The objective of this study was to prepare cationized gelatins grafted with poly(ethylene glycol) (PEG) (PEG-cationized gelatin) and evaluate the in vivo efficiency as a non-viral gene carrier. Cationized gelatin was prepared by chemical introduction of ethylenediamine to the carboxyl groups of gelatin. PEG with one terminal of active ester group was coupled to the amino groups of cationized gelatin to prepare PEG-cationized gelatins. Electrophoretic experiments revealed that the PEG-cationized gelatin with low PEGylation degrees was complexed with a plasmid DNA of luciferase, in remarked contrast to that with high PEGylation degrees. When the plasmid DNA complexed with the cationized gelatin or PEG-cationized gelatin was mixed with deoxyribonuclease I (DNase I) in solution to evaluate the resistance to enzymatic degradation, stronger protection effect of the PEG-cationized gelatin was observed than that of the cationized gelatin. The complex of plasmid DNA and PEG-cationized gelatin had an apparent molecular size of about 300 nm and almost zero surface charge. These findings indicate that the PEG-cationized gelatin–plasmid DNA complex has a nano-order structure where the plasmid DNA is covered with PEG molecules. When the PEG-cationized gelatin–plasmid DNA complex was intramuscularly injected, the level of gene expression was significantly increased compared with the injection of plasmid DNA solution. It is concluded that the PEG-cationized gelatin was a promising non-viral gene carrier to enhance gene expression in vivo. 相似文献
The objective of this study was to prepare cationized gelatins grafted with poly(ethylene glycol) (PEG) (PEG-cationized gelatin) and evaluate the in vivo efficiency as a non-viral gene carrier. Cationized gelatin was prepared by chemical introduction of ethylenediamine to the carboxyl groups of gelatin. PEG with one terminal of active ester group was coupled to the amino groups of cationized gelatin to prepare PEG-cationized gelatins. Electrophoretic experiments revealed that the PEG-cationized gelatin with low PEGylation degrees was complexed with a plasmid DNA of luciferase, in remarked contrast to that with high PEGylation degrees. When the plasmid DNA complexed with the cationized gelatin or PEG-cationized gelatin was mixed with deoxyribonuclease I (DNase I) in solution to evaluate the resistance to enzymatic degradation, stronger protection effect of the PEG-cationized gelatin was observed than that of the cationized gelatin. The complex of plasmid DNA and PEG-cationized gelatin had an apparent molecular size of about 300 nm and almost zero surface charge. These findings indicate that the PEG-cationized gelatin-plasmid DNA complex has a nano-order structure where the plasmid DNA is covered with PEG molecules. When the PEG-cationized gelatin-plasmid DNA complex was intramuscularly injected, the level of gene expression was significantly increased compared with the injection of plasmid DNA solution. It is concluded that the PEG-cationized gelatin was a promising non-viral gene carrier to enhance gene expression in vivo. 相似文献
Polyelectrolyte complexes have been widely studied as gene carriers in recent years. In this study, poly (ethylene imine) was grafted onto chitosan (PEI-g-CHI) as a nonviral gene carrier in order to improve the water solubility as well as the inherent transfection efficiency of chitosan. We present a novel method to conjugate the amine or hydroxyl groups of chitosan (CHI) and the amine groups of PEI through opening the epoxide rings of ethylene glycol diglycidyl ether (EX-810), which also brings the merits as mentioned in PEGylation chemistry. The degree of substitution of PEI onto CHI was characterized by NMR. The preliminarily cellular mechanisms, from the cellular entry to the endosomal release, were investigated by the correlations among the physicochemical properties of the DNA-polymer complexes, the buffering capacity of the modified polymer, the cytotoxicity, and the efficiency of the transgene expression. The cytotoxicity assayed by MTT shows that cell viability of PEI-g-CHI is higher than CHI especially noticeable at high concentrations using human kidney 293T cells. The efficiency of transgene expression and the amount of intracellular plasmid were monitored using green fluorescent protein (GFP) and visualized by fluorescence microscopy. The transfection efficiency of PEI-g-CHI/DNA polyplex is significantly better than CHI/DNA polyplex when using the weight ratios higher than 2.5. 相似文献
