Preparation, characterization, and biodistribution study of technetium-99m-labeled leuprolide acetate-loaded liposomes in ehrlich ascites tumor-bearing mice

The purpose of this study was to prepare conventional and sterically stabilized liposomes containing leuprolide acetate in an attempt to prolong the biological half life of the drug, to reduce the uptake by reticuloendothelial system (RES), and to reduce the injection frequency of intravenously administered peptide drugs. The conventional and sterically stabilized liposomes containing leuprolide acetate were prepared by reverse phase evaporation method and characterized for entrapment efficiency and particle size. Radiolabeling of leuprolide acetate and its liposomes was performed by direct labeling with reduced technetium-99m. Its biodistribution and imaging characteristics were studied in ehrlich ascites tumor (EAT)-bearing mice after labeling with technetium-99m. The systemic pharmacokinetic studies were performed in rabbits. A high uptake by tumor was observed by sterically stabilized liposome containing leuprolide acetate compared with free drug and conventional liposomes. The liver/tumor uptake ratio of free drug, conventional (LL), and sterically stabilized liposomes (SLL5000 and SLL2000) was found to be 20, 7.99, 1.63, and 1.23, respectively, which showed the increased accumulation of sterically stabilized liposomes in tumor compared with the free drug and conventional liposomes at 24 hours postinjection. Liver uptake of sterically stabilized liposomes was still 7-fold less than the conventional liposomes. The marked accumulation of liposomes in the tumor-bearing mice was also documented by gamma scintigraphic studies. The findings demonstrate the distribution of these liposomes within solid tumor and prove that the sterically stabilized liposomes experience increased tumor uptake and prolonged circulation half life. Hence these findings will be relevant for the optimal design of long circulating liposomes for the peptide drugs and for targeting of liposomes toward tumor.     

Liposomes modified with cyclic RGD peptide for tumor targeting

Cyclic RGD peptide anchored sterically stabilized liposomes (RGD-SL) were investigated for selective and preferential presentation of carrier contents at angiogenic endothelial cells overexpressing alphavbeta3 integrins on and around tumor tissue and thus for assessing their targetabilty. Liposomes were prepared using distearoylphosphatidylcholine (DSPC), cholesterol and distearoylphosphatidylethanolamine-polyethyleneglycol-RGD peptide conjugate (DSPE-PEG-RGD) in a molar ratio 56:39:5. The control RAD peptide anchored sterically stabilized liposomes (RAD-SL) and liposome with 5 mol% PEG (SL) without peptide conjugate which had similar lipid composition were used for comparison. The average size of all liposome preparations prepared was approximately 105 nm and maximum drug entrapment was 10.5+/- 1.1%. In vitro endothelial cell binding of liposomes exhibited 7-fold higher binding of RGD-SL to HUVEC in comparison to the SL and RAD-SL. Spontaneous lung metastasis and angiogenesis assays show that RGD peptide anchored liposomes are significantly (p<0.01) effective in the prevention of lung metastasis and angiogenesis compared to free 5-FU, SL and RAD-SL. In therapeutic experiments, 5-FU, SL, RGD-SL and RAD-SL were administered intravenously on day 4 at the dose of 10 mg 5-FU/kg body weight to B16F10 tumor bearing BALB/c mice resulting in effective regression of tumors compared with free 5-FU, SL and RAD-SL. Results indicate that cyclic RGD peptide anchored sterically stabilized liposomes bearing 5-FU are significantly (p<0.01) active against primary tumor and metastasis than the non-targeted sterically stabilized liposomes and free drug. Thus cyclic RGD peptide anchored sterically stabilized liposomes hold potential of targeted cancer chemotherapeutics.     

