Optimization and upscaling of doxorubicin-containing liposomes for clinical use

This work describes the optimization of a doxorubicin (DXR)-containing liposome formulation and its upscaling for human therapy. Multilamellar vesicles (MLV) composed of egg phosphatidylcholine, egg-derived phosphatidylglycerol, cholesterol, and the drug were prepared in 0.9% sterile, pyrogen-free NaCl by five different hydration methods. The optimal hydration was shown to be the formation of a thin lipid film with high surface area. Alternative hydration methods based on freeze-drying techniques of the lipids in tertiary butanol or based on "alcohol" premixing procedures of the dry DXR-lipid mixture showed smaller DXR loading capacities and lower DXR incorporation per phospholipid. Maximal DXR entrapment was obtained at a molar concentration of phosphatidylglycerol of 30 mol % of total phospholipid. This and previous studies led to a final lipid composition of phosphatidylcholine:phosphatidylglycerol:cholesterol in a molar ratio of 7:3:4. Oligolamellar DXR-liposomes with an average diameter in the range 0.3-0.5 microM were prepared from DXR-MLV by extrusion through polycarbonate membranes using moderate pressures (up to 100 psi). At this size range, maximal entrapment of DXR per phospholipid was obtained. The extrusion process also ensures the sterilization of the final product. Free DXR was removed from liposome-associated DXR (L-DXR) by the use of a cation-exchange resin. The L-DXR formulation was shown to have reasonable stability on storage at 4 degrees C.     

Targeted Delivery of Doxorubicin via Sterically Stabilized Immunoliposomes: Pharmacokinetics and Biodistribution in Tumor-bearing Mice

Purpose. To evaluate benefits in tumor localization, availability, and noncancerous organ distribution of doxorubicin (DOX) delivered via small (120 nm) sterically stabilized immunoliposomes targeted against a tumor-associated antigen in fibrosarcoma-bearing mice. Methods. DOX-loaded liposomes were prepared with (i) specific monoclonal IgG₃ antibody (32/2, D-SSIL-32/2); (ii) non-specific IgG₃ (D-SSIL-IgG); or (iii) no IgG (D-SSL) on their surface. Equal DOX amounts were injected intravenously via each type of liposome into BALB/c mice carrying experimental lung metastases of a polyoma virus-induced fibrosarcoma (A9 etc 220) expressing a polyoma virus-induced tumor-associated antigen (PAA) on their surface. Metastases occurred mainly in lung. Mice were treated at 3 stages of tumor development (micrometastases, medium-size metastases, and large, necrotic metastases). Performance evaluation was based on time-dependent quantification of DOX and DOX metabolites (DOX-M) in lung tumor, noncancerous organs, and plasma. Results. (i) DOX delivered via both SSIL retained the prolonged circulation time typical of DOX delivered via D-SSL. (ii) DOX accumulation in noncancerous organs was similar for all preparations. Low levels of DOX-M were obtained for all three preparations in all organs except liver, suggesting a similar processing, (iii) Preparations differed in behavior in lung tumor depending on tumor size and microanatomy. Only at the micrometastases stage were the specifically targeted D-SSIL-32/2 superior to D-SSL and D-SSIL-IgG, delivering 2–4 times more drug into the tumor, (iv) DOX-M level in all three tumor stages was in the following order: D-SSIL-32/2 >> D-SSL >> D-SSIL-IgG, suggesting that DOX delivered as D-SSIL-32/2 is most available to tumor cells. Conclusions. The advantage of specific targeting of sterically stabilized liposomes is expressed mainly in increasing availability of DOX to tumor cells in a way which is dependent on tumor microanatomy. The impact of this advantage to therapeutic efficacy remains to be determined.     

Receptor-mediated toxicity of pahutoxin, a marine trunkfish surfactant.

Pahutoxin (PHN, choline chloride ester of 3-acetoxypalmitic acid) is a natural fish-killing (ichthyotoxic) agent derived from the defensive secretions of trunkfish. In spite of its obvious structural resemblance to synthetic cationic long-chain quaternary ammonium detergents, we show that PHN's action does not rely on its surfactant properties and is in fact, receptor-mediated. The above conclusion is supported by the following data: 1. Ichthyotoxicity is not related to its detergency or surfactivity, as indicated by the fact that the lethal concentration is about 1.5 orders of magnitude below its critical micelle concentration value (69 microM) and its liposomal/seawater partition coefficient is low (62-85); 2. The trunkfish is tolerant to its own pahutoxin; 3. Ichthyotoxicity occurs only upon application to the surrounding water, suggesting the existence of externally located receptors; 4. The receptor hypothesis was supported by the aid of equilibrium saturation binding assays revealing the presence of specific binding sites to PHN on the fish gill membranes; 5. The PHN tolerant trunkfish was shown to be devoid of PHN-binding sites. Some chemo-ecological, and environmental implications are discussed.     

