Catalytic Cleavage of Phosphate by Modified Polyethylenimines (Ⅱ)

A series of modified polyethylenimines (PEIs) containing oxime groups and cetyl groups were prepared. The dissociated constants of oxime group and the rate constants of its reaction with p-nitrophenyl diphenyl phosphate (PNPDPP) were determined. These polymers are good catalysts for the cleavage of PNPDPP under aqueous conditions. Rate accelerations approach 10~4-10~5-fold level with turnover behavior. Reaction mechanism is analogous to that of enzyme-catalyzed kinetics.

Influence of Aliphatic Amide Terminals on the Thermoresponsive Properties of Hyperbranched Polyethylenimines

Acetamide （C2）, propionamide （C3）, butyramide （C4）, isobutyramide （i-C4）, isovaleramide （i-C5） and trimethylacetamide （t-C5） groups each were introduced to the terminals of hyperbranched polyethylenimine （HPEI） through the amidation reaction between HPEI and the corresponding anhydride. Moreover, HPEIs terminated with two kinds of amides were also prepared. The first amide was fixed to be i-C4 with 52% degree of amidation （DA）, and the second amide varied from C2, C3, C4, i-C5 to t-C5. All the polymers were characterized by 1H-NMR. Turbidimetry measurements were performed for these polymers in water at different temperatures. With respect to the polymers bearing only one kind of amide group, except C2, all the other amide groups could render thermoresponsive properties to HPEI. The specific ordering of these amide groups to reduce the cloud point temperature （Top） was as follows： i-C5 〉 t-C5 〉 C4 〉 i-C4 〉 C3. Moreover, the more branched i-C4 and t-C5 were better groups than their less branched isomers C4 and i-C5 in the Tcp range of 12-51 ~C to render the sharper phase transition to the thermoresponsive polymers. As for the polymers bearing two kinds of amide groups, the further introduction of C2, C3, C4, i-C5 or t-C5 could effectively endow HPEI bearing 52% of i-C4 with thermoresponsive properties. The specific ordering of these second amide groups to reduce the Top was as follows： i-C5 〉 C4 〉 i-C4 〉 C3 〉 C2. C4, i-C5 and t-C5 were all effective second amide groups to prepare the thermoresponsive polymers with sharper phase transition.

Effect of poly(ethylene glycol) modified polyethylenimine polyelectrolyte complex on pharmaceutical characteristics and uptake on breast cancer cell

Cationic polyethylenimine （PEI） with dextran fluorescein anionic （DFA） or oligodeoxynucleotide （ODN） could form polyelectrolyte complex by self-assembly as a gene delivery vector. This study was designed to investigate the effects on pharmaceutical characteristics and cell uptake PEI after a long-circulation modification with poly（ethylene glycol） （PEG）. DFA or ODN reacted with PEI or PEI-PEG to form polyelectrolyte complexes. Surface characters of these complexes and the retardation of ODN by PEI and PEI-PEG were evaluated. The uptake rates of DFA/PEI and DFA/PEI-PEG complexes by MCF-7 cells were evaluated by flow cytometry. Confocal laser scanning microscopy was utilized to visualize the internalization of these complexes. ODN/PEI complex showed the dependence of their size and ξ potential on the N/P ratio. ODN/PEI-PEG complex were much less affected by N/P ratio and their size was around 30 100 nm. PEI and PEI-PEG retarded ODN even at N/P ratio as low as 4, and complete retardation was found at N/P ratio of 8. The uptake rate by MCF-7 cells was direct correlated to the DFA concentration and incubation time, and the uptake rate could exceed 99% under the selected condition. The results in this study showed that PEI self-assembly polyelectrolyte complex after stealth or long circulation modification may increase the ability as a gene vector to delivery genes into cells.

