Enhancement of polyethylene glycol (PEG)-modified cationic liposome-mediated gene deliveries: effects on serum stability and transfection efficiency

In this study, we modified cationic liposomes either by polyethylene glycol (PEG)-grafting or PEG-adding methods, and compared the physical properties of transfection complexes and transfection efficiency in-vitro and prolonged circulation in-vivo. The PEG-grafted transfection complexes were prepared by mixing plasmid DNA with PEG-grafted cationic liposomes, which were composed of DSPE-PEG 2000 and cationic lipids. The PEG-added transfection complexes were prepared by adding DSPE-PEG 2000 to the mixture of cationic liposomes and plasmid DNA. The particle sizes of the PEG-modified transfection complexes (approximately 200 nm) changed a little over 4 weeks compared with the conventional transfection complexes. In the presence of serum, the transfection efficiency of the conventional transfection complexes was lowered whereas the transfection efficiency of the PEG-modified transfection complexes was maintained. Moreover, the transfection efficiency of the conventional transfection complexes was significantly reduced when they were stored. However, the transfection efficiency was stable for the PEG-modified transfection complexes, even after two weeks of storage. Of the in-vitro transfection efficiencies, there was no difference between PEG-grafted and PEG-added transfection complexes. When the conventional, PEG-grafted, and PEG-added transfection complexes were administered into mice by the tail vein, the PEG-added transfection complexes showed a prolonged circulation of plasmid DNA compared with other transfection complexes. These results suggest that the PEG-added transfection complexes could be a useful non-viral vector because of their simplicity in preparation, enhanced stability and prolonged circulation compared with the conventional transfection complexes.     

Peptide-based cationic molecules for the production of positive charged liposomes and micelles

This paper describes the synthesis and the physico-chemical characterization of cationic peptides (CPs) for possible application as non-viral gene delivery systems. Particularly, the production of cationic liposomes and micelle solutions was considered. Liposomes were prepared by REV-phase and extrusion presenting an average diameter reflecting the pore size of the membrane used for the extrusion. After DNA complexation the mean diameter of complexes decreased by increasing the number of positive charges. The non-complexed liposome preparations showed a net positive zeta potential comprised between 17.8–30 mV. After adding Defibrotide (DFT) to liposomes (at a 1:4?±?molar ratio) the zeta potential fell down to a net negative value indicating the formation of the ionic complex. Concerning micelles, before complexation it was not possible to measure their size by PCS. However, after DFT complexation the size of complexes highly increased. In addition, as previously seen for liposomes, before complexation, the five CPs solutions showed a positive zeta potential ranging from 10–17.8 mV, while after addition of DFT the zeta potential fell to negative values. Concerning toxicity studies, in general CP-liposomes displayed a lower toxicity towards K562 cells as compared to the corresponding CP-solution. Taking into account these results, the studied CPs could be efficiently used to obtain both cationic liposomes and micelles. Moreover they are able to complex DNA with different interaction strength, depending on the type of peptide-based cationic molecule used.     

Characterization of DNA-lipid complexes commonly used for gene delivery.

Cationic liposomes are used to deliver genes into cells. Here we describe some poorly understood basic features of DNA-lipid complexes (lipoplexes), especially the electrostatics, stability and DNA structure of lipoplexes, and their effects on transfection (lipofection). Use of the lipophilic, pH-sensitive fluorophore 4-heptadecyl-7-hydroxycoumarin, in combination with Gouy-Chapman calculations, showed that cationic liposomes had a large positive surface potential (180-240 mV) and a high pH (10-11.5) at the location of the probe on the liposomal surface in 20 mM Hepes buffer (pH 7.4). Other electrostatic characteristics were also found, such as the existence of protonable groups of cationic or helper lipids or salt bridges between those. Addition of DNA resulted in neutralization of cationic lipids, which was lower than expected and depending on the type of lipid and the DNA/cationic lipid ratio. The liposomes containing DOTAP (N-(1-(2,3-dioleoyloxy)propyl)-N,N, N-trimethylammonium chloride) were unstable upon dilution, probably due to the high critical micellar concentration of DOTAP, 7x10(-5) M. Large instability expressed as continuous size increase was demonstrated by the time-dependent static changes in light-scattering monitored following the mixing of cationic liposomes and DNA at DNA/cationic lipid molar ratios between 0.2 and 0.8. Addition of cationic liposomes composed of 100% DOTAP or DOTAP/DOPE (1/1) liposomes, induced instantaneous transition of the plasmid DNA from the B- toward a partial C-type conformation as shown by circular dichroism (CD) spectroscopy and at certain conditions Psi--DNA could be found as well. The Psi--DNA is characterized by inter-helical interaction between parallel helices. The highest lipofection was obtained under conditions of lipoplex instability, and when the DNA was partially dehydrated and had a partial Psi-- structure.     

