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.     

Targeted and sustained drug delivery using PEGylated galactosylated liposomes

To achieve a sustained and targeted delivery of liposomes to liver parenchymal cells (PC), we modified distearoyl-L-phosphatidylcholine (DSPC)/cholesterol (Chol) (60:40) (DSPC/Chol) liposomes with a galactosylated cholesterol derivative (Gal-C4-Chol), and polysorbate (Tween) 20 or 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N-polyethylene glycol (PEG(x)-DSPE). After intravenous injection, DSPC/Chol/Gal-C4-Chol (60:35:5) (Gal) liposomes were rapidly eliminated from the blood circulation and mostly recovered in the liver. The blood elimination of DSPC/Chol/Gal-C4-Chol/Tween 20 (55:35:5:5) (Tween 20-Gal) liposomes was slightly reduced as compared to Gal-liposomes. In contrast, a significant reduction in the blood elimination was observed with DSPC/Chol/Gal-C4-Chol/PEG(2000)-DSPE (59:35:5:1) (PEG(2000)-Gal) liposomes. Hepatic uptake of DSPC/Chol/Gal-C4-Chol/PEG(350)-DSPE (59:35:5:1) (PEG(350)-Gal) liposomes was intermediate between PEG(2000)-Gal-liposomes and Tween 20-Gal-liposomes. The uptake of PEG(350)-Gal-liposomes by liver PC was 7.7-fold higher than that by non-parenchymal cells (NPC). These results suggest that PEG(350)-DSPE can control the delivery rate of Gal-liposomes to liver PC without losing its targeting capability.     

Reduced hepatic toxicity, enhanced cellular uptake and altered pharmacokinetics of stavudine loaded galactosylated liposomes.

The aim of the present investigation was to reduce the hepatic toxicity, enhance the cellular uptake and alter the pharmacokinetics of stavudine using galactosylated liposomes. beta-D-1-Thiogalactopyranoside residues were covalently coupled with dimyristoyl phosphatidylethanolamine, which was then used to form liposomes. The galactosylated liposomal system was assessed for in vitro ligand-specific activity. The drug release from liposomes was studied by dialysis method. Ex vivo cellular uptake study was performed using liver parenchymal cells harvested from male albino rats. Changes in hematological parameters, hepatic enzymes, hepatomegaly, plasma and tissue distribution of the formulations (free stavudine solution, uncoated liposomal and galactosylated liposomes) were determined using albino rats. Percent cumulative drug release in 24h was low (34.8+/-2.6%). Enhanced hepatic cellular d4T uptake (27.96+/-2.41pg d4T/million cells) was seen in case of galactosylated liposomal d4T. Galactosylated liposomes maintained a significant level of d4T in tissues rich in galactose specific receptors and had a prolonged residence (11.44+/-1.25h) in the body resulting in enhanced half-life of d4T (23.07+/-1.25h). This formulation did not show either hematological or hepatic toxicity. Galactosylation of liposomes alter the biodistribution of encapsulated drug thereby delivering the drug to cells bearing galactose specific receptors.     

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.     

Single-chain Fv immunoliposomes for the targeting of fibroblast activation protein-expressing tumor stromal cells

Tumor stromal cells have gained increasing attention as possible target for cancer therapy. Fibroblast activation protein (FAP) represents a cell surface antigen selectively expressed by reactive tumor stromal fibroblasts of various cancers. Here, we describe anti-FAP immunoliposomes as carrier systems for active targeting of FAP-expressing cells. As targeting ligand we used single-chain Fv (scFv) molecules cross-reacting with human and mouse FAP. These scFv molecules were genetically modified to express an additional cysteine residue at the C-terminus allowing a defined and site-directed conjugation. Coupling to Mal-PEG(2000)-DSPE containing liposomes resulted in sterically stabilized scFv immunoliposomes showing strong and specific binding to FAP-expressing cells. These immunoliposomes were highly stable when incubated under physiological conditions (human plasma, 37 degrees C). In addition, we could show that binding to FAP-expressing cells leads to internalization of intact liposomes into the endosomal compartment. Thus, these anti-FAP scFv immunoliposomes should be suitable for target cell-specific delivery and uptake of encapsulated drugs.     

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.     