Assessment of targeting potential of galactosylated and mannosylated sterically stabilized liposomes to different cell types of mouse liver

Galactose and Mannose residues were tagged on the surface of n-glutaryl-phosphatidylethanolamine (NGPE) containing liposomes with and without polyethylene glycol of molecular weight 2000 Da conjugated to distearoyl phosphatidylethanolamine (PEG-2000-DSPE). Biodistribution studies showed that sugar bearing liposomes were cleared more rapidly from circulation than those not bearing the sugar moieties. However, the rate of clearance of glycosylated conventional liposomes was much faster than the sugar bearing sterically stabilized liposomes. Intrahepatic distribution studies showed that a substantial amount of conventional liposomes without sugar residues were taken up by both parenchymal (P) (40%) and non-parenchymal (NP) cells (60%). However, incorporation of PEG-2000-DSPE shifted this uptake slightly in favour of parenchymal cells (47%). While ratio of distribution of galactosylated conventional liposomes to P and NP cells was found to be 74:26, galactosylation of sterically stabilized liposomes further enhanced the affinity of these vesicles towards P cells (P:NP ratio being 93:7). Thus, reduced uptake by Kupffer cells was observed with galactosylated sterically stabilized liposomes as compared to conventional liposomes. Whereas, mannosylation of both the liposomes shifted the distribution towards Kupffer cells in an analogous manner. These findings indicate that sterically stabilized liposomes tagged with galactose residues on their surface are more effective in targeting the entrapped material to hepatocytes as compared to conventional liposomes. This approach can therefore be employed for delivering therapeutic agents like drugs, enzymes, genetic materials, anti-sense oligonucleotides selectively to liver P cells for treatment of hepatic disorders.     

Liposomes Modified with Cyclic RGD Peptide for Tumor Targeting

Cyclic RGD peptide anchored sterically stabilized liposomes (RGD-SL) were investigated for selective and preferential presentation of carrier contents at angiogenic endothelial cells overexpressing α_vβ₃ integrins on and around tumor tissue and thus for assessing their targetabilty. Liposomes were prepared using distearoylphosphatidylcholine (DSPC), cholesterol and distearoylphosphatidylethanolamine–polyethyleneglycol–RGD peptide conjugate (DSPE–PEG–RGD) in a molar ratio 56:39:5. The control RAD peptide anchored sterically stabilized liposomes (RAD-SL) and liposome with 5 mol% PEG (SL) without peptide conjugate which had similar lipid composition were used for comparison. The average size of all liposome preparations prepared was approximately 105 nm and maximum drug entrapment was 10.2±1.1%. In vitro endothelial cell binding of liposomes exhibited 7-fold higher binding of RGD-SL to HUVEC in comparison to the SL and RAD-SL. Spontaneous lung metastasis and angiogenesis assays show that RGD peptide anchored liposomes are significantly (p<0.01) effective in the prevention of lung metastasis and angiogenesis compared to free 5-FU, SL and RAD-SL. In therapeutic experiments, 5-FU, SL, RGD-SL and RAD-SL were administered intravenously on day 4 at the dose of 10 mg 5-FU/kg body weight to B16F10 tumor bearing BALB/c mice resulting in effective regression of tumors compared with free 5-FU, SL and RAD-SL. Results indicate that cyclic RGD peptide anchored sterically stabilized liposomes bearing 5-FU are significantly (p<0.01) active against primary tumor and metastasis than the non-targeted sterically stabilized liposomes and free drug. Thus cyclic RGD peptide anchored sterically stabilized liposomes hold potential of targeted cancer chemotherapeutics.     

RGD-based strategies for improving antitumor activity of paclitaxel-loaded liposomes in nude mice xenografted with human ovarian cancer