Poly(3-hydroxyalkanoate)-g-poly(ethylene glycol) crosslinked graft copolymers are described. Poly(3-hydroxyalkanoate)s containing double bonds in the side chain (PHA-DB) were obtained by co-feeding Pseudomonas oleovorans with a mixture of nonanoic acid and anchovy (hamci) oily acid (in weight ratios of 50/50 and 70/30). PHA-DB was thermally grafted with a polyazoester synthesized by the reaction of poly(ethylene glycol) with MW of 400 (PEG-400) and 4,4′-azobis(4-cyanopentanoyl chloride). Sol-gel analysis and spectrometric and thermal characterization of the networks are reported. 相似文献
An ideal gene carrier is required both in safety and efficiency for transfection. Polyethylenimine (PEI), a well-studied cationic polymer, has been proved with high transfection efficiency, but is reported as toxicity in many cell lines. In this study, PEI was coupled with polyethylene glycol (PEG) to reduce its cytotoxicity. PEG-PEI copolymers were synthesized with isoporon diisocyanate (IPDI) in two steps. A set of PEG-PEI with different PEG molecular weights (MWs) and amounts of PEG were synthesized. The molecular structure of the resulting copolymers was evaluated by nuclear magnetic resonance spectroscopy ((1)H NMR), infrared spectroscopy (IR), and gel permeation chromatography (GPC), all of which had successfully verified formation of the copolymers. The particle size and zeta potential of polymer/DNA complexes were measured, and their cytotoxicity and transfection efficiency in Hela cells were evaluated. We found that the copolymer block structure significantly influenced not only the physicochemical properties of complexes, but also their cytotoxicity and transfection efficiency. PEG (5 kDa) significantly reduced the diameter of the spherical complexes. The zeta potential of complexes was reduced with increasing amount of PEG grafting. Cytotoxicity was dependent not on PEG MW but on the amount of PEG grafting. Copolymer PEG-PEI (2-25-1) with 1.89 PEG (2 kDa) was proved to be more efficient for in vitro gene transfer. In conclusion, PEG MW and the degree of PEGylation were found to significantly influence the biological activity of PEG-PEI/DNA complexes. These results provide new sights into the studies using block copolymer as gene delivery systems. 相似文献
In order to obtain a stable human immunoglobulin G (IgG) preparation for clinical use, the chemical coupling of different molecular weights of poly(ethylene glycol)s (PEGs) to IgG molecules was achieved. The abilities of PEG-coupled IgGs (PEG-IgG hybrids) to aggregate were examined when they were subjected to such physicochemical treatments as interfacial exposure, heating, lyophilization, and acid treatment. It was found that the higher the molecular weight of PEG coupled, the more stable was the PEG-IgG hybrid obtained concerning interfacial exposure and heating. The hybrid was stable against lyophilization and acid treatment and its stability was independent of the PEG molecular weight. The decrease in antigen binding ability was suppressed as much as possible by the use of a small amount of PEG of higher molecular weight. The PEG-IgG hybrids were further assessed as a stabilizer for IgG. A limited degree of PEG coupling was required for the hybrids to achieve the most efficient stabilization of IgG: the optimal PEG contents of the hybrid were > 20 wt% (interfacial exposure), about 5'wt,?o (heating), 20 wt% (lyophilization), and 10 wt% (acid treatment) for PEG 5600. It was also confirmed that the PEG-IgG hybrid was superior to PEG and human serum albumin as a stabilizer. 相似文献
