Imidazolyl-PEI modified nanoparticles for enhanced gene delivery

The derivatives of polyethylenimine (PEI 25 and 750kDa) were synthesized by partially substituting their amino groups with imidazolyl moieties. The series of imidazolyl-PEIs thus obtained were cross-linked with polyethylene glycol (PEG) to get imidazolyl-PEI-PEG nanoparticles (IPP). The component of hydrophobicity was introduced by grafting the lauryl groups in the maximal substituted IPP nanoparticles (IPPL). The nanoparticles were characterized with respect to DNA interaction, hydrodynamic diameter, zeta potential, in vitro cytotoxicity and transfection efficiency on model cell lines. The IPP and IPPL nanoparticles formed a loose complex with DNA compared to the corresponding native PEI, leading to more efficient unpackaging of DNA. The DNA loading capacity of IPP and IPPL nanoparticles was also lower compared to PEI. The imidazolyl substitution improved the gene delivery efficiency of PEI (750kDa) by nine- to ten-fold and PEI (25kDa) by three- to four-fold. At maximum transfection efficiency, the zeta potential of nanoparticles was positive after forming a complex with DNA. The maximum level of reporter gene expression was mediated by IPPL nanoparticles in both the series. The cytotoxicity, another pertinent problem with cationic polymers, was also negligible in case of IPP and IPPL nanoparticles.     

Guanidinium-grafted polyethylenimine: an efficient transfecting agent for mammalian cells.

Polyethylenimine (PEI) is one of the most efficient polycationic non-viral gene delivery vectors. Its efficiency and cytotoxicity depends on molecular weight, with the 25-kDa PEI being most efficient but accompanied with cytotoxicity. In the present study, enhancement in gene delivery efficiency along with reduction in cytotoxicity by attachment of guanidinium side group was explored. The hypothesis was that the guanidination would lead to the delocalization of charge present on primary amines of the polymer thereby leading to enhancement in gene delivery efficiency along with reduction in cytotoxicity. The polymer was guanidinated using O-methylisourea hemisulfate and the chemical linkage characterized by FTIR spectroscopy. The hydrodynamic diameter of guanidinated PEI-DNA complexes was determined using DLS. Subsequently, these complexes were used for DNA binding assay and zeta-potential measurements, taking native PEI as reference. Further, guanidinated PEI-DNA complexes were investigated for their gene delivery efficacy on HEK 293 cells. The hydrodynamic diameter of guanidinated PEI-DNA complexes was found to be in the range of 176-548 nm. As expected, the zeta potential values increased, on increasing the N/P ratios. It was found that guanidinated PEI had higher transfection efficiency at the majority of the N/P ratios tested as compared to commercially available transfecting agent lipofectin and native PEI itself. The toxicity of guanidinated PEI-DNA complexes was also reduced considerably in comparison to PEI polymer, as determined by MTT colorimetric assay. Out of the various derivatives prepared, gPEI 56% was found to be the most efficient in in vitro transfection.     

PEG化聚乙烯亚胺作为非病毒基因给药载体的研究

采用不同比例的单甲氧基聚乙二醇-琥珀酰亚胺基丙酸盐（mPEG-SPA）对支链聚乙烯亚胺（PEI）进行修饰，考察了不同接枝率的mPEG-PEI与DNA复合物的粒径、ζ‘电位、包封率，及其对A549细胞的转染效率和细胞毒性。体外转染试验表明，低PEG接枝率的PEI转染效果与PEI相当，且细胞毒性大大降低。     

