DOTAP/UDCA vesicles: novel approach in oligonucleotide delivery

The relatively hydrophilic bile acid, ursodeoxycholic acid (UDCA), was used as an additive to DOTAP cationic liposomes to evaluate the effect on the cellular uptake of an oligonucleotide. Nuclear magnetic resonance studies were applied to estimate the relative amount of incorporated UDCA into the lipidic bilayers. DOTAP or DOTAP-UDCA vesicles (MixVes; DOTAP/UDCA molar ratios 1:0.25, 1:0.5, 1:1, and 1:2) formed complexes with 5'-fluorescein conjugated 29-mer phosphorothioate oligonucleotides (PS-ODNs) and studied using gel electrophoresis. In addition, the complexes were tested after transfection to assess the cellular uptake and the localization of the oligo in a HaCaT cell line by the use of cytofluorimetric and confocal microscopic analysis. DOTAP lipid formulated in the presence of a defined amount of UDCA forms more stable, flexible, and active MixVes. In particular, the MixVes at 1:0.25 and 1:0.5 molar ratios increase and modify the cellular uptake of PS-ODNs if compared with DOTAP liposomes 3 hours after the transfection studies. Moreover, the in vitro data suggest that these new formulations are not toxic.     

纳米脂质体包裹胰岛素经Caco-2细胞转运的研究

目的　研究脂质体包裹胰岛素、壳聚糖包覆脂质体胰岛素对胰岛素透过Caco 2细胞的促进作用。方法　用培养于Transwell上的Caco 2细胞作为通透模型研究胰岛素的通透促进作用;用ELISA方法检测细胞裂解液中胰岛素的含量;用荧光标记的方法研究药物的通透途径。结果　脂质体,特别是壳聚糖均可以增加胰岛素的通透量。脂质体和壳聚糖可打开细胞间连接,但是生物大分子主要通过跨细胞转运进行。结论　壳聚糖包覆脂质体胰岛素促进胰岛素的跨细胞转运主要通过胞内途径进行。     

Increased intracellular targeting to airway cells using octaarginine-coated liposomes: in vitro assessment of their suitability for inhalation

Delivery of macromolecular drugs to airway cells after inhalation can be limited by rapid clearance, in vivo degradation, and poor intracellular targeting. Liposome carriers offer an effective method of improving drug stability, but conventional liposomes have limited intracellular targeting capacity and are cleared rapidly by the lungs. Further modification is required to improve liposome-cell interaction and intracellular targeting. Therefore, we proposed conjugating three arginine-rich membrane translocating peptides, namely, HIV-TAT, Antennapedia, and octaarginine, to neutral liposomes as a biocompatible alternative to cationic lipids for intracellular delivery of macromolecules to airway cells. Conjugation did not significantly affect liposome stability, and each system was nebulized to produce aerosols of mean aerodynamic diameter < 1.5 microm. The peptides caused a significant (p < 0.05) increase in liposome-airway cell association compared to untagged liposomes and to DOTAP liposomes. Up to 30% of the peptide-conjugated liposomes added were bound and internalized (via a temperature-dependent, endocytic process) after just 2 h. The novel carriers all delivered encapsulated dextrans rapidly and efficiently to the cytoplasm of Calu-3 cells. Once internalized by the cells, the modified carriers localize for the most part in the cytoplasm with only a small amount of nuclear localization. These peptide-conjugated liposomes were significantly (p < 0.05) less toxic than DOTAP liposomes with octaarginine-coated liposomes the least toxic. These systems, particularly octaarginine-coated liposomes, offer many advantages for drug delivery to airway epithelial cells including increased stability, improved cell binding, and cell uptake with an improved toxicity profile.     