Preparation of chitosan-coated liposomes as a novel carrier system for the antiviral drug Triazavirin

Abstract

Novel method for the coating of positively charged liposomes with modified chitosan was elaborated. Liposomes were prepared by stepwise extrusion through inorganic membranes (Anotop) of 0.2 and 0.1?μm pore sizes. Chitosan derivatives were synthesized via the Ugi multicomponent reaction. Several series of liposomal compositions were produced and their properties were compared in terms of particle size, polydispersity index (PDI), zeta potential and stability. The effect of various additives was investigated and the optimal composition of the lipid film was determined. The addition of the uncharged fatty esters allowed the diameter of the liposomes obtained by extrusion to be reduced to 145–150?nm with a PDI of 0.13–0.15. The prepared liposomes were loaded with the novel antiviral drug Triazavirin and used to determine the release profile. Triazavirin was included into liposome layer as a salt with biocompatible choline derivatives of limiting fatty acids. The appropriate lipid composition was used for the preparation of a larger quantity of liposomes coated by modified chitosan. It was shown that an appropriate combination of liposomes and polysaccharide layer potentially extended colloidal stability by up to 3 months and exhibited broad functional capabilities for surface modification.     

Aerosolization of lipoplexes using AERx Pulmonary Delivery System

The lung represents an attractive target for delivering gene therapy to achieve local and potentially systemic delivery of gene products. The objective of this study was to evaluate the feasibility of the AERx Pulmonary Delivery System for delivering nonviral gene therapy formulations to the lung. We found that "naked" DNA undergoes degradation following aerosolization through the AERx nozzle system. However, DNA formulated with a molar excess of cationic lipids (lipoplexes) showed no loss of integrity. In addition, the lipoplexes showed no significant change in particle size, zeta (zeta) potential, or degree of complexation following extrusion. The data suggest that complexation with cationic lipids had a protective effect on the formulation following extrusion. In addition, there was no significant change in the potency of the formulation as determined by a transfection study in A-549 cells in culture. We also found that DNA formulations prepared in lactose were aerosolized poorly. Significant improvements in aerosolization efficiency were seen when electrolytes such as NaCl were added to the formulation. In conclusion, the data suggest that delivery of lipoplexes using the AERx Pulmonary Delivery System may be a viable approach for pulmonary gene therapy.     

Aerosolization of lipoplexes using AERx® pulmonary delivery system

The lung represents an attractive target for delivering gene therapy to achieve local and potentially systemic delivery of gene products. The objective of this study was to evaluate the feasibility of the AERx Pulmonary Delivery System for delivering nonviral gene therapy formulations to the lung. We found that “naked” DNA undergoes degradation following aerosolization through the AERx nozzle system. However, DNA formulated with a molar excess of cationic lipids (lipoplexes) showed no loss of integrity. In addition, the lipoplexes showed no significant change in particle size, zeta (ζ) potential, or degree of complexation following extrusion. The data suggest that complexation with cationic lipids had a protective effect on the formulation following extrusion. In addition, there was no significant change in the potency of the formulation as determined by a transfection study in A-549 cells in culture. We also found that DNA formulations prepared in lactose were aerosolized poorly. Significant improvements in aerosolization efficiency were seen when electrolytes such as NaCl were added to the formulation. In conclusion, the data suggest that delivery of lipoplexes using the AERx Pulmonary Delivery System may be a viable approach for pulmonary gene therapy.     

替诺福韦阳离子脂质体的制备及其对人体肝细胞SMMC-7721摄取和细胞毒性研究

目的:研究替诺福韦阳离子脂质体的制备及其促进肝实质细胞摄取的情况和细胞毒性作用。方法:采用叔丁醇冻干法制备替诺福韦阳离子脂质体,测定其包封率及理化性质;以SMMC-7721细胞为模型,研究脂质体对肝实质细胞摄取替诺福韦的促进作用,MTT法检测不同条件下载药脂质体对细胞的毒性情况。结果:制备的脂质体包封率为(88.3±1.6)%,粒径为(278.4±67.6)nm,Zeta电势为(31±5)mV;经半乳糖基及PEG修饰的脂质体较游离药物进入肝实质细胞的浓度明显升高,且时间延长;当替诺福韦脂质体、脂质浓度分别为7.5、30μg·mL-1时,细胞存活率在80%以上,毒性较小。结论:所制备的阳离子脂质体具有显著增加细胞摄取替诺福韦和保护替诺福韦的作用,有望成为抗病毒药物如替诺福韦等的高效传递系统。     