Polyethylenimine nanoparticles as an efficient in vitro siRNA delivery system

Degradation of mRNA by RNA interference is one of the most powerful and specific mechanism for gene silencing. Owing to this property, siRNAs are emerging as promising therapeutic agents for the treatment of inherited and acquired diseases, as well as research tools for the elucidation of gene function in both health and disease. Here we have explored the potential of polyethylenimine (PEI) to deliver siRNA to mammalian cells. Nanoparticles of PEI were prepared by acylating PEI with propionic anhydride followed by cross-linking with polyethylene glycol-bis(phosphate). The nanoparticles size as revealed by DLS studies was found to be 110 nm and AFM investigations showed spherical and compact complexes with an average size of 100 nm. For electro-neutralization of negative charge of siRNA higher amount of nanoparticles was required as compared to native PEI. The siRNA delivery efficiency of nanoparticles was assessed by using siRNA against gene coding for green fluorescent protein (GFP). The gene silencing efficiency of PEI nanoparticles was found to be comparable to commercially available transfecting agent Lipofectin but with reduced cytotoxicity.     

A one-step process in preparation of cationic nanoparticles with poly(lactide-co-glycolide)-containing polyethylenimine gives efficient gene delivery

A one-step preparation of nanoparticles with poly(lactide-co-glycolide) (PLGA) pre-modified with polyethylenimine (PEI) is better in requirements for DNA delivery compared to those prepared in a two-step process (preformed PLGA nanoparticles and subsequently coated with PEI). The particles were prepared by emulsification of PLGA/ethyl acetate in an aqueous solution of PVA and PEI. DLS, AFM and SEM were used for the size characteristics. The cytotoxicity of PLGA/PEI nanoparticles was detected by MTT assay. The transfection activity of the particles was measured using pEGFP and pβ-gal plasmid DNA. Results showed that the PLGA/PEI nanoparticles were spherical and non-porous with a size of about 0.2 μm and a small size distribution. These particles had a positive zeta potential demonstrating that PEI was attached. Interestingly, the zeta potential of the particles (from one-step procedure) was substantially higher than that of two-step process and is ascribed to the conjugation of PEI to PLGA via aminolysis. The PLGA/PEI nanoparticles were able to bind DNA and the formed complexes had a substantially lower cytotoxicity and a higher transfection activity than PEI polyplexes. In conclusion, given their small size, stability, low cytotoxicity and good transfection activity, PLGA/PEI-DNA complexes are attractive gene delivery systems.     

Biophysical characterization of PEI/DNA complexes

The main goal of this study was to determine the effects of polyethylenimine (PEI) molecular weight and structure (750 kDa, 25 kDa, 2 kDa branched, and 25 kDa linear PEI) and the nitrogen/phosphate (N/P) molar ratio on the physical properties and transfection efficiencies of PEI/DNA complexes. Fourier transform infrared spectroscopy revealed that DNA remained in the B conformation when complexed to all PEIs. Unique alterations in the circular dichroism spectra of DNA were observed in the presence of each PEI, whereas differential scanning calorimetry measurements showed that all PEIs examined destabilized supercoiled DNA at N/P < 3/1, but not at higher ratios. Isothermal titration calorimetry revealed the existence of protonation changes at low ionic strength due to possible shifts in pK(a) of the ionizable groups of PEI during complex formation. Twenty-five kilodalton branched and 25 kDa linear PEI complexes showed the highest transfection efficiencies at an N/P ratio of 6:1 in COS-7 and CHO-K1 cells, respectively. These investigations have detected alterations in the physical and colloidal properties of the complexes that were sensitive to polymer structure, molecular weight, and polymer/DNA ratio, but these properties did not directly correlate with their transfection efficiencies. To further probe any possible relationship between these parameters and activity, a more refined biophysical analysis of any subpopulations in these samples that may differ in transfection activity is suggested, although the existence of such species remains unknown.     

Serum-resistant lipopolyplexes for gene delivery to liver tumour cells.