Superior therapeutic activity of liposome-associated adriamycin in a murine metastatic tumour model

We have examined the anti-tumour activity of liposome-entrapped Adriamycin in a murine metastatic tumour model produced by i.v. inoculation of J-6456 lymphoma cells and affecting predominantly the liver. Sonicated liposomes containing phosphatidylcholine, a negatively-charged phospholipid and cholesterol were used in these experiments. Liposome-entrapped Adriamycin was more effective than free Adriamycin at equivalent doses of the drug. The superior therapeutic effect of the liposome-associated drug was manifest, either with a single i.v. treatment using a dose bordering the toxicity threshold of free Adriamycin or with a multi-injection schedule using smaller doses. Based on the growth kinetics data of the J-6456 lymphoma, our results indicate that tumour cell killing was enhanced by a factor of approximately 100 using the liposome associated form of Adriamycin. Histopathologic studies in mice bearing well-established metastases of the J-6456 lymphoma in liver and spleen indicated that the extent and duration of pathologic remission were significantly improved in mice receiving the liposome-entrapped drug as compared to mice receiving free drug. No significant differences in the anti-tumour effect of liposome entrapped Adriamycin were observed replacing phosphatidylserine by phosphatidylglycerol and reducing the cholesterol:phospholipid molar ratio from 100% to 25%. In contrast to the metastatic tumour model, liposome-entrapped Adriamycin was significantly less effective than free Adriamycin on the local i.m. growth of the J-6456 tumour. Altogether the survival and histopathological data presented suggest that, with regard to a group of neoplastic conditions with a predominant pattern of liver dissemination, a substantial increase in the therapeutic index of Adriamycin can be achieved in a selective manner with the use of liposomes.     

Pharmacokinetics of pegylated liposomal Doxorubicin: review of animal and human studies

Pegylated liposomal doxorubicin (doxorubicin HCl liposome injection; Doxil or Caelyx) is a liposomal formulation of doxorubicin, reducing uptake by the reticulo-endothelial system due to the attachment of polyethylene glycol polymers to a lipid anchor and stably retaining drug as a result of liposomal entrapment via an ammonium sulfate chemical gradient. These features result in a pharmacokinetic profile characterised by an extended circulation time and a reduced volume of distribution, thereby promoting tumour uptake. Preclinical studies demonstrated one- or two-phase plasma concentration-time profiles. Most of the drug is cleared with an elimination half-life of 20-30 hours. The volume of distribution is close to the blood volume, and the area under the concentration-time curve (AUC) is increased at least 60-fold compared with free doxorubicin. Studies of tissue distribution indicated preferential accumulation into various implanted tumours and human tumour xenografts, with an enhancement of drug concentrations in the tumour when compared with free drug. Clinical studies of pegylated liposomal doxorubicin in humans have included patients with AIDS-related Kaposi's sarcoma (ARKS) and with a variety of solid tumours, including ovarian, breast and prostate carcinomas. The pharmacokinetic profile in humans at doses between 10 and 80 mg/m(2) is similar to that in animals, with one or two distribution phases: an initial phase with a half-life of 1-3 hours and a second phase with a half-life of 30-90 hours. The AUC after a dose of 50 mg/m(2) is approximately 300-fold greater than that with free drug. Clearance and volume of distribution are drastically reduced (at least 250-fold and 60-fold, respectively). Preliminary observations indicate that utilising the distinct pharmacokinetic parameters of pegylated liposomal doxorubicin in dose scheduling is an attractive possibility. In agreement with the preclinical findings, the ability of pegylated liposomes to extravasate through the leaky vasculature of tumours, as well as their extended circulation time, results in enhanced delivery of liposomal drug and/or radiotracers to the tumour site in cancer patients. There is evidence of selective tumour uptake in malignant effusions, ARKS skin lesions and a variety of solid tumours. The toxicity profile of pegylated liposomal doxorubicin is characterised by dose-limiting mucosal and cutaneous toxicities, mild myelosuppression, decreased cardiotoxicity compared with free doxorubicin and minimal alopecia. The mucocutaneous toxicities are dose-limiting per injection; however, the reduced cardiotoxicity allows a larger cumulative dose than that acceptable for free doxorubicin. Thus, pegylated liposomal doxorubicin represents a new class of chemotherapy delivery system that may significantly improve the therapeutic index of doxorubicin.     