Intracellular Distribution and Mechanism of Delivery of Oligonucleotides Mediated by Cationic Lipids

Purpose. To study the parameters influencing the intracellular trafficking of oligonucleotides delivered by cationic 1,2-dioleoyl-3-trimethylammonium-propane (DOTAP) lipids and to elucidate the mechanism of uptake. Methods. We have studied the intracellular localization of fluorescently labeled oligonucleotide (F-ODN) delivered by DOTAP using confocal microscopy and measured inhibition of luciferase synthesis. The delivery mechanism of ODN/DOTAP complexes was investigated using inhibitors of the endocytosis pathway. Results. F-ODN delivered by DOTAP liposomes redistribute from punctate cytoplasmic regions into the nucleus. The nuclear uptake of F-ODN depends on: charge ratio (+/–), time of incubation, temperature and presence of serum. A positively charged complex is required for enhanced uptake. The association of neutral lipids with DOTAP reduced the optimum charge ratio without altering the delivery efficiency. DOTAP lipids increased >100 fold the antisense activity of a specific anti-luciferase ODN. Inhibitors of the endocytosis pathway show that the majority of F-ODN are introduced through an endocytic pathway mainly involving uncoated vesicles. Nuclear accumulation of oligonucleotides can be decreased by inhibitors of actin microfilaments, energy metabolism and proteins implicated in the fusion of endosomes. Nuclear uptake is independent of acidification of the endosomal vesicles and unaffected by inhibitors of microtubules. Conclusions. Oligonucleotides are delivered by cationic lipids into the cytoplasm at an early stage of the endocytotic pathway which leads to a marked increase in antisense activity and oligonucleotide nuclear uptake.     

Physico-chemical characterisation and transfection efficiency of lipid-based gene delivery complexes.

Cationic liposomes spontaneously interact with negatively charged plasmid DNA to form a transfection competent complex capable of promoting the expression of a therapeutic gene. This work aims to improve the understanding of the poorly defined mechanisms and structural rearrangements associated with the lipid-DNA interaction. Specifically, dimethyl dioctadecylammonium bromide (DDAB):dioleoyl phosphatidylethanolamine (DOPE) and 1,2-dioleoyl-3-trimethylammonium propane (DOTAP) liposomes were mixed with a reporter plasmid (pADbeta or pCMVbeta) to form lipid-DNA complexes. The size and charge characteristics of the complexes as determined by photon correlation spectroscopy and microelectrophoresis were found to be dependent on the lipid:DNA ratio, with both DDAB:DOPE-DNA and DOTAP-DNA complexes aggregating at around neutral zeta potential. Negative stain transmission electron microscopy demonstrated at least three distinct complex structures being formed at the same DOTAP:DNA ratio. We postulate that two of these aggregates are structural moieties involved in the formation of the efficient transfection particle. Gel electrophoresis was used to determine the efficiency and extent of lipid-DNA complex formation. Results showed that only DOTAP liposomes were capable of preventing ethidium bromide intercalation with DNA and protecting the enclosed plasmid from nuclease digestion. When a range of lipid-DNA complexes were transfected into in vitro cell lines, the efficiency of reporter gene (beta-galactosidase) expression was found to depend on the type of liposome used in the complex, the ratio of lipid:DNA and the transfected cell line. Our results challenge the requirement for DOPE to be included in the formulation of cationic lipid vectors, especially in the case of DOTAP containing liposomes.     

Efficient telomerase inhibition in human non-small cell lung cancer cells by liposomal delivery of 2'-O-methyl-RNA

The antisense oligonucleotide 2'-O-methyl-RNA is a selective telomerase inhibitor targeting the telomerase RNA component and represents a potential candidate for anticancer therapy. The poor cellular uptake of 2'-O-methyl-RNA is a limiting factor that may contribute to the lack of functional efficacy. To improve delivery of 2'-O-methyl-RNA and consequently antitumoral efficiency in human lung cancer cells, we have investigated several transfection reagents. The transfection reagents DOTAP, MegaFectin 60, SuperFect, FuGENE 6 and MATra-A were tested for intracellular delivery. A FAM-labeled 2'-O-methyl-RNA was used to assess the intracellular distribution by confocal laser scanning microscopy in A549 human non-small cell lung cancer cells. Telomerase activity was measured using the telomeric repeat amplification protocol. Cell viability after transfection was quantified by the MTT assay. All transfection reagents enhanced 2'-O-methyl-RNA uptake in A549 cells but the cationic lipid reagents DOTAP and MegaFectin 60 were most efficient in the delivery of 2'-O-methyl-RNA resulting in telomerase inhibition. Among both DOTAP exhibited the lowest cytotoxicity. Our experiments show that DOTAP is the most suitable transfection reagent for the delivery of 2'-O-methyl-RNA in human lung cancer cells according to its relatively low cytotoxicity and its ability to promote efficient uptake leading to the inhibition of telomerase.     

