerated Blood Clearance Phenomenon Induced by PEGylated Liposomal Gambogenic Acid: The Contribution of PEG-Specific IgM

Repeated injection of PEGylated liposomes can cause the disappearance of long circulating property because of the induction of anti-PEG IgM antibody referred to as “accelerated blood clearance (ABC) phenomenon.” Although ABC phenomenon typically occurs when entrapped drugs are chemotherapeutic agent with low cytotoxic, there is little evidence of accelerated blood clearance of PEGylated herbal-derived compound on repeated injection. Herein, we investigated the blood concentration of PEGylated liposomal gambogenic acid (PEG-GEA-L), a model PEGylated liposomal herbal extract, on its repeated injection to rats. We found time interval between injections had considerable impact on the magnitude of ABC phenomenon induced by PEG-GEA-L. When time interval was prolonged from 3 days to 7 days, ABC phenomenon could be attenuated. Furthermore, its magnitude was enhanced accompanied by a marked rise in the accumulation of PEG-GEA-L in the liver and spleen in a first-dose–dependent manner. Consistently, the level of anti-PEG IgM significantly increased with the first dose of PEG-GEA-L and decreased with the extended time interval between injections, which implies anti-PEG IgM is a major contributor to the ABC phenomenon. Notably, the increased expression of liver anti-PEG IgM was accompanied by an increased expression of efflux transporters in the induction process of the ABC phenomenon.     

Inhalable Liposomes of Low Molecular Weight Heparin for the Treatment of Venous Thromboembolism

This study tests the feasibility of inhalable pegylated liposomal formulations of low molecular weight heparin (LMWH) for treatment of two clinical manifestations of vascular thromboembolism: deep vein thrombosis (DVT) and pulmonary embolism (PE). Conventional distearoyl-sn-glycero-3-phosphoethanolamine (DSPE) and long-circulating pegylated (DSPE–PEG-2000 and DSPE-PEG-5000) liposomes were prepared by hydration method. Formulations were evaluated for particle size, entrapment efficiency, stability, pulmonary absorption, anticoagulant, and thrombolytic effects in rats. Pulmonary absorption was monitored by measuring plasma antifactor Xa activity; anticoagulant and thrombolytic effects were studied by measuring reduction in thrombus weight and amount of dissolved radioactive clot in the blood, respectively. Pegylated liposomal were smaller and showed greater drug entrapment efficiency than conventional liposomes. All formulations produced an increase in pulmonary absorption and circulation time of LMWH upon first dosing. Three repeated dosings of conventional liposomes resulted in decreased half-life and bioavailability; no changes in these parameters were observed with pegylated liposomes. PEG-2000 liposomes were effective in reducing thrombus weight when administered every 48 h over 8 days. In terms of thrombolytic effects and dosing frequency, PEG-2000 liposomes administered via the pulmonary route at a dose of 100U/kg were as effective as 50 U/kg LMWH administered subcutaneously. This paper suggests that inhalable pegylated liposomes of LMWH could be a potential noninvasive approach for DVT and PE treatment. © 2010 Wiley-Liss, Inc. and the American Pharmacists Association J Pharm Sci99:4554–4564,     

Application of Polyglycerol Coating to Plasmid DNA Lipoplex for the Evasion of the Accelerated Blood Clearance Phenomenon in Nucleic Acid Delivery