In this study, an efficient non-viral gene transfer system has been developed by employing polyethylenimine (PEI 800, 25 and 22kDa) and DOTAP and cholesterol (Chol) as lipids (lipopolyplex), at three different lipid/DNA molar ratios (2/1, 5/1 and 17/1) by using five different protocols of formulation. Condensation assays revealed that PEI of 800, 25 and 22kDa were very effective in condensing plasmid DNA, leading to a complete condensation at N/P ratios above 4. Addition of DOTAP/Chol liposomes did not further condense DNA. Increasing the molar ratio lipid/DNA in the complex resulted in higher positive values of the zeta-potential, while the particle size increased in some protocols, but not in others. High molecular weight PEI (800kDa) used in the formulation of lipopolyplexes lead to a bigger particle size, compared to that obtained with smaller PEI species, whether branched (25kDa) or linear (22kDa). These vectors were also highly effective in protecting DNA from attack by DNAse I. Transfection activity was maximal by using protocols 3 and 4 and a lipid/DNA molar ratio of 17/1. These complexes showed high efficiency in gene delivery of DNA to liver cancer cells, even in the presence of high concentration of serum (60% FBS). On the other hand, complexes formed with linear PEI (22kDa) were more effective than lipopolyplexes containing branched PEI (800 or 25kDa). The complexes resulted to be much more efficient than conventional lipoplexes (cationic lipid and DNA) and polyplexes (cationic polymer and DNA). The same behaviour was observed for complexes prepared in the presence of the therapeutic gene pCMVIL-12. Toxicity assays revealed a viability higher than 80% in all cases, independently of the protocol, molar ratio (lipid/DNA), molecular weight and type of PEI.     

Skin photoprotection improvement: synergistic interaction between lipid nanoparticles and organic UV filters

The main objective of this study was to prepare two types of nanoparticles with poly(d,l-lactide-co-glycolide) (PLGA) and polyethylenimine (PEI) polymers. Plasmid DNA (pDNA) was adsorbed either on PLGA/PEI nanoparticles, or as PEI/DNA complex onto the surface of PLGA nanoparticles. Both types of nanoparticles were prepared by the double emulsion method. The nanoparticles were characterized by their size, zeta potential and pDNA or PEI/DNA complex adsorption. The PEI/DNA complex adsorption was confirmed with ethidium bromide assay. pDNA adsorption onto PLGA/PEI nanoparticles (PLGA/PEI-DNA) was studied by electrophoresis on agarose gel. Cytotoxicity and transfection efficiency of both types of nanoparticle and PEI/DNA complexes formulations were studied in head and neck squamous carcinoma cell line (FaDu). To improve endosomal release, photochemical internalization (PCI) was used. The zeta potential increased when the PEI/DNA complex adsorbed onto PLGA nanoparticles (PLGA-PEI/DNA). Optimal pDNA adsorption efficiency was achieved for nitrogen/phosphorous ratio≥20/1. In vitro transfection and cells viability on FaDu cells with or without PCI were found to be variable depending on the type and concentration of nanoparticles. The results showed that transfection efficiency for PLGA/PEI-DNA or PLGA-PEI/DNA nanoparticles ranged between 2 and 80%, respectively. PCI was found to slightly improve the transfection efficiency for all formulations.     

Cross-linked polyethylenimine-hexametaphosphate nanoparticles to deliver nucleic acids therapeutics