Biotinylated Cyclen‐Contained Cationic Lipids as Non‐Viral Gene Delivery Vectors

A series of 1, 4, 7, 10‐tetraazacyclododecane (cyclen)‐based cationic lipids, namely 5a–c bearing a biotin moiety and a variety of end groups (cholesterol, diosgenin, and α‐tocopherol) via biodegradable carbamate bond linkage were prepared and applied as non‐viral gene delivery vectors. The liposomes formed from 5 and dioleoylphosphatidylethanolamine could bind and condense plasmid DNA into nanoparticles with appropriate size and zeta potentials. All biotinylated cyclen cationic lipids showed higher cell viability than commercially available lipofectamine 2000 even at high N/P ratios, while their transfection efficiency was relatively lower. Further, results indicate that among the three lipids, α‐tocopherol‐containing compound 5c has higher DNA‐binding ability, lower cytotoxicity, and higher transfection efficiency. Transfection in two different cell lines revealed that these lipoplexes have higher gene delivery efficiency toward tumor cells.     

Peptide-based cationic molecules for the production of positive charged liposomes and micelles

This paper describes the synthesis and the physico-chemical characterization of cationic peptides (CPs) for possible application as non-viral gene delivery systems. Particularly, the production of cationic liposomes and micelle solutions was considered. Liposomes were prepared by REV-phase and extrusion presenting an average diameter reflecting the pore size of the membrane used for the extrusion. After DNA complexation the mean diameter of complexes decreased by increasing the number of positive charges. The non-complexed liposome preparations showed a net positive zeta potential comprised between 17.8-30 mV. After adding Defibrotide (DFT) to liposomes (at a 1:4 +/- molar ratio) the zeta potential fell down to a net negative value indicating the formation of the ionic complex. Concerning micelles, before complexation it was not possible to measure their size by PCS. However, after DFT complexation the size of complexes highly increased. In addition, as previously seen for liposomes, before complexation, the five CPs solutions showed a positive zeta potential ranging from 10-17.8 mV, while after addition of DFT the zeta potential fell to negative values. Concerning toxicity studies, in general CP-liposomes displayed a lower toxicity towards K562 cells as compared to the corresponding CP-solution. Taking into account these results, the studied CPs could be efficiently used to obtain both cationic liposomes and micelles. Moreover they are able to complex DNA with different interaction strength, depending on the type of peptide-based cationic molecule used.     

非特异靶向荷正电高分子磷脂脂质体的构建和体外评价

采用一种新设计的末端带有枝状结构寡赖氨酸聚乙二醇高分子磷脂为主要功能性辅料, 依照常规薄膜-水合和后续高分子插入两种方法制备了系列外表面带正电荷的高分子脂质体。激光衍射粒径仪研究证明, 常规脂质体制备方法和后续高分子插入都可以制备纳米、粒径均匀、外表面携带不同密度正电荷的高分子磷脂脂质体, 正电荷密度不同并不影响脂质体的粒径和分布。后续高分子插入过程不影响脂质体的载药工艺, 不干扰脂质体的载药量, 不引起脂质体的形态和粒径变化, 也不诱发脂质体内部包裹的药物早期泄漏。体外细胞学实验证明这种荷正电高分子脂质体局部电荷密度高, 对细胞有显著非特异性靶向作用。     

Modifications in the head group and in the spacer of cholesterol-based cationic lipids promote transfection in melanoma B16-F10 cells and tumours