Cationic liposomes (CLs) have shown promise as nonviral delivery systems. To achieve in vivo stability and long circulation, most liposomes are modified with hydrophilic polymer polyethylene glycol (PEG). However, we have reported that repeated administration of PEG-coated CLs containing plasmid DNA (pDNA; PEGylated lipoplexes) induces what is referred to as “the accelerated blood clearance (ABC) phenomenon” and, consequently, subsequently administered lipoplexes lose their prolonged circulation characteristics. Anti-PEG IgM produced in response to the first dose of PEG-coated pDNA–lipoplexes (PEG–DCL) has proven to be a major cause of the ABC phenomenon. In this study, to evade and/or attenuate this unexpected immune response, we modified the surface of a lipoplex with polyglycerol (PG)-derived lipid. The PG-coated pDNA–lipoplex (PG–DCL) attenuated the production of anti-polymer IgM, whereas PEG-coated pDNA–lipoplex (PEG–DCL) did not. In addition, a second dose of PG–DCL maintained the accumulation level in the tumor tissue of a tumor-bearing mouse model, comparable to that of the first dose, whereas the tumor accumulation level of a second dose of PEG–DCL was significantly compromised, compared with the first dose of PEG–DCL. Our results indicate that surface modification of lipoplex with PG represents a viable means for the attenuation, and/or evasion, of the ABC phenomenon that is encountered upon repeated administrations of nucleic acids containing PEG-coated nanocarriers.     

Characterization of Cationic Liposome Formulations Designed to Exhibit Extended Plasma Residence Times and Tumor Vasculature Targeting Properties

Cationic liposomes exhibit a propensity to selectively target tumor-associated blood vessels demonstrating potential value as anti-cancer drug delivery vehicles. Their utility however, is hampered by their biological instability and rapid elimination following i.v. administration. Efforts to circumvent rapid plasma elimination have, to date, focused on decreasing cationic lipid content and incorporating polyethylene glycol (PEG)-modified lipids. In this study we wanted to determine whether highly charged cationic liposomes with surface-associated PEG could be designed to exhibit extended circulation lifetimes, while retaining tumor vascular targeting properties in an HT29 colorectal cancer xenograft model. Cationic liposomes prepared of DSPC, cationic lipids (DODAC, DOTAP, or DC-CHOL), and DSPE-PEG₂₀₀₀ were studied. Our results demonstrate that formulations prepared with 50 mol% DODAC or DC-CHOL, and 20 mol% DSPE-PEG₂₀₀₀ exhibited circulation half-lives ranging from 6.5 to 12.5 h. Biodistribution studies demonstrated that DC-CHOL formulations prepared with DSPE-PEG₂₀₀₀ accumulated threefold higher in s.c. HT29 tumors than its PEG-free counterpart. Fluorescence microscopy studies suggested that the presence of DSPE-PEG₂₀₀₀ did not adversely affect liposomal tumor vasculature targeting. We show for the first time that it is achievable to design highly charged, highly pegylated (20 mol% DSPE-PEG₂₀₀₀) cationic liposomes which exhibit both extended circulation lifetimes and tumor vascular targeting properties     

Cationic liposomes as carriers for aerosolized formulations of an anionic drug: Safety and efficacy study

This study tests the hypothesis that pegylated cationic liposomes are a viable carrier for inhalable formulations of low molecular weight heparin, an anionic drug. Cationic liposomal formulations of low molecular weight heparin were prepared by the hydration method using 1,2-dioleoyl-3-trimethylammonium-propane (chloride salt), cholesterol and 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N-[methoxy(polyethyleneglycol)-2000]. The formulations were characterized for particle size, entrapment efficiency, pulmonary absorption and pharmacological efficacy. For absorption studies, the formulations were administered to anesthetized male Sprague–Dawley rats via the pulmonary route and drug absorption was monitored by measuring plasma anti-factor Xa activity. The pharmacological efficacy of the formulations was studied in rodent models of pulmonary embolism and deep vein thrombosis. The mean particle size of the liposomes was 104.8 ± 20.7 nm and the drug entrapment efficiency was 90.3 ± 0.1%. The half-life of the cationic liposomal formulation was 10.6 ± 0.2 h, a 2.2-fold increase compared to low molecular weight heparin formulated in saline, and the relative bioavailability was 73.4 ± 19.1% when compared to subcutaneously administered drug. A once-every-other-day inhaled dose of the formulation showed similar efficacy in reducing thrombus weight as a once-daily dose of subcutaneously administered drug. Likewise, cationic liposomal formulations administered via the pulmonary route 6 h prior to embolization in the lungs showed a thrombolytic effect comparable to that of low molecular weight heparin administered subcutaneously 2 h before embolization. Histological examination of lung tissue and measurement of injury markers in bronchoalveolar lavage fluid suggest that the formulations did not produce extensive damage. The results demonstrate that pegylated cationic liposomes could be a viable carrier for an inhalable formulation of low molecular weight heparin.     