Branched polyethylenimine (PEI; 25 kDa) as a nonviral vector exhibits high transfection efficiency and is a potential candidate for efficient gene delivery. However, the cytotoxicity of PEI limits its application in vivo. PEI was ionically interacted with hexametaphosphate, a compact molecule with high anionic charge density, to obtain nanoparticles (PEI-HMP). Nanoparticles were assessed for their efficacy in protecting complexed DNA against nucleases. The intracellular trafficking of nanoparticles was monitored by confocal microscopy. The cytotoxicity and transfection efficiency of PEI-HMP nanoparticles were evaluated in vitro. In vitro transfection efficiency of PEI-HMP (7.7%) was ～1.3- to 6.4-folds higher than that of the commercial reagents GenePORTER 2^TM, Fugene^TM, and Superfect^TM. Also, PEI-HMP (7.7%) delivered green fluorescent protein (GFP)-specific small interfering ribonucleic acid (siRNA) in culture cells leading to >80% suppression in GFP gene expression. PEI-HMP nanoparticles protected complexed DNA against DNase for at least 2 hours. A time-course uptake of PEI-HMP (7.7%) nanoparticles showed the internalization of nanoparticles inside the cell nucleus in 2 hours. Thus, PEI-HMP nanoparticles efficiently transfect cells with negligible cytotoxicity and show great promise as nonviral vectors for gene delivery.From the Clinical EditorBranched polyethylenimine (PEI) as a non-viral vector exhibits high transfection efficiency for gene delivery, but its cytotoxicity limits its applications. PEI hexametaphosphate nanoparticles (PEI-HMP) demonstrated a 1.3-6.4 folds higher transfection rate compared to commercial reagents. Overall, PEI-HMP nanoparticles efficiently transfect cells with negligible cytotoxicity and show great promise as non-viral vectors for gene delivery.     

Gene delivery and expression in human retinal pigment epithelial cells: effects of synthetic carriers, serum, extracellular matrix and viral promoters

Non-viral gene therapy is a potential treatment to many incurable retinal diseases. To fulfill this promise, plasmid DNA must be delivered to the retinal target cells. We evaluated the efficacy of synthetic DNA complexing compounds in transfecting primary human retinal pigment epithelial (RPE) cells in vitro. Fetal human RPE cells were cultured with or without extracellular matrix (ECM), produced using calf corneal endothelial cells. Plasmids encoding nuclear localizing beta galactosidase or luciferase (pRSVLuc, pCLuc4, pSV2Luc) were complexed in water at various +/- charge ratios using cationic lipids (Lipofectin, DOTAP, DOGS), polyethylene imines (25 and 750 kDa), and with degraded 6th generation starburst polyamidoamine dendrimers. Luciferase was quantified using a luminometric assay and beta galactosidase with X-gal staining. Toxicities of transfections were evaluated with the MTT-assay. Using beta galactosidase as the reporter gene naked DNA did not transfect RPE cells at measurable levels whereas 1-5% of the cells expressed histochemically detectable amounts of the gene after transfection with cationic lipid DNA complexes. In RPE cells, Rous sarcoma virus and cytomegalovirus (CMV) were more efficient promoters than SV40 in driving luciferase expression, and CMV was chosen for further experiments. At optimal complex charge ratios, expression levels of luciferase were > 10(9) light units/mg protein after transfection using dendrimers and PEI25, while transfection mediated with the other carriers resulted in luciferase expression levels of 10(7)-10(9) light units/mg protein or less. In general, dendrimers and large molecular weight PEI were less toxic than cationic lipids or PEI25 to RPE cells. Serum and ECM decreased gene expression to the RPE cells with all carriers. Despite low percentage of transfected cells the transgene expression per RPE cell is high, important feature in the retinal tissue with small dimensions, in particular in the case of secreted gene products. Degraded dendrimers and high molecular weight PEI exhibited the best combination of high activity and low toxicity in RPE cell transfection.     

Formulation and characterization of DNA-polyethylenimine-dextran sulfate nanoparticles.

Polyethylenimine (PEI) is a promising non-viral gene delivery polymer that produces high transfection efficiency both in vitro and in vivo. The use of PEI, however, is hindered by its toxicity, reflecting its polycationic nature. In an attempt to decrease this charge-dependent cytotoxicity, a polyanionic polymer, dextran sulfate (DS), has been incorporated into self-assembling PEI-DNA complexes with zinc as stabilizing agent. Spherical particles with a mean particle size of approximately 200 nm and a polydispersity index of 0.2 were achieved using the following optimal conditions: PEI solutions at pH 8, PEI/DS mass ratios of >or=2, and 25 microM zinc sulfate. Plasmid DNA was completely condensed within the nanoparticles as confirmed by an ethidium bromide accessibility assay. This result correlates well with DNase protection studies which find partial protection of the DNA nanoparticles from degradation by the enzyme. The DNA was incorporated into the PEI-DS particles with a high efficiency (>95%) and maintained a primarily supercoiled B-form as determined by gel electrophoresis and circular dichroism. The cytotoxicity of the DNA nanoparticles appeared to decrease as the amount of DS in the formulation was increased and they produced moderate transfection activities that were only modestly inhibited by the presence of serum.     