Gene functional research using polyethylenimine-mediated in vivo gene transfection into mouse spermatogenic cells

Aim： To study polyethylenimine （PEI）-mediated in vivo gene transfection into testis cells and preliminary functional research of spermatogenic cell-specific gene NYD-SP12 using this method. Methods： PEI/DNA complexes were introduced into the seminiferous tubules of mouse testes using intratesticular injection. Transfection efficiency and speciality were analyzed on the third day of transfection with fluorescent microscopy and hematoxylin staining. The long-lasting expression of the GFP-NYD-SP12 fusion protein and its subcelluar localization in spermatogenic cells at different stages were analyzed with fluorescent microscopy and propidium iodide staining. Results： With the mediation of PEI, the GFP-NYD-SP12 fusion gene was efficiently transferred and expressed in the germ cells （especially in primary spermatocytes）. Transfection into Sertoli cells was not observed. The subcellular localization of the GFP-NYD-SP2 fusion protein showed dynamic shifts in spermatogenic cells at different stages during spermatogenesis. Conclusion： PEI can efficiently mediate gene transfer into spermatocytes. Thus, it might be useful for the functional research of spermatogenic-cell specific genes such as the NYD-SP12 gene. In our gtudy, the NYD-SP12 protein was visualized and was involved in the formation of acrosome during spermatogenesis. Our research will continue into the detailed function of NYD-SP12 in spermatocytes. （Asian J Androl 2006 Jan; 8： 53-59）

Transient Expression of Exogenous Gene into Plant Cell Mediated by PEI Nanovector

This study was carried out to investigate the transfection effect of exogenous gene into plant protoplast cell mediated by polyethylenimine （PEI） nanovector, based on PEI gene delivery system in the field of medical science. PEI/DNA complexes were prepared by using PEI polymer to bind the plant expression plasmid, pCMl205-GFPn. The ability of PEI combining and protecting DNA was investigated by agarose gel electrophoresis retardation assay. The surface characteristics of PEI/DNA complexes were observed with transmission electron microscope. The transfection efficiency of Arabidopsis thaliana protoplasts mediated by PEI/DNA complexes at different N/P ratios was analyzed based on observation of transient expression of green fluorescent protein with confocal laser scanning microscope. PEI could bind and condense DNA, and form stable 100-200 nm PEI/DNA complexes when the proportion of PEl and DNA is in the range of 5：1-1：4. Transfection efficiency of PEI/DNA complexes increased with N/P ratios in range of N/P〈5 and reached the highest at N/P=5, and began to decrease beyond N/P〉5 as higher toxicity to cells. The transfection efficiency of PEI/DNA complexes at N/P=5 was higher than PEG. This study confirmed that PEI nanovector could effectively mediate foreign gene entering into A. thaliana protoplast cell to obtain transient expression, which may be developed as a hopeful and novel transgenic method combined with plant protoplast regeneration.

CO2 capture over molecular basket sorbents:Effects of SiO2 supports and PEG additive

The objective of this work is to study the influences of silica supports and PEG additive on the sorption performance of molecular basket sorbent（MBS） for COcapture consisting of polyethylenimine and one of the following supports: SBA-15（2-D structure）, TUD-1（3-D sponge-like structure） and fumed silica HS-5（3-D disordered structure）. Effects of the supports regarding pore structures and pore properties, the PEI loading amount as well as the sorption temperature were examined. Furthermore, polyethylene glycol（PEG） was introduced as an additive into the sorbents and its effect was investigated at different PEI loadings and sorption temperatures. The results suggest that the pore properties of MBS（after PEI loading） play a more important role in the COsorption capacity, rather than those of the supports alone.MBS with 3D pore structure exhibits higher COsorption capacity and amine efficiency than those with 2D-structured support. Among the sorbents studied, fumed silica（HS-5） based MBS showed the highest COsorption capacity in the temperature range of 30-95 °C, probably due to its unique interstitial pores formed by the aggregation of polymer-loaded SiOparticles. It was found that the temperature dependence is directly related to the PEI surface coverage layers. The more PEI surface coverage layers, the higher diffusion barrier for COand the stronger temperature dependence of COcapacity. 3D MBS exceeds 2D MBS at the same PEI coverage layers due to lower diffusion barrier. Adding PEG can significantly enhance the COsorption capacity and improve amine efficiency of all MBS, most likely by alleviating the diffusion barrier within PEI bulk layers through the inter-molecular interaction between PEI and PEG.