The effect of PEG coating on in vitro cytotoxicity and in vivo disposition of topotecan loaded liposomes in rats

Amphoteric drugs encapsulated in PEGylated liposomes may not show superior therapeutic antitumor activity due to increased leakage rate of these drugs in presence of PEG-lipids. In order to investigate the effect of PEG coating on in vitro and in vivo characteristics of topotecan loaded liposomes, an amphoteric anticancer drug, PEGylated and conventional liposomes were prepared by lipid film hydration method. Various properties of the prepared nanoliposomes such as encapsulation efficiency, size, zeta potential, physical stability as well as the chemical stability of lactone form of topotecan, cytotoxicity and topotecan pharmacokinetics were evaluated. In vitro cytotoxic activity was evaluated on murine Lewis lung carcinoma (LLC) and human mammary adenocarcinoma (BT20) cells. Pharmacokinetic was evaluated in Wistar rats after i.v. injection of topotecan, formulated in PBS pH 7.4 or in conventional or in PEGylated liposomes. The conventional liposome (CL) formulation was composed of DSPC/cholesterol/DSPG (molar ratio; 7:7:3), while for PEGylated liposome the composition was DSPC/cholesterol/DSPG/DSPE-PEG(2000) (molar ratio; 7:7:3:1.28). The size of both liposomes was around 100 nm with polydispersity index of about 0.1. In comparison with free drug, liposomal topotecan showed more stability for topotecan lactone form in vitro. Compared to free topotecan, PEGylated and conventional liposomes improved cytotoxic effect of topotecan against the two cancer cell line studied. The results of pharmacokinetic studies in rats showed that both CL and PEGylated liposomal formulations increased the concentration of total topotecan in plasma, however, initial concentration and the values of AUC, MRT and t(1/2 beta) were much higher (P<0.001) for PEGylated liposomal drug than for conventional one or free drug. PEGylated liposome resulted in a 52-fold and 2-fold increases in AUC(0-infinity) compared with that of free topotecan and CL, respectively. These results indicated that PEG modified liposome might be an effective carrier for topotecan.     

Characterization of Long-Circulating Cationic Nanoparticle Formulations Consisting of a Two-Stage PEGylation Step for the Delivery of siRNA in a Breast Cancer Tumor Model

Polyethylene glycol (PEG) has been used widely in liposomal formulations as a strategy to inhibit opsonization by plasma proteins and to prolong liposome plasma circulation time. PEG can be incorporated onto the surface of liposomes either during the spontaneous self‐assembling process or inserted after vesicle formation. The advantages of employing the PEG postinsertion method include improved drug encapsulation efficiency and the ability to incorporate PEG conjugates for enhanced cell binding and uptake. In this study, we propose to evaluate a cationic lipid nanoparticle formulation containing two PEGylation steps: pre‐ and post‐siRNA insertion. Our results indicate that formulations consisting of the extra PEG post‐insertion step significantly increased siRNA circulation in the plasma by two‐folds in comparison with the formulations consisting of only the single PEGylation step. Moreover, this formulation was able to efficiently carry siRNA to the tumor site, increase siRNA stability and significantly downregulate luciferase mRNA expression by >50% when compared with the controls in an intraperitoneal and subcutaneous breast cancer tumor model. Overall, our cationic lipid nanoparticle formulation displayed enhanced plasma circulation, reduced liver accumulation, enhanced tumor targeting, and effective gene knockdown‐–demonstrating excellent utility for the delivery of siRNA.     