Tumor-targeting drug delivery systems are being the ideal carrier for systemic administration of antiproliferative drugs. RGD peptide (arginine–glycine–aspartic acid) modified liposomes containing paclitaxel (RGD-SSL-PTX). The arginine-glycine-aspartic acid tripeptide (RGD) modified sterically stabilized liposomes (SSL) containing paclitaxel (PTX) (RGD-SSL-PTX), which could increase targeting to tumor by binding with the integrin receptors overexpressed on tumor cells. The encapsulation efficiency was more than 90% and the mean particle size was of 120 nm with a narrow size distribution. It was indicated that significant cytotoxicity (3.5 times lower IC₅₀) was found in the SKOV-3 human ovarian cancer cells treated with RGD-SSL-PTX preparation, as well as the intracellular uptake of liposomes (a 6.21-fold increase in fluorescence intensity), when compared to those of non-targeted liposomes (SSL). For in vivo antitumor activity, it was shown in the present study that RGD-SSL-PTX preparation had the strongest tumor growth inhibition among the test formulations (P < 0.05) in BALB/c nude mice xenografted with SKOV-3 solid tumor. Meanwhile, there was no significant change in the body weight of the animals treated with RGD-SSL-PTX for intravenous injection at a dose of 12.5 mg/kg. It was suggested that the RGD-SSL-PTX preparation might have a great advantage over present-day chemotherapy with Taxol^® in curing those tumors overexpressing integrin receptors.     

Anxiety and cognitive effects of quercetin liposomes in rats

Quercetin, an effective flavonol used as an antioxidant, was investigated for its anxiolytic and cognitive activities in male Wistar rats. Oral quercetin (300 mg/kg body weight/day) was compared with oral and intranasal quercetin liposomes (20 microg/day). Quercetin liposomes, in a mixture of egg phosphatidylcholine, cholesterol, and quercetin (2:1:1) and dispersed in 50% polyethylene glycol in water, were approximately 200 nm in mean particle diameter and negative surface charge with a range of encapsulation efficiency of 60% to 80%. Anxiolytic and cognitive-enhancing effects of quercetin, conventional and liposomal, were subjected to elevated plus maze and Morris water maze tests, respectively. Both conventional and quercetin liposomes showed anxiolytic and cognitive-enhancing effects. A lower dose and a faster rate were observed with intranasal quercetin liposomes when compared with oral quercetin, conventional and liposomal. The intranasal quercetin liposomes are effective in the delivery of quercetin to the central nervous system.     

Etoposide encapsulated in positively charged liposomes: pharmacokinetic studies in mice and formulation stability studies.

Etoposide is an antineoplastic agent which acts by forming a ternary complex with topoisomerase II and DNA, causing DNA breaks and cell death. In recent studies we have demonstrated that encapsulation in liposomes increases the antitumour efficacy and reduces the adverse effects associated with etoposide. The present study was thus conducted to evaluate whether encapsulation in cationic liposomes altered the pharmacokinetics of etoposide and to study the effect of cholesterol incorporation on the stability of the liposomes. Etoposide-encapsulated unilammellar liposomes were synthesized by thin film hydration followed by extrusion. The drug was administered to Swiss albino mice at a dose of 10 mg kg(-1). The concentration of the drug in plasma was analysed at different time points till 360 min after injection, using a h.p.l.c. method. The terbium chloride-dipicolinic acid interaction method was applied to study the stability of the formulation in mouse serum and also following storage at 0( composite function)C over a period of time. The effect of the free and liposomal drug on myelosuppression was evaluated at 10 mg m(-2)and 40 mg m(-2)dose levels by quantifying blood cell counts on day 15 and day 21 following a 5 day course of therapy. Encapsulation in cationic liposomes increased the area under the concentration vs time curve to 42.98 microghml(-1)from 24.18 microghml(-1)in the case of the free drug. Half-life (beta) was 58. 62 and 186 min in the case of free and liposomal etoposide, respectively. In the stability studies, incorporation of cholesterol progressively stabilized the formulation in serum. The use of sucrose at increasing concentrations as a cryoprotectant also increased the shelf stability of the formulation at 0( composite function)C. Toxicity studies using a dose of pure drug revealed that though myelosuppression was evident in both liposomal- and free drug-treated groups on day 15 it was reversed by day 21 following initiation of therapy. The present findings suggest that liposomes could serve as an alternative mode of delivery for etoposide.     