Efficient Gene Delivery to Myocardium with Ultrasound Targeted Microbubble Destruction and Polyethylenimine

The aim of present study was to evaluate the feasibility and efficiency of enhanced green fluorescent protein （EGFP） gene delivery to myocardium in vivo by ultrasound targeted microbubble destruction （UTMD） and polyethylenimine （PEI）. SonoVue/DNA and PEI/DNA/SonoVue complexes were prepared. Gel electrophoresis analysis was performed to determine the structural integrity of plasmid DNA or PEI/DNA after UTMD. Solutions of plasmid DNA, SonoVue/DNA, PEI/DNA complexes or PEI/DNA/SonoVue complexes were respectively transduced into BALB/c mice hearts by means of transthoracic ultrasound irradiation. Mice undergoing PBS injection, plasmid injection or PEI/DNA complexes injection without ultrasound irradiation served as controls. Gene expression in myocardium was detected 4 days after treatment. Cryosections and histological examinations were conducted. Electrophoresis gel assay showed no damage to DNA or PEI/DNA complexes after UTMD. When the heart was not exposed to ultrasound, the expression of EGFP was observed in the subendocardial myocardium obviously. The strongest expression was detected in the anterior wall of the left ventricle when the heart was exposed to ultrasound alone. Injection of PEI/DNA complexes and UTMD resulted in the highest transfection efficiency and the distributional difference of EGFP was not obvious. No tissue damage was seen histologically. In conclusion, a combination of UTMD and PEI was highly effective in transfecting mice hearts without causing any apparently adverse effect. It provides an alternative to current clinical gene therapy and opens a new concept of non-viral gene delivery for the treatment of cardiac disease.

Expression Pattern of Testis-specific Expressed Gene 2 in Cryptorchidism Model and Its Role in Apoptosis of Spermatogenic Cells

In our previous study, we identified a novel testis-specific expressed gene 2 （TSEG-2） from mouse testis. To further investigate its functions, 35 male Balb/c mice （8 weeks old） were divided into cryptorchidism group （n=20）, sham group （n=10）, and control group （n=5）. In cryptorchidism group, the right testes were anchored to the inner lateral abdominal wall. In situ hybridization （ISH） was applied to measure the localization of TSEG-2 in mouse testis. Real-time quantitative PCR was performed to detect the expression of TSEG-2 gene. Meanwhile, under the mediation of polyethylenimine （PEI）, the recombinant vector pEGFP-TSEG-2 （n=5） or empty vector （mock, n=5） was transfected into the testis of male mice. The transfection efficiencies were measured under a fluorescence microscope. The apoptosis of spermatogenic cells was detected by terminal deoxynuleotidyl-mediated nick end labeling （TUNEL）. The results showed that TSEG-2 was expressed in convoluted seminiferous tubules, more precisely, in spermatogonia and spermatocytes. As compared with sham and control groups, the TSEG-2 transcription was significantly enhanced （P〈0.05） and was correlated with apoptosis of spermatogenic cells in cryptorchid testes （P〈0.05）. PEI was efficient in mediating transfeetion of TSEG-2 into seminiferous tubules of testis. One week post-transfection, intratesticular injection of TSEG-2 resulted in increased apoptosis of spermatogenic cells in vivo （P〈0.05）. These results indicate that TSEG-2 may participate in the apoptosis of spermatogenic cells and the pathogenesis of cryptorchidism.

CYTOTOXICITY AND GENOTOXICITY OF POLYETHYLENIMINE AND NICKEL CHLORIDE IN RED SEA BREAM (Pagrosomus major) FIN CELL LINE RSBF