A series of four cationic lipids derived from cholesterol was synthesised and their efficiencies to vectorise nucleic acids were compared. The investigation concerns the effects of systematic chemical modifications in the polar head and in the spacer. The cationic lipid molecules used are in the same family of 3beta[N-(N',N',N'-trimethylaminoethane)-carbamoyl] cholesterol iodide (TMAEC-Chol), presenting a spacer of two or three carbons and a quaternary ammonium polar head ramified with methyl or ethyl groups. These lipids formed stable liposomes sizing from 100 to 200 nm when prepared with the colipid dioleoyl phosphatidylethanolamine (DOPE). The goal of this work was to investigate the effect of the chemical structure of these cationic lipids on lipofection. Their ability to form complexes with DNA, their cytotoxicity and their transfection efficiency in vitro and in vivo were studied. Results were compared with those obtained from the well known cholesterol-based cationic lipid DC-Chol. In a melanoma cell line (B16-F10), results showed that either the polar head or the spacer affected the cytotoxicity. Cationic lipids with three ethyl groups in the head are more toxic than those with three methyl groups while cationic lipids with three carbons in the spacer are less toxic than those with two carbons in the spacer. The best transfection level was obtained in vitro and in vivo with cationic lipids having 3C in the spacer. Data indicated that among these lipids, in vivo gene transfer is advantaged by the methylated polar head while in vitro the best level was obtained with the ethylated one. Finally, it was observed that the chemical structure influences the transfection in the presence of serum while the complex charge and the DOPE ratios in liposomes preferentially affect the interaction with erythrocytes. Argumentations are proposed to explain the discrepancies between in vitro and in vivo transfection results concerning the optimal charge ratio and the chemical nature of the cationic lipid head group.     

Novel cationic lipids possessing protonated cyclen and imidazolium salt for gene delivery

In this study, two novel protonated cyclen and imidazolium salt-containing cationic lipids differing only in their hydrophobic region (cholesterol or diosgenin) have been designed and synthesized for gene delivery. Cationic liposomes were easily prepared from each of these lipids individually or from the mixtures of each cationic lipid and dioleoylphosphatidyl ethanolamine (DOPE). Several studies including DLS, gel retardation assay, ethidium bromide intercalation assay, and TEM demonstrated that these amphiphilic molecules are able to bind and compact DNA into nanometer particles that could be used as non-viral gene delivery agents. Our results from in vitro transfection showed that in association with DOPE, two cationic lipids can induce effective gene transfection in HEK293 cells. Furthermore, the gene transfection efficiencies of two cationic lipids were dramatically increased in the presence of calcium ion (Ca²⁺). It is notable that the gene transfection abilities of two cationic lipids were maintained in the presence of 10% serum. Besides, different cytotoxicity was found for two lipoplexes. This study demonstrates that the title cationic lipids have large potential to be efficient non-viral gene vector.     

Cationic lipids containing cyclen and ammonium moieties as gene delivery vectors

In this study, two novel cationic lipids containing protonated cyclen and quaternary ammonium moieties were designed and synthesized as non-viral gene delivery vectors. The structures of the two lipids differ in their hydrophobic region (cholesterol or diosgenin). Cationic liposomes were easily prepared from the lipids individually or from the mixtures of each cationic lipid and dioleoylphosphatidylethanolamine. Several studies including DLS, gel retardation assay, and ethidium bromide intercalation assay suggest that these amphiphilic molecules are able to bind and compact DNA into nanometer particles which can be used as non-viral gene delivery agents. Our results from in vitro transfection show that in association with dioleoylphosphatidylethanolamine, two cationic lipids can induce effective gene transfection in human embryonic kidney 293 cells, although the gene transfection efficiencies of two cationic lipids were found to be lower than that of lipofectamine 2000(TM) . Besides, different cytotoxicity was found for two lipoplexes. This study demonstrates that the title cationic lipids have large potential to be efficient non-viral gene vectors.     

Anionic pH-sensitive pegylated lipoplexes to deliver DNA to tumors

Anionic pegylated lipoplexes have been prepared from the combined formulation of cationic lipoplexes and pegylated anionic liposomes. To this end, two original (bis- and tetra-) carboxylated cholesterol derivatives have been synthesised. Titration of the particle surface charge was realised to determine the ratio between anionic and cationic lipids that would give pH-sensitive complexes. This ratio has been optimised to form particles sensitive to pH change in the range 5.5-6.5. Compaction of DNA into these newly formed anionic complexes was checked by DNA accessibility to picogreen and DNA electrophoresis on an agarose gel. Gene expression of the formulated gene was similar for the cationic formulation taken as a control and the anionic formulations prepared. The pH-sensitive properties of these formulations was shown in vitro using bafilomycin, a vacuolar H(+)ATPase inhibitor. The efficiency of the new formulations to deliver DNA to the tumor was compared with cholesteryl hemisuccinate (CHEMS) formulations. The tetracarboxylated compound gave the most efficient formulations for tumor delivery in vivo.     