Influence of cationic lipids on the stability and membrane properties of paclitaxel-containing liposomes

Paclitaxel (taxol) is a poorly soluble anticancer agent that is in widespread clinical use. Liposomes provide a less toxic vehicle for solubilizing the drug and increasing the therapeutic index of paclitaxel in model tumor systems. The role of liposome membrane composition in the stability of paclitaxel-containing formulations is understood partially for neutral and anionic liposomes, but poorly for other compositions. We investigated the effect of dialkyl cationic lipids on the stability and physical properties of paclitaxel-containing liposomes, using circular dichroism (CD), fluorescence spectroscopy, and differential interference contrast microscopy (DIC). DOTAP (1,2-dioleoyl-3-trimethylammonium propane), a cationic lipid used frequently for gene delivery, was combined at various ratios with dimyristoylphosphatidylcholine (DMPC), dipalmitoylphosphatidylcholine (DPPC), or distearoylphosphatidylcholine (DSPC). In the absence of DOTAP, the stability of liposomes containing > or =3 mol% paclitaxel was observed to follow the following rank order: DPPC >DSPC > DMPC. Increasing concentrations of DOTAP increased the physical stability of all compositions, and maximal stabilization was achieved at 30-50 mol% DOTAP, depending on the paclitaxel concentration and the acyl chain length of the phosphatidylcholine. The relationship between stability and mole fraction of DOTAP was complex for some compositions. DOTAP exerted a major fluidizing effect on DMPC, DPPC, and DSPC membranes, and the addition of paclitaxel at 3-8 mol% did not increase fluidity further. Studies of membrane phase domain behavior using the probe Laurdan (6-dodecanoyl-2-dimethylaminonaphthalene) indicated that both paclitaxel and DOTAP were miscible with the phosphatidylcholine phase. The physical events leading to destabilization of formulations are hypothesized to arise from concentration-dependent paclitaxel self-association rather than immiscibility of the membrane lipids. Given the increased incorporation and stability of paclitaxel in DOTAP-containing membranes and the potential for enhanced interaction with cells, cationic liposomes may provide a therapeutic advantage over previously described liposome formulations.     

Negatively charged liposomes show potent adjuvant activity when simply admixed with protein antigens

Liposomes have been investigated extensively as a vaccine delivery system. Herein the adjuvant activities of liposomes with different net surface charges (neutral, positive, or negative) were evaluated when admixed with protein antigens, ovalbumin (OVA, pI = 4.7), Bacillus anthracis protective antigen protein (PA, pI = 5.6), or cationized OVA (cOVA). Mice immunized subcutaneously with OVA admixed with different liposomes generated different antibody responses. Interestingly, OVA admixed with net negatively charged liposomes prepared with DOPA was as immunogenic as OVA admixed with positively charged liposomes prepared with DOTAP. Immunization of mice with the anthrax PA protein admixed with the net negatively charged DOPA liposomes also induced a strong and functional anti-PA antibody response. When the cationized OVA was used as a model antigen, liposomes with net neutral, negative, or positive charges showed comparable adjuvant activities. Immunization of mice with the OVA admixed with DOPA liposomes also induced OVA-specific CD8(+) cytotoxic T lymphocyte responses and significantly delayed the growth of OVA-expressing B16-OVA tumors in mice. However, not all net negatively charged liposomes showed a strong adjuvant activity. The adjuvant activity of the negatively charged liposomes may be related to the liposome's ability (i) to upregulate the expression of molecules related to the activation and maturation of antigen-presenting cells and (ii) to slightly facilitate the uptake of the antigens by antigen-presenting cells. Simply admixing certain negatively charged liposomes with certain protein antigens of interest may represent a novel platform for vaccine development.     