Prolongation of the Circulation Time of Doxorubicin Encapsulated in Liposomes Containing a Polyethylene Glycol-Derivatized Phospholipid: Pharmacokinetic Studies in Rodents and Dogs

The pharmacokinetics of doxorubicin (DOX) encapsulated in liposomes containing polyethylene glycol-derivatized distearoylphosphatidylethanolamine (PEG/DSPE) were investigated in rodents and dogs. The plasma levels of DOX obtained with PEG/DSPE-containing liposomes were consistently higher than those without PEG/DSPE or when PEG/DSPE was replaced with hydrogenated phosphatidylinositol (HPI). Despite the inclusion of PEG/DSPE in liposomes, there was a significant drop in the plasma levels of DOX when the main phospholipid component, hydrogenated phosphatidylcholine, was replaced with lipids of lower phase transition temperature (dipalmitoylphosphatidylcholine, egg phosphatidylcholine), indicating that phase transition temperature affects the pharmacokinetics of liposome-encapsulated DOX. In beagle dogs, clearance was significantly slower for DOX encapsulated in PEG/ DSPE-containing liposomes than in HPI-containing liposomes, with distribution half-lives of 29 and 13 hr, respectively. In both instances, almost 100% of the drug measured in plasma was liposome-associated. The apparent volume of distribution was only slightly above the estimated plasma volume of the dogs, indicating that drug leakage from circulating liposomes is insignificant and that the distribution of liposomal drug is limited mostly to the intravascular compartment in healthy animals.     

Mucosal immunization against hepatitis A: antibody responses are enhanced by co-administration of synthetic oligodeoxynucleotides and a novel cationic lipid

Hepatitis A caused by hepatitis A virus (HAV) transmitted by the fecal-oral route, results in considerable morbidity and economic loss. Mucosal immunization can be more effective than conventional injection at inducing both local and systemic immunity to HAV. Here we show that co-administration of killed HAV with synthetic oligodeoxynucleotides (ODNs) containing CpG sequences, and a novel polycationic sphingolipid (CCS)/cholesterol liposomal delivery system, markedly enhances the HAV-specific antibody response at the intestinal interface, particularly when delivered intrarectally or intranasally, to Balb/c mice at low HAV doses. A mucosally delivered, antigen-sparing HAV vaccine that is easily administered without specialized equipment or personnel, is an attractive alternative for facilitating mass immunization in hepatitis A outbreaks.     

Liposome-induced complement activation and related cardiopulmonary distress in pigs: factors promoting reactogenicity of Doxil and AmBisome

Hypersensitivity reactions to liposomal drugs, often observed with Doxil and AmBisome, can arise from activation of the complement (C) system by phospholipid bilayers. To understand the mechanism of this adverse immune reaction called C activation-related pseudoallergy (CARPA), we analyzed the relationship among liposome features, C activation in human serum in vitro, and liposome-induced cardiovascular distress in pigs, a model for human CARPA. Among the structural variables (surface charge, presence of saturated, unsaturated, and PEGylated phospholipids, and cisplatin vs. doxorubicin inside liposomes), high negative surface charge and the presence of doxorubicin were significant contributors to reactogenicity both in vitro and in vivo. Morphological analysis suggested that the effect of doxorubicin might be indirect, via distorting the sphericity of liposomes and, if leaked, causing aggregation. The parallelism among C activation, cardiopulmonary reactions in pigs, and high rate of hypersensitivity reactions to Doxil and AmBisome in humans strengthens the utility of the applied tests in predicting the risk of CARPA. FROM THE CLINICAL EDITOR: The authors studied complement activation-related pseudoallergy (CARPA) in a porcine model and demonstrate that high negative surface charge and drug effects leading to distortion of liposome sphericity might be the most critical factors leading to CARPA. The applied tests might be used to predict CARPA in humans.