Preparation and evaluation of sterically stabilized liposomes: colloidal stability, serum stability, macrophage uptake, and toxicity

Sterically stabilized liposomes were produced by incorporating a nonionic surfactant, polysorbate 80 (Tween 80), into the lipid bilayer. The sterically stabilized liposomes exhibited a superior entrapment stability compared with surfactant-free liposomes (i.e., liposomes prepared with lipids and cholesterol). The sterically stabilized liposomes were stable at high calcium ion concentrations, and liposome-entrapped carboxyfluorescein was retained within the stabilized liposomes in the presence of serum for at least 5 h. The macrophage uptake of the sterically stabilized liposomes was comparable to that of liposomes containing lipids and cholesterol. The sterically stabilized liposomes were non-toxic, in concentrations up to 3.0 mM, to macrophages. These results indicate that polysorbate 80 can be used to produce stable liposomes without changing the unique macrophage distribution of this drug delivery system.     

Liposomes modified with YIGSR peptide for tumor targeting

YIGSR peptide anchored sterically stabilized liposomes (YIGSR-SL) were investigated for selective and preferential presentation of carrier contents at angiogenic endothelial cells overexpressing laminin receptors on and around tumor tissue and thus for assessing their targetabilty. In vitro endothelial cell binding of liposomes exhibited 7-fold higher binding of YIGSR-SL to HUVEC in comparison to the nontargeted sterically stabilized liposomes (SL). Spontaneous lung metastasis and angiogenesis assays show that YIGSR peptide anchored liposomes are significantly (P ≤ 0.01) effective in the prevention of lung metastasis and angiogenesis compared to free 5-fluorouracil (5-FU) and SL. YIGSR-SL was very effective in regression of tumors in BALB/c mice bearing B16F10 melanoma cells. Results indicate that YIGSR peptide anchored sterically stabilized liposomes bearing 5-FU are significantly (P ≤ 0.01) active against primary tumor and metastasis than the SL and free drug. Thus, YIGSR peptide anchored sterically stabilized liposomes hold potential of targeted cancer chemotherapeutics.     

Nasal Delivery. The Use of Animal Models to Predict Performance in Man

Abstract

Galactose and Mannose residues were tagged on the surface of n-glutaryl-phosphatidyl-ethanolamine (NGPE) containing liposomes with and without polyethylene glycol of molecular weight 2000 Da conjugated to distearoyl phosphatidylethanolamine (PEG-2000-DSPE). Biodistribution studies showed that sugar bearing liposomes were cleared more rapidly from circulation than those not bearing the sugar moieties. However, the rate of clearance of glycosylated conventional liposomes was much faster than the sugar bearing sterically stabilized liposomes. Intrahepatic distribution studies showed that a substantial amount of conventional liposomes without sugar residues were taken up by both parenchymal (P) (40%) and non-parenchymal (NP) cells (60%). However, incorporation of PEG-2000-DSPE shifted this uptake slightly in favour of parenchymal cells (47%). While ratio of distribution of galactosylated conventional liposomes to P and NP cells was found to be 74: 26, galactosylation of sterically stabilized liposomes further enhanced the affinity of these vesicles towards P cells (P: NP ratio being 93: 7). Thus, reduced uptake by Kupffer cells was observed with galactosylated sterically stabilized liposomes as compared to conventional liposomes. Whereas, mannosylation of both the liposomes shifted the distribution towards Kupffer cells in an analogous manner. These findings indicate that sterically stabilized liposomes tagged with galactose residues on their surface are more effective in targeting the entrapped material to hepatocytes as compared to conventional liposomes. This approach can therefore be employed for delivering therapeutic agents like drugs, enzymes, genetic materials, anti-sense oligonucleotides selectively to liver P cells for treatment of hepatic disorders.     