Gene delivery using cationic liposomes

The development of cationic liposomes for gene delivery has been ongoing for almost 20 years; however, despite extensive efforts to develop a successful therapeutic agent, there has been limited progress towards generating an effective pharmaceutical product. Since the introduction of N-(1-[2,3-dioleyloxy]propyl)-N,N,N-trimethylammonium chloride, an immense number of different cationic lipids have been synthesised and used to formulate cationic liposome–DNA complexes. Structural modification of the cationic lipids and the addition of components within the delivery system that can facilitate the fusion, cellular uptake and targeting of liposome–DNA complexes have all been used in a bid to enhance their transfection efficiency. Unfortunately, the overall impact of these improvements is still nominal, with the vast majority of clinical trials (～ 85%) continuing to rely on more potent viral delivery of DNA despite their associated toxicity issues. Key characteristics of the most effective cationic liposomes for the delivery of plasmid DNA (from a consensus of the literature) is identified here and the problems of converting these attributes into an effective pharmaceutical product are outlined.     

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.     

Effect of long‐term stabilization of cationic liposomes as defibrotide delivery system for antithrombotic activity

The general goal of this study was to produce cationic liposome formulations suitable for the in vivo administration of defibrotide (DFT) (a DNA‐based drug) and to investigate in vitro and in vivo the stability of such a formulation. This article describes the freeze‐drying of cationic liposomes using as cryoprotectants different carbohydrates, such as sorbitol, mannitol, and sucrose. Liposome characteristics before and after freeze‐drying, such as size, morphology, and ability in complexing a DNA‐based drug, have been investigated. The in vitro studies indicate that cationic liposomes sufficiently maintain the initial characteristics after lyophilization and rehydration including the ability to complex DFT. The in vivo data show that lyophilized cationic liposome formulations can be safely stored for at least 3 months. Before in vivo use, liposomes can be rehydrated with DFT solutions, resulting in the formation of stable complexes retaining an in vivo activity comparable to that of the freshly prepared formulation. Drug Dev. Res. 55:127–138, 2002. © 2002 Wiley‐Liss, Inc.     

Water insoluble and soluble lipids for gene delivery

Among various synthetic gene carriers currently in use, liposomes composed of cationic lipids and co-lipids remain the most efficient transfection reagents. Physicochemical properties of lipid/plasmid complexes, such as cationic lipid structure, cationic lipid to co-lipid ratio, charge ratio, particle size and zeta potential have significant influence on gene expression and biodistribution. However, most cationic lipids are toxic and cationic liposomes/plasmid complexes do not disperse well inside the target tissues because of their large particle size. To overcome the problems associated with cationic lipids, we designed water soluble lipopolymers for gene delivery to various cells and tissues. This review provides a critical discussion on how the components of water insoluble and soluble lipids affect their transfection efficiency and biodistribution of lipid/plasmid complexes.     

阳性脂质体介导基因转染及其研究进展*

基因治疗是一种很有前景的治疗模式,而阳性脂质体介导的基因转染是目前基因治疗的研究热点之一。现综述近5年来有关阳性脂质体的文献,介绍了阳性脂质体的基本组成,并从生物学、理化性质及制剂学等几个方面介绍了影响阳性脂质体/DNA复合物转染效率的主要因素,最后从新的阳性脂质成分及阳性脂质体或阳性脂质体/DNA复合物的表面修饰等方面介绍了近年来有关改善阳性脂质体介导基因转染的研究进展。     

载基因阳离子脂质体的制备与包封率测定

目的:制备包封基因质粒的阳离子脂质体并考察其性质、测定包封率。方法:以DC-Chol和DOPE为材料,薄膜分散法制备阳离子脂质体,与可表达增强型绿色荧光蛋白的基因质粒结合并考察其转染性能,激光粒度分析仪测定阳离子脂质体和脂质复合物的粒径及Zeta电位;使用葡聚糖凝胶过滤法测定包封率,并对该法进行详细考察。结果:所制备的阳离子脂质体和脂质复合物的平均粒径分别为161.6和216.3 nm,Zeta电位分别为+22.2和+3.2 mV;基因质粒在0.1925～3.85μg.mL-1浓度范围内线性良好,精密度高,与葡聚糖无吸附作用,柱回收率高,测得脂质复合物的包封率为89.94%。结论:采用该处方和工艺可成功制备质量良好、能有效转染细胞的阳离子脂质体载体,葡聚糖凝胶过滤法可准确测定其包封率,该法快速、简便、有效。