Polyethylenimine PEI F25-LMW allows the long-term storage of frozen complexes as fully active reagents in siRNA-mediated gene targeting and DNA delivery.

Background: Polyethylenimines (PEIs) are synthetic, charged polymers which function as transfection reagents based on their ability to compact DNA into complexes. Recently, PEI-mediated delivery of nucleic acids has been extended towards small interfering RNAs (siRNAs) which are instrumental in the induction of RNA interference (RNAi). Since RNAi represents a powerful method for specific gene silencing, the PEI-based delivery of siRNAs is a promising tool for novel putative therapeutic strategies. Aim: For therapeutic use, major requirements are the development of formulations which (i) are sufficiently stable in the presence of serum, and which can be (ii) easily and reproducibly manufactured and (iii) stored for a prolonged time with full retention of their integrity and bioactivity. In this paper, we explore the potential of PEI F25-LMW, a low-molecular weight PEI with superior transfection efficacy and low toxicity, towards these goals. Results: We have systematically analyzed and determined optimal DNA and siRNA complexation conditions with regard to various parameters including buffer concentration, ionic strength, pH and incubation time. As opposed to 22kDa linear PEI (L-PEI), the low-molecular weight (4-10kDa) PEI F25-LMW performs DNA transfection and siRNA gene targeting with identical efficacies in the presence of serum, thus emphasizing its usefulness in vivo. Furthermore, in contrast to other polyethylenimines, PEI F25-LMW-based DNA or siRNA complexes allow freeze/thawing and frozen storage for several months. Their activity is fully retained without requiring specific buffer conditions or the addition of any lyoprotectant. Physicochemical analysis and atomic force microscopy reveal a distinct size pattern with the presence of two complex subgroups and show that frozen PEI F25-LMW complexes remain stable with little increase in complex size, no changes regarding their zeta potential and cytotoxicity, and full retention of nucleic acid protection. Conclusions: Frozen PEI F25-LMW-based complexes represent efficient and stable ready-to-use formulations of DNA- or siRNA-based gene therapy products.     

Blending of polyethylenimine with a cationic polyurethane greatly enhances both DNA delivery efficacy and reduces the overall cytotoxicity

Three blending methods were introduced to combine a biodegradable cationic- polyurethane (PUg3) and polyethylenimine (PEI) together with DNA by different mixing sequences. Results of gel electrophoresis assays and particle size measurements show that complexes prepared by method 1 and 3 bear an ability to condense DNA into small nanoparticles. On the contrary, the use of method 2 in making complexes produces significantly large particles because of the weaker interaction with DNA and lack of DNA condensation. Moreover, cell proliferation assays show that no cytotoxicity of the DNA/blended-polymers complexes (exhibited by method 1) was found and due to a result of the outer coating of PUg3, reducing cytotoxic PEI exposure outside the complexes. With a new technique in pharmaceutics, the complexes prepared for DNA delivery by mixing of PEI and PUg3 with DNA in a sequence (method 1) could achieve an even better transfection efficiency (reaching 40% higher) than using PEI alone as well as reduce the cytotoxicity substantially. In conclusion, a new class of complexes (non-viral combo-system) made by a skillful blending sequence (method 1) has been designed and demonstrated to obtain the beneficial properties from two useful and individual polymers for gene delivery. This method can be used in greatly improving the transfection efficiency of polymer-based gene vectors. The blended polymers with DNA also have a better biocompatibility and no cytotoxicity, which are the requirements and critical points for great success in performing gene therapy in vivo.     