In vivo distribution and antitumor activity of heparin-stabilized doxorubicin-loaded liposomes

The purpose of this study was to investigate the effect of heparin conjugation to the surface of doxorubicin (DOX)-loaded liposomes on the circulation time, biodistribution and antitumor activity after intravenous injection in murine B16F10 melanoma tumor-bearing mice. The heparin-conjugated liposomes (heparin-liposomes) were prepared by fixation of the negatively charged heparin to the positively charged liposomes. The existence of heparin on the liposomal surface was confirmed by measuring the changes in the particle size, zeta potential and heparin amount of the liposomes. The stability of the heparin-liposomes in serum was higher than that of the control liposomes, due to the heparin-liposomes being better protected from the adsorption of serum proteins. The DOX-loaded heparin-liposomes showed high drug levels for up to 64 h after the intravenous injection and the half-life of DOX was approximately 8.4- or 1.5-fold higher than that of the control liposomes or polyethyleneglycol-fixed liposomes (PEG-liposomes), respectively. The heparin-liposomes accumulated to a greater extent in the tumor than the control or PEG-liposomes as a result of their lower uptake by the reticuloendothelial system cells in the liver and spleen. In addition, the DOX-loaded heparin-liposomes retarded the growth of the tumor effectively compared with the control or PEG-liposomes. These results indicate the promising potential of heparin-liposomes as a new sterically stabilized liposomal delivery system for the enhancement of the therapeutic efficacy of chemotherapeutic agents.     

人鼠嵌合抗肿瘤细胞核单抗-空间稳定脂质体的制备及其体外靶向

目的研究人鼠嵌合抗肿瘤细胞核单抗(chTNT-3)-空间稳定脂质体的制备方法、免疫活性及体外靶向性。方法合成聚乙二醇末端带吡啶二硫丙酰基的磷脂衍生物(PDP-PEG-HSPE)，制备含PDP-PEG-HSPE的空间稳定脂质体，经二巯基苏糖醇还原后共价连接马来酰亚胺衍生化抗体。荧光胺法和钼蓝法测定脂质体与抗体的连接效率及抗体密度，激光散射粒度仪测定其粒径分布，ELISA法检测脂质体表面的抗体免疫活性。体外实验考察该免疫脂质体与固定Raji细胞的结合活性。结果chTNT-3-空间稳定脂质体的粒径分布为(115±33) nm。当初始Ab/PDP-PEG-HSPE=1∶10时，脂质体与抗体的连接效率为71%，抗体密度为106 μg Ab/μmol PL。chTNT-3经化学修饰后连接到脂质体表面，其免疫活性基本保留。chTNT-3-空间稳定脂质体能特异性地结合固定Raji细胞。结论通过PDP-PEG-HSPE法共价连接抗体制备的chTNT-3-空间稳定脂质体能基本保留chTNT-3的免疫活性，具有体外靶向细胞核抗原的能力。     

Promotion or suppression of experimental metastasis of B16 melanoma cells after oral administration of lapachol

Lapachol [2-hydroxy-3-(3-methyl-2-butenyl)-1,4-naphthoquinone] is a vitamin K antagonist with antitumor activity. The effect of lapachol on the experimental metastasis of murine B16BL6 melanoma cells was examined. A single oral administration of a high toxic dose of lapachol (80-100 mg/kg) 6 h before iv injection of tumor cells drastically promoted metastasis. This promotion of metastasis was also observed in T-cell-deficient mice and NK-suppressed mice. In vitro treatment of B16BL6 cells with lapachol promoted metastasis only slightly, indicating that lapachol promotes metastasis primarily by affecting host factors other than T cells and NK cells. A single oral administration of warfarin, the most commonly used vitamin K antagonist, 6 h before iv injection of tumor cells also drastically promoted the metastasis of B16BL6 cells. The promotion of metastasis by lapachol and warfarin was almost completely suppressed by preadministration of vitamin K3, indicating that the promotion of metastasis by lapachol was derived from vitamin K antagonism. Six hours after oral administration of lapachol or warfarin, the protein C level was reduced maximally, without elongation of prothrombin time. These observations suggest that a high toxic dose of lapachol promotes metastasis by inducing a hypercoagulable state as a result of vitamin K-dependent pathway inhibition. On the other hand, serial oral administration of low non-toxic doses of lapachol (5-20 mg/kg) weakly but significantly suppressed metastasis by an unknown mechanism, suggesting the possible use of lapachol as an anti-metastatic agent.     