Accelerated Blood Clearance of PEGylated PLGA Nanoparticles Following Repeated Injections: Effects of Polymer Dose, PEG Coating, and Encapsulated Anticancer Drug

Purpose

To investigate accelerated blood clearance (ABC) induction upon repeated injections of PLGA-PEG nanoparticles as a commonly used polymeric drug carrier.

Methods

Etoposide-loaded PLGA-PEG NPs were developed and administered as the test dose to rats pre-injected with various NP treatments at certain time intervals. Pharmacokinetic parameters of etoposide and production of anti-PEG IgM antibody were evaluated.

Results

A notable ABC effect was induced by a wide range of polymer doses (0.1 to 20 mg) of empty NPs, accompanied by IgM secretion. However, a further increase in polymer dose resulted not only in the abrogation of the observed ABC induction but also in distinctly a higher value for AUC of the NPs relative to the control. The data from the PEG-negative group verified the fundamental role of PEG for ABC induction. The first injection of etoposide-containing PEGylated nanoparticles (a cell cycle phase-specific drug) produced a strong ABC phenomenon. Three sequential administrations of etoposide-loaded NPs abolished ABC, although a high level of IgM was still detected, which suggests saturation with insignificant poisoning of immune cells.

Conclusion

The presented results demonstrate the importance of clinical evaluations for PLGA-PEG nanocarriers that consider the administration schedule in multiple drug delivery, particularly in cancer chemotherapy.     

Preliminary investigation of the nasal delivery of liposomal leuprorelin acetate for contraception in rats

The purpose of the study was to investigate the nasal route as a non-invasive alternative for delivery of leuprorelin acetate (leuprolide acetate, LEU) and to achieve an effective concentration of leuprorelin acetate in blood after nasal administration for contraception in rats. The plain drug solution, physical mixture (plain drug along with constituents of liposomes), or drug encapsulated in either neutral or charged liposomes containing 5 microg leuprorelin acetate were administered to rats through the nasal route. The plain drug solution was administered subcutaneously (s.c.). Simultaneous evaluation was performed on the influence of a mucoadhesive agent (chitosan) on nasal absorption of the plain drug and the liposome-encapsulated drug. Blood samples were taken at regular time intervals and subjected to luteinising hormone (LH) analysis using a specific immunoassay kit. The plasma luteinising hormone concentration vs time data of nasal and subcutaneous treatments were plotted and compared with that of subcutaneous administration. Relative percentage of bioavailability (F) for nasal treatments was calculated from plasma concentration vs time plots. Sperm count and fertility performance studies were carried out for selected formulations in rats. Neutral liposomes (LLEU) and negatively-charged liposomes (LLEUn) showed higher relative percentage of bioavailability (F 27.83 and 21.30%, respectively) as compared with the plain drug and the physical mixture (F 10.89 and 10.96%, respectively) after nasal administration. Hence, work on neutral liposomes was continued. F was further improved after incorporation of chitosan i.e. 10.89 to 49.13% for plain leuprorelin acetate and 27.83 to 88.90% for liposomal leuprorelin acetate formulations. Liposomal chitosan formulation administered nasally and leuprorelin acetate solution subcutaneously achieved complete azoospermia. No implantation sites were observed after the mating of female rats with treated males. It was observed that in the treated female rats, the estrous cycles ceased with the same formulations from the first treatment cycle. The findings of these investigations demonstrated that the bioavailability of the nasally-administered liposomal leuprorelin acetate with chitosan formulation was comparable with that of the subcutaneously administered drug. Complete contraception was obtained in male and female rats that had been treated with either the nasally administered liposomal leuprorelin acetate with chitosan or the subcutaneously administered drug.     