Single-chain Fv immunoliposomes for the targeting of fibroblast activation protein-expressing tumor stromal cells

Tumor stromal cells have gained increasing attention as possible target for cancer therapy. Fibroblast activation protein (FAP) represents a cell surface antigen selectively expressed by reactive tumor stromal fibroblasts of various cancers. Here, we describe anti-FAP immunoliposomes as carrier systems for active targeting of FAP-expressing cells. As targeting ligand we used single-chain Fv (scFv) molecules cross-reacting with human and mouse FAP. These scFv molecules were genetically modified to express an additional cysteine residue at the C-terminus allowing a defined and site-directed conjugation. Coupling to Mal-PEG₂₀₀₀-DSPE containing liposomes resulted in sterically stabilized scFv immunoliposomes showing strong and specific binding to FAP-expressing cells. These immunoliposomes were highly stable when incubated under physiological conditions (human plasma, 37°C). In addition, we could show that binding to FAP-expressing cells leads to internalization of intact liposomes into the endosomal compartment. Thus, these anti-FAP scFv immunoliposomes should be suitable for target cell-specific delivery and uptake of encapsulated drugs.     

Design and synthesis of novel galactosylated polymers for liposomes as gene drug carriers targeting the hepatic asialoglycoprotein receptor

The 18-mer oligodeoxynucleotides (ODNs) that can inhibit survivin gene expression were selected as a model gene drug to study hepatic-targeting drug delivery system. Novel galactosylated polymers (cholesteryloxycarbonylamino) ethylamine-alpha,beta-polyasparthydrazied (CHE-PAHy-Lacs), which target asialoglycoprotein receptor on hepatic parenchymal cells (PC), were designed and synthesized as non-toxic, non-antigenic and non-teratogenic ligands for liposomes. The liposomes incorporating different CHE-PAHy-Lacs were prepared and characterized by zeta potential and particle size analyzer. The drug encapsulation efficiency was measured by gel filtration method. 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate was used as a marker for all the liposome preparations in the in vivo experiments. The CHE-PAHy-Lac liposomes produced a significant improvement in the encapsulation efficiency of ODNs (28.73-51.37%) compared with conventional liposomes (9.88%). The in vivo results showed that the liposomes incorporating CHE-PAHy-Lac, which contained about 30% (w/w) galactosyl residues, exhibited marked accumulation in the liver and hepatic PC. These results suggest that the novel galactosylated polymers used for liposomes have a great potential as a gene delivery system for hepatic targeting.     

Design and synthesis of novel galactosylated polymers for liposomes as gene drug carriers targeting the hepatic asialoglycoprotein receptor

The 18-mer oligodeoxynucleotides (ODNs) that can inhibit survivin gene expression were selected as a model gene drug to study hepatic-targeting drug delivery system. Novel galactosylated polymers (cholesteryloxycarbonylamino) ethylamine-α,β-polyasparthydrazied (CHE-PAHy-Lacs), which target asialoglycoprotein receptor on hepatic parenchymal cells (PC), were designed and synthesized as non-toxic, non-antigenic and non-teratogenic ligands for liposomes. The liposomes incorporating different CHE-PAHy-Lacs were prepared and characterized by zeta potential and particle size analyzer. The drug encapsulation efficiency was measured by gel filtration method. 1,1′-Dioctadecyl-3,3,3′,3′-tetramethylindocarbocyanine perchlorate was used as a marker for all the liposome preparations in the in vivo experiments. The CHE-PAHy-Lac liposomes produced a significant improvement in the encapsulation efficiency of ODNs (28.73–51.37%) compared with conventional liposomes (9.88%). The in vivo results showed that the liposomes incorporating CHE-PAHy-Lac, which contained about 30% (w/w) galactosyl residues, exhibited marked accumulation in the liver and hepatic PC. These results suggest that the novel galactosylated polymers used for liposomes have a great potential as a gene delivery system for hepatic targeting.     

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。     

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.     