Factors determining the superior performance of lipid/DNA/protammine nanoparticles over lipoplexes

The utility of using a protammine/DNA complex coated with a lipid envelope made of cationic 1,2-dioleoyl-3-trimethylammonium propane (DOTAP) for transfecting CHO (Chinese hamster ovary cells), HEK293 (human embryonic kidney cells), NIH 3T3 (mouse embryonal cells), and A17 (murine cancer cells) cells was examined. The widely used DOTAP/DNA lipoplex was employed as a reference. In all the tested cell lines lipid/protamine/DNA (LPD) nanoparticles were more efficient in transfecting cells than lipoplexes even though the lipid composition of the lipid envelope was the same in both devices. Physical-chemical properties were found to control the ability of nanocarriers to release DNA upon interaction with cellular membranes. LPD complexes easily release their DNA payload, while lipoplexes remain largely intact and accumulate at the cell nucleus. Collectively, these data explain why LPD nanoparticles often exhibit superior performances compared to lipoplexes in trasfecting cells and represent a promising class of nanocarriers for gene delivery.     

Lipoic acid modified low molecular weight polyethylenimine mediates nontoxic and highly potent in vitro gene transfection

The clinical success of gene therapy intimately relies on the development of safe and efficient gene carrier systems. We found here that 1.8 kDa polyethylenimine (PEI) following hydrophobic modification with lipoic acid (LA) mediated nontoxic and highly potent in vitro gene transfection in both HeLa and 293T cells. 1.8 kDa PEI-LA conjugates were prepared with controlled degree of substitution (DS) by coupling LA to PEI using carbodiimide chemistry. Gel electrophoresis measurements showed that the DNA binding ability of 1.8 kDa PEI was impaired by lipoylation, in which an N/P ratio of 2/1 and 4-6/1 was required for 1.8 kDa PEI and 1.8 kDa PEI-LA conjugates, respectively, to completely inhibit DNA migration. Interestingly, dynamic light scattering measurements (DLS) revealed that PEI-LA conjugates condensed DNA into much smaller sizes (183-84 nm) than unmodified 1.8 kDa PEI (444-139 nm) at N/P ratios ranging from 20/1 to 60/1. These polyplexes revealed similar surface charges of ca. +22 to +30 mV. 1.8 kDa PEI-LA(2) polyplexes formed at an N/P ratio of 10/1 were stable against exchange with 12-fold excess of negatively charged dextran sodium sulfate (DSS) relative to DNA phosphate groups while 1.8 kDa PEI controls dissociated at 6-fold excess of DSS, indicating that lipoylation of 1.8 kDa PEI resulted in stronger binding with DNA. Importantly, DNA was released from 1.8 kDa PEI-LA(2) polyplexes upon addition of 10 mM dithiothreitol (DTT). Reduction-triggered unpacking of 1.8 kDa PEI-LA(2) polyplexes was also confirmed by DLS. MTT assays demonstrated that all PEI-LA conjugates and polyplexes were essentially nontoxic to HeLa and 293T cells up to a tested concentration of 50 μg/mL and an N/P ratio of 80/1, respectively. The in vitro gene transfection studies in HeLa and 293T cells showed that lipoylation of 1.8 kDa PEI markedly boosted its transfection activity. For example, 1.8 kDa PEI-LA(2) polyplexes displayed 400-fold and 500-fold higher levels of gene expression than unmodified 1.8 kDa PEI controls, which were ca. 2-fold and 3-fold higher than 25 kDa PEI controls, in serum-free and 10% serum media, respectively. The transfection efficiency decreased with increasing DS, following an order of 1.8 kDa PEI-LA(2) > 1.8 kDa PEI-LA(4) > 1.8 kDa PEI-LA(6) ? 1.8 kDa PEI. Confocal laser scanning microscopy (CLSM) studies corroborated that 1.8 kDa PEI-LA(2) delivered and released DNA into the nuclei of HeLa cells more efficiently than 25 kDa PEI. These nontoxic 1.8 kDa PEI-LA conjugates form a superb basis for the development of targeting, biocompatible and highly efficient carriers of gene delivery.     