Pharmacodynamics of insulin in polyethylene glycol-coated liposomes

To reduce the injection frequency and toxicity of intravenously administered protein drugs, it is necessary to develop safe and sustained injectable delivery systems. In this study, to evaluate liposomes as safe and sustained injectable delivery systems of proteins, we chose insulin as a model protein drug and tested its incorporation efficiency and pharmacodynamics in various liposomes with and without polyethylene glycol (PEG)-derivatized phospholipid. The liposomes coated with PEG showed 3-fold higher efficiency of insulin incorporation than did the liposomes without PEG. Moreover, among the liposomes coated with PEG, dipalmitoylphosphocholine (DPPC) liposomes showed higher incorporation efficiency than did dimyristoylphosphocholine (DMPC) liposomes. For pharmacodynamic study, insulin (2 IU/kg) was administered in various formulations, such as insulin alone in phosphate-buffered saline and insulin in the DPPC liposomes with and without PEG, to streptozotocin-treated diabetic rats. The pharmacodynamics of insulin alone, however, could not be measured due to the immediate death of rats caused by hypoglycemic shock. In contrast, all the rats treated with liposomal insulin survived, probably by the sustained release of insulin from liposomes. Pharmacodynamics of liposomal insulin showed that PEG-coated liposomes induced the lowest level of blood glucose-the nadir-1 h later than did the liposomes without PEG. These results indicate that PEG-coated liposomes could be developed as a relatively safe and sustained injectable delivery system for insulin with improved incorporation efficiency. Moreover, it is suggested that the liposomes coated with PEG might have a potential as safe injectable delivery systems for other protein and peptide drugs.     

Interactions of Liposome Carriers with Infectious Fungal Hyphae Reveals the Role of β-Glucans

Relatively little is known about how liposomal formulations modulate drug delivery to fungal pathogens. We compared patterns of hyphal cell wall binding for empty rhodmine-labeled liposomes and the clinically available amphotericin B-containing liposomal formulation (AmBisome) in Aspergillus fumigatus and Candida albicans. Following 0.5 h of coincubation with A. fumigatus , empty liposomes concentrated primarily in fungal septae along at the surface of the cell wall, suggesting that liposome uptake is concentrated in areas of the cell wall where linear glucan is exposed on the cell surface, which was confirmed by aniline blue staining. Consistent with this hypothesis, pretreatment of liposomes with soluble linear glucan (laminarin) decreased liposome binding in both Aspergillus and Candida fungal hyphae, while growth of Aspergillus hyphae in the presence of an agent that increases fungal cell wall surface exposure of linear β-glucans without cell death (caspofungin) increased liposome uptake throughout the Aspergillus fungal cell wall. Increasing the polyethylene glycol (PEG) concentration in liposomes from 0 to 30% significantly increased fungal uptake of liposomes that was only modestly attenuated when fungal cells were incubated in serum concentrations ranging from 10 to 100%. The presence of β-glucans on the fungal hyphae cell walls of Aspergillus fumigatus is one of the factors responsible for mediating the binding of liposome carriers to the hyphae and could explain possible synergy reported between liposomal amphotericin B and echinocanins.     

Improved targeting of antimony to the bone marrow of dogs using liposomes of reduced size

A novel liposomal formulation of meglumine antimoniate (MA), consisting of vesicles of reduced size, has been evaluated in dogs with visceral leishmaniasis to determine its pharmacokinetics as well as the impact of vesicle size on the targeting of antimony to the bone marrow. Encapsulation of MA in liposomes was achieved through freeze-drying of empty liposomes in the presence of sucrose and rehydration with a solution of MA. The resulting formulation, with a mean vesicle diameter of about 400 nm, was given to mongrel dogs with visceral leishmaniasis as an i.v. bolus injection at 4.2 mgSb/kg of body weight. The pharmacokinetics of antimony were assessed in the blood and in organs of the mononuclear phagocyte system and compared to those achieved with the free drug and the drug encapsulated in large sized liposomes (mean diameter of 1200 nm). The targeting of antimony to the bone marrow was improved (approximately three-fold) with the novel liposomal formulation, when compared to the formulation of MA in large sized liposomes. This study provides the first direct experimental evidence that passive targeting of liposomes to the bone marrow of dogs is improved by the reduction of vesicle size from the micron to the nanometer scale.