全反式维甲酸立体稳定脂质体的制备

目的　制备全反式维甲酸(RA)的立体稳定脂质体,初步研究其物理化学性质。方法　用DSC、¹HNMR、激光粒径测定仪研究其微观结构、粒径大小及其分布,并用TEM拍摄。结果　制备的普通和立体稳定脂质体粒径分别约为0.35和0.42 μm,电镜下可观察到脂质体的立体稳定结构。结论　立体稳定脂质体中磷脂极性头部被吐温-80的聚氧乙烯基所覆盖,吐温-80掺入脂质膜,伸出的亲水性聚氧乙烯基提供了RA立体稳定脂质体的立体位阻。     

Development of pH-sensitive liposomes that efficiently retain encapsulated doxorubicin (DXR) in blood

We have reported that targeted, pH-sensitive sterically stabilized liposomes are able to increase the cytotoxicity of DXR in vitro against B lymphoma cells, but the rate of release of DXR in plasma was too rapid to permit the results to be extended to in vivo applications. The purpose of the study reported here is two-fold. First, to understand the mechanism of the rapid release of DXR from pH-sensitive sterically stabilized liposomes (PSL) in human plasma. Second, to reformulate the above liposomes to improve their drug retention, while retaining their pH sensitivity. The stability of the PSL formulations in human plasma was evaluated by comparing the rate of release of encapsulated DXR with that of HPTS, a water-soluble fluorescent marker. Since DXR, but not HPTS, a water soluble-less membrane permeable fluorescence marker, was rapidly released from liposomes in the presence of plasma, the rapid release of DXR is likely caused by the diffusion of DXR molecules through the lipid bilayer, not by the disruption of the membrane. In order to develop more stable PSL formulations, various molar ratios of the membrane rigidifying lipid, hydrogenated soy HSPC and/or CHOL, were added to the lipid composition and the rate of release of encapsulated solutes and pH-sensitivity were evaluated. The compositions that showed the best drug retention and pH-sensitivity were a mixture of DOPE/HSPC/CHEMS/CHOL/mPEG(2000)-DSPE at a molar ratio of 4:2:2:2:0.3 and DOPE/HSPC/CHEMS/CHOL at a molar ratio of 4:2:2:2. Our formulations, if targeted to internalizing antigens on cancer cells, may increase intracellular drug release rates within acidic compartment, resulting in a further increase in the therapeutic efficacy of targeted anticancer drug-containing liposomes.     

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.     

Synthesis of a novel galactosylated lipid and its application to the hepatocyte-selective targeting of liposomal doxorubicin.

This paper described the synthesis of a novel galactosylated lipid with mono-galactoside moiety, (5-Cholesten-3beta-yl) 4-oxo-4-[2-(lactobionyl amido) ethylamido] butanoate (CHS-ED-LA), and the targetability of doxorubicin (DOX), a model drug, in liposomes containing 10% mol/mol CHS-ED-LA (galactosylated liposomes, GalL) to the liver was studied. The weighted-average overall drug targeting efficiency (Te(*)) was used to evaluate the liver targetability of GalL DOX. The results showed that GalL DOX gave a relatively high (Te(*))(liver) value of 64.6%, while DOX in conventional liposome (CL DOX) only gave a (Te(*))(liver) value of 21.8%. In the liver, the GalL DOX was mainly taken up by parenchymal cells (88% of the total hepatic uptake). Moreover, preinjection of asialofetuin significantly inhibited the liver uptake of GalL DOX (from 70 to 12% of the total injected dose). It was suggested that liposomes containing such novel galactosylated lipid, CHS-ED-LA, had a great potential as drug delivery carriers for hepatocyte-selective targeting.     

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.     

Galactosylated liposomes as oligodeoxynucleotides carrier for hepatocyte-selective targeting

18mer oligodeoxynucleotides (ODNs) which can inhibit survivin gene expression were selected as a model gene drug. The glycolipid (5-cholestan-3beta-yl)-1-[2-(lactobionyl amido) ethylamido] formate (CHE-LA) which specific target to the cells expressing galactose receptors was synthesized through the reaction of lactone of lactobiono-1,5-lactone (LA) and the amino-group of 2-(cholesteryloxycarbonylamino) ethylamine (CHE). The galactosylated liposome incorporated with CHE-LA containing oligodeoxynucleotides was prepared with SPC, cholesterol, CHE-LA and oligodeoxynucleotides by the thin-film hydration method. 1,1'-Dioctadecyl-3,3,3',3'tetramethylindocarbocyanine perchlorate (Dil) was used as a marker for all the liposome preparations. Compared with conventional liposomes (CL), the galactosylated liposomes (GL) exhibited a drastically increased distribution to the liver in vivo and the galactosylated liposomes containing oligodeoxynucleotides (GLO) can also more efficiently induced an apoptosis of HepG2 cells in vitro than the conventional liposome containing oligodeoxynucleotides (CLO). In addition, the GLO represented an improving of the ODNs entrapment efficiency.     