Uptake of cationzied albumin coupled liposomes by cultured porcine brain microvessel endothelial cells and intact brain capillaries

The suitability of protein-coupled liposomes as drug carriers for brain specific targeting was investigated using albumin (BSA) and cationized albumin (CBSA), respectively, as model proteins. Liposomes coated with polyethylene glycol (sterically stabilized, PEG-liposomes) were prepared from phosphatidylcholine, cholesterol, and a PEG-derivatized phospholipid and covalently coupled to thiolated BSA or CBSA. Liposomes were loaded with carboxy-fluorescein and rhodamine-labeled dipalmitoyl-phosphatidylethanolamine as hydrophilic and lipophilic marker compounds, respectively. The interaction of these constructs with monolayers of porcine brain capillary endothelial cells (BCEC) and freshly isolated porcine brain capillaries was studied by means of fluorescence assays and confocal laser scanning fluorescence microscopy (CLSFM). In contrast to BSA, CBSA was rapidly taken up by cultured BCECs. BSA-coupled liposomes did not interact with endothelial cells, whereas CBSA-coupled liposomes bound to cellular surfaces and exhibited time dependently a high intracellular accumulation. CBSA-conjugated liposomes were also taken up by intact brain capillaries. Cellular uptake could be inhibited by free cationized albumin, phenylarsineoxide, nocodazole, and filipin, but not by dansylcadaverine, suggesting a caveolae-mediated incorporation process. Immunostaining demonstrated a high expression of caveolin in the capillary endothelium. In conclusion, liposomes coupled to CBSA are taken up into brain endothelium via an endocytotic pathway and may therefore be a suitable carrier for drug delivery to the brain.     

Uptake of Cationized Albumin Coupled Liposomes by Cultured Porcine Brain Microvessel Endothelial Cells and Intact Brain Capillaries

The suitability of protein-coupled liposomes as drug carriers for brain specific targeting was investigated using albumin (BSA) and cationized albumin (CBSA), respectively, as model proteins. Liposomes coated with polyethylene glycol (sterically stabilized, PEG-liposomes) were prepared from phosphatidylcholine, cholesterol, and a PEG-derivatized phospholipid and covalently coupled to thiolated BSA or CBSA. Liposomes were loaded with carboxy-fluorescein and rhodamine-labeled dipalmitoyl-phosphatidylethanolamine as hydrophilic and lipophilic marker compounds, respectively. The interaction of these constructs with monolayers of porcine brain capillary endothelial cells (BCEC) and freshly isolated porcine brain capillaries was studied by means of fluorescence assays and confocal laser scanning fluorescence microscopy (CLSFM). In contrast to BSA, CBSA was rapidly taken up by cultured BCECs. BSA-coupled liposomes did not interact with endothelial cells, whereas CBSA-coupled liposomes bound to cellular surfaces and exhibited time dependently a high intracellular accumulation. CBSA-conjugated liposomes were also taken up by intact brain capillaries. Cellular uptake could be inhibited by free cationized albumin, phenylarsineoxide, nocodazole, and filipin, but not by dansylcadaverine, suggesting a caveolae-mediated incorporation process. Immunostaining demonstrated a high expression of caveolin in the capillary endothelium. In conclusion, liposomes coupled to CBSA are taken up into brain endothelium via an endocytotic pathway and may therefore be a suitable carrier for drug delivery to the brain.     

Modification of the C16Y peptide on nanoparticles is an effective approach to target endothelial and cancer cells via the integrin receptor