聚乙烯亚胺-DNA复合物的形成和聚集行为研究

聚乙烯亚胺 (polyethyleneimine,PEI) 是一种优良的非病毒基因传输载体材料,本文对PEI/DNA复合物粒子的形成机制进行了初步探讨,电泳阻滞实验和紫外测定实验表明, 复合物的形成过程中存在着某种过渡状态即珠串样结构,透射电镜的结果提供了相应的例证。此外通过离子强度实验,作者认为在PEI与DNA的复合过程尽管以静电作用为主要作用力,同时也可能存在着其他类型的非静电作用力。PEI/DNA复合物粒子的表面电荷随着N/P的增加逐步增加,但由于DNA的分子质量较大,在N/P为8和12时表面电荷的绝对值较小,容易聚集成葡萄串样聚集体,离子强度实验表明该聚集过程的支配作用力可能是疏水作用力。EI/DNA复合物在N/P为12时的细胞转染效果与阳性对照组相当,表明聚集的PEI/DNA复合物也具有一定的细胞转染能力。     

Fabrication of a Novel Core-Shell Gene Delivery System Based on a Brush-Like Polycation of α, β–Poly (L-Aspartate-Graft-PEI)

Purpose  A novel core-shell gene delivery system was fabricated in order to improve its gene transfection efficiency, particularly in the presence of serum. Materials and Methods  α, β–poly (L-aspartate-graft-PEI) (PAE) was simply synthesized by ring-opening reaction of poly (L-succinimide) with low molecular weight (LMW) linear polyethylenimine (PEI, Mn = 423). PAE/DNA nanoparticles were characterized. Condensation and protection ability of plasmid by PAE were confirmed by agarose gel electrophoresis assay. Cytotoxicity of the polymer and polymer/DNA nanoparticles were measured by MTS assay. Gene transfection efficiencies were evaluated both in vitro and in vivo. Results  Core-shell nanoparticles assembled between DNA and PAE showed positive zeta potential, narrow size distribution, and spherical compact shapes with size below 250 nm when N/P ratio is above 10. Cytotoxicity of PAE was rather lower than that of PEI 25K, while the most efficient gene transfection and serum resistant ability of PAE/DNA complexes were higher than that of PEI 25K. Bafilomycin A1 treatment suggested “proton sponge” mechanism of PAE-mediated gene transfection. PAE/pEGFP-N2 nanoparticles also showed good gene expression in vivo and were dominantly distributed in kidney, liver, spleen and lung after intravenous administration. Conclusions  The results demonstrated the potential use of PAE as an effective gene carrier. J.-H. Yu and J.-S. Quan have contributed equally to this work.     

不同相对分子质量聚乙烯亚胺体外介导基因传递的研究

目的研究4种不同相对分子质量聚乙烯亚胺（PEI）作为非病毒基因载体体外介导基因传递的能力。方法采用四甲基噻唑蓝法（MTT法）测定了PEI对Hela细胞的毒性,利用琼脂糖凝胶电泳阻滞试验考察PEI与DNA的结合能力,测定PEI—DNA复合物的粒径和Zeta电位,以及考察转染率。结果PEI的细胞毒性与相对分子质量呈正相关,高相对分子质量PEI的细胞毒性远大于低相对分子质量PEI;高相对分子质量PEI在较低的N／P比时就能对DNA起到完全阻滞作用;低相对分子质量PEI与DNA形成的复合物粒径明显大于高相对分子质量的PEI;Zeta电位随着PEI相对分子质量的增大而增大,复合物的粒径和Zeta电位都与组成中的N／P比有关;相对分子质量为2000的PEI（PEI2K）在Hela细胞中的转染率最低,而相对分子质量为25000的PEI（PEI25K）的转染率最高。结论PEI的相对分子质量对其各项性能指标以及介导基因传递的能力都有较大影响。     