Cell-specific delivery of genes with glycosylated carriers.

Cationic liposomes and polymers have been accepted as effective non-viral vectors for gene delivery with low immunogenicity unlike viral vectors. However, the lack of organ or cell specificity sometimes hampers their application and the development of a cell-specific targeting technology for them attracts great interest in gene therapy. In this review, the potential of cell-specific delivery of genes with glycosylated liposomes or polymers is discussed. Galactosylated liposomes and poly(amino acids) are selectively taken up by the asialoglycoprotein receptor-positive liver parenchymal cells in vitro and in vivo after intravenous injection. DNA-galactosylated cationic liposome complexes show higher DNA uptake and gene expression in the liver parenchymal cells in vitro than DNA complexes with bare cationic liposomes. In the in vitro gene transfer experiment, galactosylated liposome complexes are more efficient than DNA-galactosylated poly(amino acids) complexes but they have some difficulties in their biodistribution control. On the other hand, introduction of mannose residues to carriers resulted in specific delivery of genes to non-parenchymal liver cells. These results suggest advantages of these glycosylated carriers in cell-specific targeted delivery of genes.     

Enhancement of anti-metastatic activity of pentoxifylline by encapsulation in conventional liposomes and sterically stabilized liposomes in murine experimental B16F10 melanoma model

Pentoxifylline has been shown to exhibit anti-metastatic activity by inhibiting homing of B16F10 melanoma cells in the murine experimental metastasis model. In this study, the effect of encapsulation of pentoxifylline in conventional and sterically stabilized liposomes on its anti-metastatic activity in the murine experimental metastasis model was investigated. After a single intravenous dose (10, 20 or 40 mg kg(-1)), pentoxifylline solution, as well as conventional pentoxifylline liposomes, significantly reduced the number of pulmonary nodules compared with the untreated control group. Conventional pentoxifylline liposomes showed significantly higher inhibition (69%) of pulmonary tumour nodule formation at a dose of 20mg kg(-1) as compared with pentoxifylline solution (49%) at the same dose. Encapsulation of pentoxifylline in sterically stabilized liposomes prepared by incorporation of monomethoxypolyethyleneglycol (5000)-cholesteryl ester further enhanced the inhibition of pulmonary nodule formation (77%) at a dose of 20 mg kg(-1) as compared with conventional pentoxifylline liposomes. Overall, the results suggest that encapsulation of pentoxifylline in conventional liposomes enhanced its anti-metastatic activity. Steric stabilization of pentoxifylline liposomes also resulted in a two-fold increase in anti-metastatic activity (at dose of 10 mg kg(-1)) as compared with conventional liposomes.     

EGFR-targeted immunoliposomes derived from the monoclonal antibody EMD72000 mediate specific and efficient drug delivery to a variety of colorectal cancer cells

We hypothesized that immunoliposomes (ILs) constructed using Fab' from the humanized anti-EGFR monoclonal antibody, EMD72000, can provide efficient intracellular drug delivery in EGFR-overexpressing colorectal tumor cells.ILs were constructed modularly with various MAb fragments, including Fab' from EMD72000 (matuzumab) or C225 (cetuximab, Erbitux) covalently linked to stabilized liposomes containing chemotherapeutic drugs or probes. Immunoliposome preparation was optimized, including Fab' reduction and linkage, and evaluated for specific binding and cytotoxicity in epidermal growth factor receptor (EGFR)--overexpressing colorectal cancer cell lines in vitro. Flow cytometry showed that EGFR-targeted ILs, but not non-targeted liposomes or irrelevant ILs, were efficiently bound and internalized by a variety of EGFR-overexpressing colorectal cancer cells. Linkage of the Fab' to a longer PEG chain (Mal-PEG3400-DSPE) resulted in an increased uptake of immunoliposomal constructs when compared to previously used materials (Mal-PEG2000-DSPE). ILs derived from EMD72000-Fab' were used to deliver doxorubicin to EGFR-overexpressing target cells in vitro. Immunoliposomal doxorubicin was significantly more cytotoxic than the corresponding non-targeted liposomal drug in target cells, such as HCT116, while equivalent in cells lacking EGFR-overexpression, such as Colo205. We conclude that EGFR-targeted ILs derived from the humanized MAb EMD72000 provide efficient and targeted delivery of anticancer drugs in colorectal cancer cells overexpressing EGFR.