In order to obtain a stable human immunoglobulin G (IgG) preparation for clinical use, the chemical coupling of different molecular weights of poly(ethylene glycol)s (PEGs) to IgG molecules was achieved. The abilities of PEG-coupled IgGs (PEG-IgG hybrids) to aggregate were examined when they were subjected to such physicochemical treatments as interfacial exposure, heating, lyophilization, and acid treatment. It was found that the higher the molecular weight of PEG coupled, the more stable was the PEG-IgG hybrid obtained concerning interfacial exposure and heating. The hybrid was stable against lyophilization and acid treatment and its stability was independent of the PEG molecular weight. The decrease in antigen binding ability was suppressed as much as possible by the use of a small amount of PEG of higher molecular weight. The PEG-IgG hybrids were further assessed as a stabilizer for IgG. A limited degree of PEG coupling was required for the hybrids to achieve the most efficient stabilization of IgG; the optimal PEG contents of the hybrid were greater than 20 wt% (interfacial exposure), about 5 wt% (heating), 20 wt% (lyophilization), and 10 wt% (acid treatment) for PEG 5600. It was also confirmed that the PEG-IgG hybrid was superior to PEG and human serum albumin as a stabilizer. 相似文献
This study was designed to determine the effect of changes in poly(ethylene glycol) (PEG) molecular weight on swelling and mechanical properties of hydrogels made from a novel polymer, oligo(poly(ethylene glycol) fumarate) (OPF), recently developed in our laboratory. Properties of hydrogels made from OPF with initial PEG molecular weights of 860, 3900, and 9300 were examined. The PEG 3900 formulation had a tensile modulus of 23.1 +/- 12.4 kPa and percent elongation at fracture of 53.2 +/- 13.7%; the PEG 9300 formulation had similar tensile properties (modulus: 16.5 +/- 4.6 kPa, elongation: 76.0 +/- 26.4%). However, the PEG 860 gels had a significantly higher modulus (89.5 +/- 50.7 kPa) and a significantly smaller percent elongation at fracture (30.1 +/- 6.4%), when compared with other formulations. Additionally, there were significant differences in percent swelling between each of the formulations. Molecular weight between crosslinks (M(c)) and mesh size were calculated for each OPF formulation. M(c) increased from 2010 +/- 116 g/mol with PEG 860 to 6250 +/- 280 g/mol with PEG 9300. Mesh size calculations showed a similar trend (76 +/- 2 A for PEG 860 to 160 +/- 6 A for PEG 9300). It was also found that these hydrogels could be laminated if a second layer was added before the first had completely crosslinked. Mechanical testing of these laminated gels revealed that the presence of an interfacial area did not significantly alter their tensile properties. These results suggest that the material properties of OPF-based hydrogels can be altered by changing the molecular weight of PEG used in synthesis and that multilayered OPF hydrogel constructs can be produced, with each layer having distinct mechanical properties. 相似文献
There are two main hindrances for the application of chitosan (CS) as a gene-delivery vector: poor water solubility and low transfection efficiency. To address these problems, we modified chitosan with poly(ethylene glycol) (PEG) and poly(ethylene imine) (PEI). As previously described, PEG was grafted onto CS by a reaction between the activated PEG and CS amine. This increased the solubility of CS in neutral or basic solution. Then, monomers of PEI (i.e., aziridine) were polymerized on the CS chain of the PEG(40k)-CS(50k) co-polymer obtained in the previous step. The resulting PEG-CS-PEI (PCP) co-polymer was characterized by 1H-NMR, 13C-NMR and gel-permeation chromatography (GPC). It was found in the preliminary experiments that, amongst the series of PEG-CS-PEI co-polymers with various PEI molecular weights, PEG(40k)-CS(50k)-PEI(20k) was the most efficient one; therefore, it was chosen for the study. The PCP co-polymer showed lower cytotoxicity compared to PEI (25k) by MTT assay. Particle size and zeta potential of PCP/DNA complexes were measured by dynamic light scattering (DLS) and were shown to be predominantly affected by N/P ratios. PCP/DNA complexes at N/P ratio 20 were observed under a transmission electron microscope (TEM) as spherical particles with a mean diameter of about 50 nm. Plasmid DNA could be efficiently protected by PCP co-polymer from DNase I. The in vitro gene-transfection efficiency of PCP/pEGFP was higher than that of PEI(25k)/pEGFP and was markedly facilitated by serum. 相似文献