A continuous marine fish cell line RSBF (i.e. Red Sea Bream Fin) was utilized to screen the cytotoxicity and genotoxicity of polyethylenimine (PEI) and nickel chloride (NiCl 2) in this study on the deleterious effects of aquatic genotoxins on fish. At the 0.01 to 1 μg/ml concentration tested, PEI had acute toxicity to the treated RSBF cells (IC 50 =1.12, 0.92, 0.88 and 0.64 μg/ml PEI for time 0 h, 24 h, 48 h and 72 h after treatment, respectively) and markedly inhibited their proliferation in a dose dependent manner. At the 0.001 to 5 μmol/L concentration tested, NiCl 2 posed no acute toxicity but significantly stimulated their growth (107%-214% of control). Random amplified polymorphic DNA (RAPD) technique was used to detect the genotoxic effects of PEI and NiCl 2 by comparing the RAPD banding patterns of the control and treated cells. RAPD analysis indicated that at the concentrations tested, PEI was more genotoxic than NiCl 2 to RSBF cells; that there was a slight dose dependent response in the genotoxic effect of PEI but not NiCl 2; and that RAPD technique might provide a sensitive, non specific genotoxic endpoint. And the potent cytotoxicity and genotoxicity of PEI on fish cells showed that we should be cautious in utilizing it as gene vector in fish gene transfer and human gene therapy.

Positively charged nanofiltration membrane fabricated by poly(acid–base) complexing effect induced phase inversion method for heavy metal removal

Poly(arylene ether ketone)s with carboxylic groups(PAEK-COOH)is a good membrane fabrication material,a kind of polyacids,while polyethylenimine(PEI)is a weak organic base,a kind of polybases.Those polyacids and polybases would form ionic complexation at the interface of two liquid phases.In this paper,PAEK-COOH/N-methyl pyrrolidone(NMP)/1,4-dioxane(DO)mixture,employed as polymer casting solution and aqueous solution of PEI,used as coagulation bath,respectively.Then ion complexation induced phase inversion process is applied to prepare positively charged nanofiltration membrane with thinner but denser separation skin layer.The complexing reaction at the interface of two liquid phases has great influence on the kinetic aspects of phase inversion process,which in accordance would affect the morphology and performance of the membrane.The obtained membrane,fabricated via the ion complexation induced phase inversion method,is positively charged,has high water permeability,and possesses high rejection towards divalent cations,such as Mg^(2+),Ca^(2+),Pb^(2+)etc.,which could be used for removal of heavy metals from polluted water.At the optimal condition,the pure water flux of the PAEK-COOH-PEI nanofiltration membrane is 24.3 L·m^(-2)·h^(-1),with MgCl_2rejection of 92.2%.

Nischarin-siRNA delivered by polyethyleniminealginate nanoparticles accelerates motor function recovery after spinal cord injury

A previous study by our group found that inhibition of nischarin promotes neurite outgrowth and neuronal regeneration in Neuro-2 a cells and primary cortical neurons.In recent years,more and more studies have shown that nanomaterials have good prospects in treatment of spinal cord injury.We proposed that small interfering RNA targeting nischarin（Nis-si RNA） delivered by polyethyleneimine-alginate（PEIALG） nanoparticles promoted motor function recovery in rats with spinal cord injury.Direct microinjection of 5 μL PEI-ALG/Nis-si RNA into the spinal cord lesion area of spinal cord injury rats was performed.From day 7 after surgery,Basso,Beattie and Bresnahan score was significantly higher in rats from the PEI-ALG/Nis-si RNA group compared with the spinal cord injury group and PEI-ALG/Control-si RNA group.On day 21 after injection,hematoxylin-eosin staining showed that the necrotic area was reduced in the PEI-ALG/Nis-si RNA group.Immunohistochemistry and western blot assay results confirmed successful inhibition of nischarin expression and increased protein expression of growth-associated protein-43 in the PEI-ALG/Nis-si RNA group.These findings suggest that a complex of PEI-ALG nanoparticles and Nis-si RNA effectively suppresses nischarin expression,induces expression of growth-associated protein-43,and accelerates motor function recovery after spinal cord injury.

Investigation of the Elasticity of Polymer Nanoparticle by Vibrating Scanning Polarization Force Microscopy

The elasticity of an individual polymer nanoparticle may be greatly different from that of the bulk one. Understanding the properties of individual particles such as elasticity and deformation under external forces is of great importance in controlling the final structures and functions of bulk materials. We study the compression properties of single polyethylenimine （PEI） particles using vibrating scanning polarization force microscopy. By controllably imaging PEI particles at different vibration amplitude set-point values, it is demonstrated that we can compress the single PEI nanoparticle with an atomic force microscopy tip in different loads. Based on the force-height and force-strain curves obtained, Young＇s moduli of PEI （5-160 MPa） in three force regions are estimated according to the Hertz model The results indicate that PEI has excellent elasticity, which may contribute to its high efficiency as vectors in gene transfection.