Comparative study of DNA encapsulation into PLGA microparticles using modified double emulsion methods and spray drying techniques

Recently, several research groups have shown the potential of microencapsulated DNA as adjuvant for DNA immunization and in tissue engineering approaches. Among techniques generally used for microencapsulation of hydrophilic drug substances into hydrophobic polymers, modified WOW double emulsion method and spray drying of water-in-oil dispersions take a prominent position. The key parameters for optimized microspheres are particle size, encapsulation efficiency, continuous DNA release and stabilization of DNA against enzymatic and mechanical degradation. This study investigates the possibility to encapsulate DNA avoiding shear forces which readily degrade DNA during this microencapsulation. DNA microparticles were prepared with polyethylenimine (PEI) as a complexation agent for DNA. Polycations are capable of stabilizing DNA against enzymatic, as well as mechanical degradation. Further, complexation was hypothesized to facilitate the encapsulation by reducing the size of the macromolecule. This study additionally evaluated the possibility of encapsulating lyophilized DNA and lyophilized DNA/PEI complexes. For this purpose, the spray drying and double emulsion techniques were compared. The size of the microparticles was characterized by laser diffractometry and the particles were visualized by scanning electron microscopy (SEM). DNA encapsulation efficiencies were investigated photometrically after complete hydrolysis of the particles. Finally, the DNA release characteristics from the particles were studied. Particles with a size of <10 microm which represent the threshold for phagocytic uptake could be prepared with these techniques. The encapsulation efficiency ranged from 100-35% for low theoretical DNA loadings. DNA complexation with PEI 25?kDa prior to the encapsulation process reduced the initial burst release of DNA for all techniques used. Spray-dried particles without PEI exhibited high burst releases, whereas double emulsion techniques showed continuous release rates.     

Polyethylenimine Derivatives as Potent Nonviral Vectors for Gene Transfer

The delivery of a functional gene into a tissue can allow the correction of gene defaults or mutations such as those observed in severe hereditary pathologies or in cancer tissues and could lead to gene therapy. To achieve gene transfer, viral vectors are mainly used because of their intrinsic ability to enter the cells and promote expression of the transgene. However, many factors can limit the use of viral vectors, including a heavy laboratory infrastructure, and, in the case of iterative administration, the induction of immune response against viral proteins. Alternative gene transfer technologies based on nonviral vectors have been proposed. Polyethylenimine (PEI) derivatives are polycationic molecules that are able to form stable complexes with plasmidic DNA. PEI/DNA complexes attach to the cell surface, migrate into clumps that enter the cell by endocytosis and are deagregated in an acidic lysosomal compartment and/or enter the nucleus. PEI derivatives can be proposed as linear (22 kDa) or reticulated (25 kDa) molecules that prove efficient for gene transfer in vitro and in vivo. Besides extensive applications of unsubstituted PEI, glycosylated-PEI derivatives were proposed and reported to enhance gene transfer efficiency through decreased size and aggregation of PEI/DNA complexes. Galactosylated-PEI derivatives have been reported to enhance interactions with cell membranes through carbohydrate-binding protein recognition and specifically target PEI/DNA complexes toward biological systems that express galectins. More recently, glucosylated PEI derivatives have been shown to yield higher and longer-lasting transgene expression than unsubstituted-PEI in human head and neck carcinoma tumor cells. In the present paper, a review of in vitro and in vivo properties of PEI-mediated gene transfer experiments is presented. (c) 2002 Prous Science. All rights reserved.