A pH responsive pseudopeptide, poly(L-lysine iso-phthalamide), has been modified with a hydrophilic poly(ethylene glycol) analogue, Jeffamine M-1000 and the effect of grafting ratio on the pH responsive behaviour of the grafted polymers in aqueous solution investigated using fluorescence and 1H NMR spectroscopy. It was demonstrated that at below 35.1 wt% grafting, the modified polymers retained the pH-driven conformational transition of the parent polymer from an expanded structure at high degrees of ionisation to a compact hydrophobically stabilised structure at low degrees of ionisation. The onset of pH response and the pH range over which the conformational transition occurred varied significantly with degree of grafting. At Jeffamine M-1000 ratios in excess of 48.0 wt%, the graft polymer existed in a micellular form over the whole pH studied. Potential applications in drug delivery of both the linear and micellular forms are discussed. 相似文献
Upper critical solution temperature (UCST)‐type thermoresponsive behavior of poly(ethylene glycol)–poly(acrylic acid) (PEG–PAA) and poly(poly(ethylene glycol) methacrylate)–poly(acrylic acid) (PPEGMA–PAA) interpolymer complexes has been observed in isopropanol. For these investigations, PPEGMA and PAA with various average molecular weights have been synthesized by atom transfer radical polymerization. It has been found that both the PEG and PPEGMA have lower cloud point temperatures (T cp) than its mixed polymer solutions with PAA, whereas PAA does not show such behavior in the investigated temperature range. These findings indicate the reversible formation of interpolymer complexes with variable structure and composition in the solutions of the polymer mixtures in isopropanol. Increasing the ethylene glycol/acrylic acid molar ratio or the molecular weight of either the PAA or the H‐acceptor PEG component of the interpolymer complexes increases the UCST‐type cloud point temperatures of these interpolymer systems. The polymer–polymer interactions by hydrogen bonds between PAA and PEG or PPEGMA and the correlations between T cp and structural parameters of the components revealed in the course of these investigations may be utilized for exploring well‐defined UCST‐type material systems for various applications.
Simple methods are described for the substitution of poly(ethylene glycol) and monomethoxy-poly(ethylene glycol) substitution. Affinity ligands, coenzymes, or enzymes can be covalently attached to the substitution product or they can be used as liquid ionexchangers. 相似文献
We report here that the incorporation of several disulfide bonds along poly(ethylene glycol) (PEG) gives temperature sensitivity, as well as biodegradability to PEG. To synthesize a PEG with temperature sensitivity in a physiologically important range (20–40°C), PEGs with molecular masses of 400 and 600 Da were randomly coupled by disulfide bonds. As the mol ratio of PEG (400 Da) disulfide to PEG (600 Da) disulfide increased from 40:60 to 60:40, the cloud point of the polymer aqueous solution decreased from 35°C to 27°C. The disulfide bonds between PEGs were degraded in the presence of a thiol-containing biomolecule of glutathione in a thiol-concentration-dependent manner. 相似文献
Poor water solubility and low transfection efficiency of chitosan are major drawbacks for its use as a gene delivery carrier. PEGylation can increase its solubility, and folate conjugation may improve gene transfection efficiency due to promoted uptake of folate receptor-bearing tumor cells. The aim of this study was to synthesize and characterize folate-poly(ethylene glycol)-grafted chitosan (FA-PEG-Chi) for targeted plasmid DNA delivery to tumor cells. Gel electrophoresis study showed strong DNA binding ability of modified chitosan. The pH(50) values, defined as the pH when the transmittance of a polymer solution at 600 nm has reached 50% of the original value, suggested that the water solubility of PEGylated chitosan had improved significantly. Regression analysis of pH(50) value as a function of substitution degree of PEG yielded an almost linear correlation for PEG-Chi and FA-PEG-Chi. The solubility of PEGylated chitosan decreased slightly by further conjugation of folic acid due to the relatively more hydrophobic nature of folic acid when compared to PEG. In addition, the chitosan-based DNA complexes did not induce remarkable cytotoxicity against HEK 293 cells. FA-PEG-Chi can be a promising gene carrier due to its solubility in physiological pH, efficiency in condensing DNA, low cytotoxicity and targeting ability. 相似文献