Liposomes have been explored as potential drug and gene-delivery particles. In recent years, tumor-targeted liposomes have been developed to improve the efficacy of antitumor treatment. The C16Y peptide is a modified C16 peptide, which is derived from the laminin γ1 chain, and binds to integrins α(v)β3 and α5β1 on endothelial cells. In this study, we prepared integrin-targeted C16Y peptide-modified liposomes (C16Y-L) to enhance the intracellular uptake of drugs and genes specifically into tumor tissues. The selectivity of C16Y-L for endothelial cells and cancer cells, which strongly express integrins α(v)β3 and α5β1, was assessed by flow cytometry and confocal microscopy. The cellular uptake of C16Y-L by both cell types was higher than uptake of the un-labeled and scramble peptide-modified liposomes. Next, to ascertain the involvement of receptor-mediated endocytosis in the process, these cells were treated with C16Y-L for 1h at 37°C or at 4°C. We found that uptake was also dependent on the temperature. Moreover, to evaluate whether the uptake depended on an integrin-ligand interaction, we examined the inhibition of C16Y-L uptake using recombinant integrin αVβ3 and found that the cellular uptake of C16Y-L treated with αVβ3 integrin decreased. This result suggests that C16Y-L can selectively target cells that highly express integrin αVβ3. Thus, the modification of the C16Y peptide on a Drug Delivery System (DDS) carrier may be a feasible approach for drug or gene delivery into tumors.     

Estrogen-functionalized liposomes grafted with glutathione-responsive sheddable chotooligosaccharides for the therapy of osteosarcoma

An estrogen (ES)-functionalized cationic liposomal system was developed and exploited for targeted delivery to osteosarcoma. Natural biocompatible chotooligosaccharides (COS, MW2-5?KDa) were covalently tethered to the liposomal surface through a disulfate bond (-SS-) to confer reduction-responsive COS detachment, whereas estrogen was grafted via polyethylene glycol (PEG 2?K) chain to achieve estrogen receptor-targeting. The liposomal carriers were prepared by the ethanol injection method and fluorescent anticancer drug doxorubicin (DOX) was loaded with ammonium sulfate gradient. The physicochemical properties, reduction-sensitivity, and the roles of estrogen on cellular uptake and tumor-targeting were studied. The Chol-SS-COS/ES/DOX liposomes were spherical with an average size about 110?nm, and high encapsulation efficiency. The liposomes were stable in physiological condition but rapidly release the payload in response to tumoral intracellular glutathione (20?mM). MTT cytotoxicity assay confirmed that Chol-SS-COS/ES/DOX liposomes exhibited higher cytotoxicity to MG63 osteosarcoma cells than to liver cells (LO2). Flow cytometry (FCM) and confocal laser scanning microscopy revealed that cellular uptake of Chol-SS-COS/ES/DOX liposomes by MG63, than the free DOX or Chol-SS-COS/DOX. Ex vivo fluorescence distribution study showed that the multifunctional liposomes selectively accumulated in the MG63 xenografts versus the organs. Chol-SS-COS/ES/DOX liposomes strongly inhibited the tumor growth and enhanced the animal survival rate. Overall, the COS grafted estrogen-functionalized cationic liposomes, fortified with glutathione-responsiveness, showed great potential for specific intracellular drug delivery to estrogen receptor-expressing tumors such as osteosarcoma.     

Novel cationic liposome formulation for the delivery of an oligonucleotide decoy to NF-kappaB into activated macrophages.

Nuclear factor-kappaB (NF-kappaB) is involved in several pathological processes, such as inflammation. Pro-inflammatory genes expression can be down-regulated by using an oligonucleotide (ODN) decoy to NF-kappaB. Cationic liposomes are largely used to improve ODN uptake into cells, although a higher transfection efficiency and a lower toxicity are required to use them in therapy. In this work, we investigated the potential of a novel liposome formulation, based on the recently synthesised cationic lipid (2,3-didodecyloxypropyl) (2-hydroxyethyl) dimethylammonium bromide (DE), as the delivery system for a double stranded ODN decoy to NF-kappaB. Liposomes composed of DE or DE mixed with 1,2-dioleyl-sn-glycero-3-phosphoethanolamine or cholesterol as helper lipids were complexed with ODN at different +/- charge ratios. In vitro uptake and the effect of ODN, naked or complexed with DE-containing liposomes, were evaluated in lipopolysaccharide-stimulated RAW 264.7 macrophages. The use of helper lipids increased liposome physical stability up to 1 year at 4 degrees C. ODN complexed with DE/cholesterol liposomes, at the +/- charge ratio of 8, showed a limited cytotoxicity and the highest inhibition of nitrite production, inducible nitric oxide synthase protein expression and NF-kappaB/DNA binding activity. Confocal microscopy confirmed a high ODN cell uptake obtained with DE/cholesterol liposomes at the highest +/- charge ratio.     