Receptor-mediated gene delivery using polyethylenimine (PEI) coupled with polypeptides targeting FGF receptors on cells surface

Objective: To construct a novel kind of nonviral gene delivery vector based on polyethylenimine (PEI) conjugated with polypeptides derived from ligand FGF with high transfection efficiency and according to tumor targeting ability. Methods: The synthetic polypeptides CR16 for binding FGF receptors was conjugated to PEI and the characters of the polypeptides in-cluding DNA condensing and particle size were determined. Enhanced efficiency and the targeting specificity of the synthesized vector were investigated in vitro and in vivo. Results: The polypeptides were successfully coupled to PEI. The new vectors PEI-CR16 could efficiently condense pDNA into particles with around 200 nm diameter. The PEI-CR16/pDNA polyplexes showed significantly greater transgene activity than PEI/pDNA in FGF receptors positive tumor cells in vitro and in vivo gene transfer, while no difference was observed in FGF receptors negative tumor cells. The enhanced transfection efficiency of PEI-CR16 could be blocked by excess free polypeptides. Conclusion: The synthesized vector could improve the efficiency of gene transfer and targeting specificity in FGF receptors positive cells. The vector had good prospect for use in cancer gene therapy.

Synthesis and Characterization of Poly (Methyl Methacrylate)/Polyethylenimine Grafting Core-Shell Nanoparticles for CO2 Adsorption Using Soap-Free Emulsion Copolymerization

Unlike previous emulsion polymerization, we used grafting reactions in soap-free emulsion systems. In this study, we synthesized grafted PMMA/PEI core-shell nanoparticles by varying the MMA/PEI content and molecular weight of PEI (Mn = 600, 8000, and 10,000). The size and morphology of the core-shell nanoparticles were characterized by a particle size analyzer and scanning electron microscopy. The nanoparticles were 178 - 408 nm in diameter and swelled in water or methanol by 30 - 75 nm. The size of the nanoparticles increased with MMA contents, whereas the size distribution progressively became homogeneous with increasing molecular weight of PEI. Lastly, we measured CO2 adsorption capacity of the grafted PMMA/PEI core-shell nanoparticles, and we found the capacity to be limited at a level of 0.69 mg, which occurred for nanoparticles prepared from emulsions at a pH value of 11.

Surface treatment on polyethylenimine interlayer to improve inverted OLED performance

Polyethylenimine(PEI) interlayer rinsing with different solvents for inverted organic light emitting diodes(OLEDs)is systematically studied in this paper. In comparison with the pristine one, the maximum current efficiency(CE) and power efficiency(PE) are enhanced by 21% and 22% for the device rinsing by ethylene glycol monomethyl ether(EEA).Little effect is found on the work function of the PEI interlayer rinsed by deionized water(DI), ethanol(EtOH), and EEA.On the other hand, the surface morphologies of PEI through different solvent treatments are quite different. Our results indicates that the surface morphology is the key to improving the device performance for IOLED as the work function of PEI keeps stable.

Preparation and characterization of poly(propylene glycol)-conjugated cationic polymers for efficient gene delivery

Nucleic acid drugs are desirable therapeutics for the treatment of fatal diseases like cancers.For clinical translation of nucleic acid drugs,carrier systems that protect nucleic acid from degradation and help cellular uptake are needed.Accordingly cationic polymers are used as a carrier due to their strong electrostatic interaction with nucleic acids,which produce nanosized particles[1].