顺铂缓释多囊脂质体的制备和体外释放性能研究

目的 制备包封率高和缓释作用好的顺铂缓释多囊脂质体,并与反相蒸发法制备的顺铂普通脂质体比较其体外释药性能。方法 用复乳法制备顺铂多囊脂质体,非火焰原子吸收分光光度法测定顺铂含量,磷脂酶试剂法测定脂质体中磷脂的浓度。测定包封率和体外释药性。结果顺铂多囊脂质体平均粒径为16.6 μm,跨距为1.0。顺铂包封率可高达80%以上。顺铂缓释多囊脂质体的体外释药符合一级释药规律, 释药t_1/2为37.7 h,比反相蒸发法制备的顺铂普通脂质体延长8.4倍。经差示热分析发现辅助膜稳定剂有明显的膜稳定作用。结论顺铂多囊脂质体包封率高,并具有良好的缓释作用。     

Intracellular delivery of doxorubicin with RGD-modified sterically stabilized liposomes for an improved antitumor efficacy: in vitro and in vivo

Passive targeting by sterically stabilized liposomes (SSL), once combined with efficient intracellular delivery, may be a very useful strategy to improve the antitumor efficacy for the anticancer agents. The arginine-glycine-aspartic acid tripeptide (RGD) is known to serve as a recognition motif for several different integrins located on cell surface. In this study, the RGD tripeptide was coupled to the distal end of the poly (ethylene glycol)-coated liposomes (RGD-SSL) aimed to achieve increased tumor accumulation and enhanced intracellular uptake. DOX-loaded RGD-SSL (RGD-SSL-DOX), DOX-loaded SSL (SSL-DOX), and free DOX were compared with respect to their in vitro uptake and cytotoxicity and their in vivo biodistribution and therapeutic efficacy in tumor-bearing mice. Flow cytometry and confocal microscopy studies revealed that RGD-SSL could facilitate the DOX uptake into melanoma cells by integrin-mediated endocytosis. RGD-SSL-DOX displayed higher cytotoxicity on melanoma cells than SSL-DOX. While RGD-SSL-DOX demonstrated prolonged circulation time and increased tumor accumulation as SSL-DOX did, it showed remarkably higher splenic uptake than SSL-DOX. Mice receiving RGD-SSL-DOX (5 mg DOX/kg) showed effective retardation in tumor growth compared with those receiving same dose of SSL-DOX, free DOX solution, or saline. These results suggest that RGD-modified SSL may be a feasible intracellular targeting carrier for efficient delivery of chemotherapeutic agents into tumor cells.     

Antagonism of paraoxon intoxication by recombinant phosphotriesterase encapsulated within sterically stabilized liposomes

This investigation effort is focused on increasing organophosphate (OP) degradation by phosphotriesterase to antagonize OP intoxication. For these studies, sterically stabilized liposomes encapsulating recombinant phosphotriesterase were employed. This enzyme was obtained from Flavobacterium sp. and was expressed in Escherichia coli. It has a broad substrate specificity, which includes parathion, paraoxon, soman, sarin, diisopropylfluorophosphate, and other organophosphorous compounds. Paraoxon is rapidly hydrolyzed by phosphotriesterase to the less toxic 4-nitrophenol and diethylphosphate. This enzyme was isolated and purified over 1600-fold and subsequently encapsulated within sterically stabilized liposomes (SL). The properties of this encapsulated phosphotriesterase were investigated. When these liposomes containing phosphotriesterase were incubated with paraoxon, it readily degraded the paraoxon. Hydrolysis of paraoxon did not occur when these sterically stabilized liposomes contained no phosphotriesterase. These sterically stabilized liposomes (SL) containing phosphotriesterases (SL)* were employed as a carrier model to antagonize the toxic effects of paraoxon by hydrolyzing it to the less toxic 4-nitrophenol and diethylphosphate. This enzyme-SL complex (SL)* was administered intravenously to mice either alone or in combination with pralidoxime (2-PAM) and/or atropine intraperitoneally. These results indicate that this carrier model system provides a striking enhanced protective effects against the lethal effects of paraoxon. Moreover when these carrier liposomes were administered with 2-PAM and/or atropine, a dramatic enhanced protection was observed.     