TPGS修饰脂质体对阿霉素抗肿瘤活性的增敏作用

目的制备聚乙二醇1000维生素E琥珀酸酯(TPGS)修饰的阿霉素脂质体并考察其对阿霉素抗肿瘤活性的增敏作用。方法用阳离子树脂吸附法测定阿霉素脂质体的包封率;MTT法测定对MCF-7和MCF-7/ADR的毒性;用荧光显微镜观察阿霉素的细胞摄取,并用HPLC测定细胞内的阿霉素含量。结果 TPGS修饰的阿霉素脂质体增加了MCF-7/ADR对阿霉素的摄取,并增强了对MCF-7和MCF-7/ADR细胞的毒性。结论 TPGS修饰脂质体能显著增强MCF-7和MCF-7/ADR对阿霉素的敏感性。     

Preparation and gene delivery of alkaline amino acids-based cationic liposomes

Cationic lipids 1, 2, and 3, based on hydrophobic cholesterol linked to L-lysine, L-histidine or L-arginine, respectively, were designed and tested as gene delivery vectors. Physicochemical and biological properties of all liposomes and lipoplexes were evaluated, including lipid-DNA interactions, size, morphology, zeta potential, acid-base buffering capability, protection of DNA from DNase I digestion, and cytotoxity. The efficiency of luciferase gene transfection of lipoplexes 1-3 was compared with that of commercial dioleoyl-trimethylammonium propane (DOTAP) and polyethyleneimine (PEI) in 293T cells and HepG2 cells with or without poly(ethylene glycol) PEG stabilizer. The complexation and protection of DNA of liposome 3 was the strongest among the three liposomes. The efficiency of gene transfection of liposomes 1-3 was two-to threefold higher than that of PEI and/or DOTAP in 293T cells. Liposomes 1 and 3 in PEG as stabilizer showed sixfold higher transfection efficiency than that of PEI and/or DOTAP, whereas liposome 2 showed very low transfection efficiency. In HepG2 cells, the transfection efficiency of all the cationic liposomes was much lower than that of DOTAP. In conclusion, lipids 1-3 were efficient and non-toxic gene vectors; the headgroup of cationic lipids and the stabilizer of liposome formulation had an important influence on gene transfection.     

Characterization of endotoxin and cationic liposome interaction

The objective of this study was to characterize the interaction of endotoxin with cationic liposomes used in nonviral gene delivery. Endotoxin-cationic liposome interaction was characterized using fluorescent anisotropy, and the Limulus amebocyte lysate (LAL) assay. Cellular toxicity of endotoxin-cationic liposome complex was examined using a dimethylthiazol diphenyltetrazolium bromide (MTT) assay. The effect of endotoxin on the lipid-DNA complex and subsequent transfection into COS-1 cells was also examined. A competitive interaction occurred between fluoroscein isothiocyanate (FITC)-labeled endotoxin and plasmid DNA for binding dioleoyl glycero trimethylammonium propane:dioleoyl glycero phosphoethanolamine (DOTAP:DOPE) liposomes using fluorescent anisotropy techniques. The LAL assay demonstrated no change in endotoxin activity upon interaction with liposomes. No loss of COS cell viability was detected via the MTT assay during a 5-hr exposure to endotoxin. Transient transfection studies indicate that increasing levels of endotoxin lowered activity more than 90% at 50,000 endotoxin units (EU)/ml. Endotoxin and cationic liposomes interact mainly by an electrostatic attraction. Endotoxin contamination can potentially impact transfection efficiency via competition with plasmid DNA for cationic liposome binding by increasing transfection variability at 50 EU/ml, a concentration of endotoxin contamination that can occur with small-scale plasmid preparations used for in vitro cell transfections, but would not be expected with typical GLP or GMP preparations used in clinical studies.     