Folic Acid-Polyethyleneimine-Ethosome as a Potential Tumor Targeting Carrier: Preparation, Characterization and in vitro Evaluation

A novel composite carrier of folic acid(FA)-polyethyleneimine(PEI)-ethosome(Eth)(FA-PEI-Eth)was developed for the treatment of cancers through loading and targeting delivery of multidrug(including gene and other drugs)into cancer cells.Physical and chemical property tests were done to prove the grafting of the composite.Gel retardation test was done to determine the optimal ratio of DNA@PEI complex,and cytocompatibility tests and tumor cell uptake tests were done to evaluate the efficiency of the composite.The results demonstrated that the FA-PEI-Eth could effectively deliver a gene and other drugs into tumor cells simultaneously,and suggested that this composite would be a promising carrier in tumor-targeted therapy applications.

Effect of Polyethylenimine Content on Liposome/Polyethylenimine Complexes-Mediated Gene Delivery

Cationic liposome(Lipo) and polyethylenimine(PEI) are widely applied for nonviral gene transfection.In this study,in order to combine the favorable properties of Lipo and PEI systems for gene delivery,Lipo/PEI complexes with different contents of PEI(5%,10%,20% and 40% relative to phosphatidyl choline in reaction system) were prepared.The physicochemical properties of Lipo/PEI complexes,as well as the influences of PEI content on the storage stability,cytotoxicity and transfection efficiency were investigated.The transmission electron microscopy(TEM) images showed that Lipo/PEI complexes had smaller size compared to pure Lipo.The zeta potential values decreased with the increasing content of PEI.After storaged for 3 months at 4 ℃,obvious aggregation was observed when the addition of PEI content was up to 20%.In vitro cytotoxicity assay showed that Lipo/PEI complexes had decreased cytotoxicity over pure PEI,while the cytotoxicity was enhanced as the PEI content increased.Importantly,the luciferase activity assay and confocal microscope observation revealed that Lipo/PEI complexes prepared with the lowest amount of PEI(Lipo/PEI-5%)possessed the highest transfection efficiency.Thus,these results suggest that feeding the appropriate content of PEI in Lipo/PEI complexes allows them to be excellent vehicle for gene delivery.

Antibacterial Activity of Polyethylenimine/Carrageenan Multilayer against Pathogenic Bacteria

The multilayer of polyethylenimine (PEI) and carrageenan (k, i, l) formed by layer-by-layer assembly was investigated for its antibacterial activity against Enterobacter cloaceae, Staphylococcus aureus and Enterococcus faecalis 29505 for potential use as coating on biomaterial surface. All the multilayers exhibited growth inhibition. PEI/Iota carrageenan multilayer was effective in inhibiting the growth of the E. cloaceae, S. aureus and E. faecalis while PEI/Lambda carrageenan was effective in inhibiting the growth of E. cloaceae. Results of the paper strip test for combined action of carrageenan and PEI showed synergism with regards to bacterial growth inhibition. The multilayers had also contact-killing effect with the test organisms. The multilayer was also characterized by atomic force microscopy (AFM), X-ray photoelectron spectroscopy (XPS) and biomolecular interaction analysis.

Utilization of Polyethylenimine(PEI)Modified Carbon Black Adsorbent Derived from Tire Waste for the Removal of Aspirin

A new adsorbent was synthesized using polyethylenimine(PEI)on the carbon black to remove aspirin from an aqueous solution.In this study,adsorption performance of modified carbon black by polyethylenimine(PEI)on aspirin was investigated.Batch adsorption studies were performed to evaluate the effects of contact time,pH solution,temperature,and initial concentration on the adsorption of aspirin.For this study,the carbon black obtained from the pyrolysis of tire waste was used as a precursor for low-cost adsorbents.The carbon black was treated by 1 M of hydrochloric acid solution to remove ash and sulphur content.Then,the treated carbon black was modified by impregnation with PEI in one to one weight ratio within 24 hours at 65°C and then cross linked with 1%(w/v)glutaraldehyde solution for one hour.The adsorption rate of aspirin by modified carbon black was rapid from 20 minutes to 60 minutes and reached equilibrium.Hence,the optimum contact time for this study is 60 minutes with 59.96%of aspirin removal and 29.98 mg/g adsorption capacity.The best performance for pH solution,temperature,and initial concentration was observed at pH 3(26.1 mg/g),30°C(26.9 mg/g)and 20 ppm(40.96 mg/g)respectively.