Preparation,characterization and evaluation of multi-component-loaded liposomes containing Tat-TOS,phospholipase D inhibitor and doxorubicin

In the present study, we aimed to co-load the α-TOS conjugate Tat-TOS with the phospholipase D inhibitor FIPI and the antitumor drug doxorubicin (DOX) in a liposome delivery system for antitumor metastasis. Firstly, Tat-TOS was synthesized by solid-phase synthesis, and its structure was confirmed. The ability of free and liposomal Tat-TOS to induce apoptosis in vitro was evaluated by flow cytometry. Biodistribution of Tat-TOS-loaded liposomes was investigated by a molecular imaging system. Multi-component-loaded liposomes modified with Tat-TOS containing FIPI and DOX was prepared by thin film dispersion method in combination with pH gradient method and post-insertion method. Physicochemical properties were determined, and the in vitro uptake ability of the formulations was evaluated. The results showed that the prepared liposomes were characterized by a uniform particle size distribution and small particle size. The encapsulation efficiency of FIPI and DOX exceeded 85%. Both free and liposomal Tat-TOS significantly improved the activity of inducing apoptosis of tumor cells. The liposomes modified with Tat-TOS were apparently accumulated in normal lung tissue and tumor metastasized lung. Multi-component-loaded liposomes exhibited the strongest cell uptake capacity, suggesting a stronger anti-metastatic effect and anti-tumor activity in vivo.     

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.     

Pulmonary administration of IgG loaded liposomes for passive immunoprophylaxy

Local passive immunoprophylaxy has been used in pulmonary infectious diseases successfully. However, the short immunoglobulins half-life in the lungs limits the duration of their action. The aim of the present study was to evaluate the efficiency of human polyvalent intravenous immunoglobulins (IVIG) when protected after encapsulation within EPC: DPPG liposomes by dehydration/rehydration. Two IVIG concentrations were chosen: 10 and 1 mg/ml for further studies in mice infected by influenza A. For the highest concentration (10 mg/ml), IVIG loaded liposomes did not significantly differ from IVIG/unloaded liposomes mixture with around 45% association yield. For the lowest concentration (1 mg/ml), two thirds of the IVIG associated were found inside the vesicles. In vivo, IVIG administered intranasally at 10 mg/ml (500 microg per mouse) 4 days before the infection led to 100% survival whatever the formulation. When administered at a lower dose (1 mg/ml-50 microg per mouse) 2 days before the challenge, loaded liposomes were found less efficient than free IVIG while unloaded liposomes showed a slight aspecific immunoprotection. Gastrointestinal clearance must be responsible for a major loss of liposomes compared to IVIG solution because of a higher viscosity of the formulation. Discrepancies with the literature are discussed.     

Antitumor activity of Cratylia mollis lectin encapsulated into liposomes

The hemagglutinating (HA) activity of Cratylia mollis lectin (Cra) was evaluated and the influence of ultrasound and mechanical agitation on its activity examined. The antitumor activity of Cra-loaded liposomes was also investigated. Liposomes were obtained by the lipid thin film method. Physicochemical characterization was carried out and long-term stability of Cra-loaded liposomes assessed. Antitumor activity of Cra-loaded liposomes was investigated against Sarcoma 180 in Swiss mice. The treatment was performed intraperitoneally (7 mg/kg body weight per day) for 7 days. Histopathological analyses of tumor, liver, spleen and kidneys were carried out after treatment of the animals. The results showed that Cra-HA activity is affected under ultrasound exposure. However, Cra was successfully encapsulated into liposomes and the activity of the lectin was preserved despite the use of ultrasound in the liposome preparation. Cra-loaded liposomes were produced with an 84% encapsulation ratio (700 microg/ml) and a tumor inhibition of 71% was achieved. The encapsulation of Cra produced a decrease in its tissue toxicity and improved its antitumor activity. In particular, histopathological analysis revealed that treatment with Cra-loaded liposomes prevented Cra cytotoxicity in the liver and kidney of animals.