The Effect of Surface Charges on the Cellular Uptake of Liposomes Investigated by Live Cell Imaging

Purpose

Liposomes have been developed as versatile nanocarriers for various pharmacological agents. The effect of surface charges on the cellular uptake of the liposomes has been studied by various methods using mainly fixed cells with inevitable limitations. Live cell imaging has been proposed as an alternative methods to overcome the limitations of the fixed cell-based analysis. In this study, we aimed to investigate the effects of surface charges on cellular association and internalization of the liposomes using live cell imaging.

Methods

We studied the cellular association and internalization of liposomes with different surface charge using laser scanning confocal microscopy (LSCM) equipped with live cell chamber system. Flow cytometry was also carried out using flow cytometer (FACS) for comparison.

Results

All of the cationic, neutral and anionic liposomes showed time-dependent cellular uptake through specific endocytic pathways. In glioblastoma U87MG cells, the cationic and anionic liposomes were mainly taken up via macropinocytosis, while the neutral liposomes mainly via caveolae-mediated endocytosis. In fibroblast NIH/3T3 cells, all of the three liposomes entered into the cell via clathrin-mediated endocytosis.

Conclusions

This study provides a better understanding on the cellular uptake mechanisms of the liposomes, which could contribute significantly to development of liposome-based drug delivery systems.

     

Liposomal delivery improves the growth-inhibitory and apoptotic activity of low doses of gemcitabine in multiple myeloma cancer cells

Gemcitabine-loaded pegylated unilamellar liposomes (200 nm) were proposed for the treatment of multiple myeloma cancer disease. Physicochemical and technological parameters of liposomes were evaluated by using laser light scattering and gel permeation chromatography. The growth-inhibitory activity of gemcitabine-loaded liposomes compared to the free drug was assayed in vitro on U266 (autocrine, interleukin-6-independent) and INA-6 (IL-6-dependent) multiple myeloma cell lines. Liposomes noticeably improved the growth-inhibitory activity of gemcitabine in terms of both dose-dependent and incubation-time effects. Liposomal delivery of gemcitabine consistently and significantly increased induction of apoptosis and caused a complete inhibition of proliferation. Liposomes were able to interact with multiple myeloma cells as demonstrated by confocal laser scanning microscopy and hence to improve the intracellular gemcitabine delivery. Gemcitabine-loaded liposomes were much more effective in vitro than the free drug. This formulation may offer even more in vivo advantages both in terms of drug pharmacokinetic and biodistribution.     

Uptake of apolipoprotein E fragment coupled liposomes by cultured brain microvessel endothelial cells and intact brain capillaries

The suitability of surface modified liposomes as drug carriers for brain-specific targeting was investigated using apolipoprotein E fragments as brain-directed vectors. Liposomes coated with polyethylene glycol-2000 (sterically stabilized, PEGylated liposomes) were prepared from hydrogenated egg phosphatidylcholine, cholesterol, and a PEG-derivatized phospholipid. Liposomes were covalently coupled to a peptide of 26 amino acids length, derived from the binding site of human apolipoprotein E4 (ApoE4) and a peptide of random amino acid sequence, respectively. Rhodamine-labeled dipalmitoylphosphatidylethanolamine was incorporated into the lipid bilayer in order to visualize the liposomal interaction with brain capillary endothelial cell monolayers. The interaction of the liposomes with monolayers of porcine brain capillary endothelial cells (BCEC), the rodent cell line RBE4, and freshly isolated porcine brain capillaries was studied by means of confocal laser scanning fluorescence microscopy. In contrast to random peptide coupled liposomes, the ApoE4-fragment coupled liposomes were rapidly taken up by cultured BCECs and RBE4 cells. Uptake could be inhibited by ApoE4, free peptide, and antibodies against the LDL receptor in a concentration-dependent manner. The results indicate that the liposomes are internalized via the LDL receptor, which is expressed at the blood?brain barrier. In conclusion, liposomes coupled to ApoE4 fragments are taken up into brain endothelium via an endocytotic pathway and may therefore be a suitable carrier for drug delivery to the brain.