Poly(L-lactide) (PLLA) films were modified with poly(ethylene imine) (PEI) either by adsorption or covalent binding to prepare the material for immobilization of polyelectrolyte multilayers (PEM). Two different PEI, low- and high-molecular-weight (LMW or HMW, respectively) PEI, were used. The PEI modification efficiency was monitored via surface amino group density, water contact angle and X-ray photoelectron spectroscopy (XPS) measurements. Covalent binding of HMW PEI by a two-step-activation method produced the highest amino group density and the lowest water contact angle. On the other hand, the adsorption method resulted in moderate amounts of immobilized PEI on the surface. Subsequently sulphated hyaluronan and chitosan were used to form PEM on PLLA that was covalently modified with HMW PEI. Regular formation of PEM was achieved, which was demonstrated by change of water contact angles and mass increase measured with quartz crystal microbalance. An osteoblast-like cell line, MG 63, was used to test the effects of modifications on biocompatibility. Contrarily to earlier reports showing that particularly HMW PEI had certain cytotoxicity, it was found that all modifications including PEM resulted in a better biocompatibility than plain PLLA indicated by a more spread phenotype of cells, their increased growth and metabolic activity. 相似文献
Novel types of methoxy poly(ethylene glycol) (PEG) linkers (U-PEG linkers) have been synthesized. These PEG linkers are linear polymers that attach to bioactive agents via a functional group, derived from a 2° alcohol, located in the center of the polymer chain versus the traditional terminal attachment site. These new types of linkers can be prepared with different functional groups (e.g. active ester, succinimidyl carbonate, and carbazate) for selected point of attachment, including ethylene oxide oligomers to provide “stems” when steric factors need to be addressed. Conversion of p-nitrophenyl carbonates to the more desirable succinimidyl carbonates has also been accomplished by a novel nucleophilic displacement procedure. Modification of proteins with these reagents is easily accomplished and is illustrated by the conjugation of a U-PEG linker with L -asparaginase. 相似文献
A major challenge in gene therapy is the development of effective gene delivery vectors with low toxicity. In the present study, linear poly(ethylenimine) (lPEI) with low molecular weight was grafted onto the block copolymer (PPL) of poly(l-lysine) (PLL) and poly(ethylene glycol)(PEG), yielding a ternary copolymer PEG-b-PLL-g-lPEI (PPI) for gene delivery. In such molecular design, PLL, lPEI and PEG blocks were expected to render the vector biodegradability, proton buffering capacity, low cationic toxicity and potentially long circulation in vivo, respectively. Given proper control of molecular composition, the copolymers demonstrated lower cytotoxicity, proton buffering capacity, ability to condense pDNA and mediate effective gene transfection in various cell lines. With folate as an exemplary targeting ligand, the FA-PPI/pDNA complex showed much higher transgene activity than its nontargeting counterpart for both reporter and therapeutic genes in folate receptor(FR)-positive cells. FA-PPI mediated effective transfection of the TNF-related apoptosis-inducing ligand gene (TRAIL) in human hepatoma Bel 7402 cells, leading to cell apoptosis and great suppression of cell viability. Our results indicate that the copolymers might be a promising vector combining low cytotoxicity, biodegradability, and high gene transfection efficiency. 相似文献
The regulation of cell motility on ligand-adsorbed poly(ethylene glycol) (PEG)-based polymeric biomaterials is governed by variables that are not well characterized. In this report, we examined keratinocyte migratory responsiveness to PEG-variant tyrosine-derived polycarbonates adsorbed with equivalent levels of the cell adhesion ligand, fibronectin. The equivalently adsorbed ligand adopted differential distributions, confirmed via atomic force microscopy, and the total number of exposed cell-binding domains (CBD), quantified through immunosorbent fluorometry, varied as a function of PEG concentration. Specifically, the CBD exposure was maximized at 4 mol % PEG and diminished at 8 mol % PEG, suggesting, based on our previous work (Tziampazis et al., Biomaterials 2000;21:511-520), that activation of cell adhesion and motility could be potentially promoted through increased CBD exposure at intermediate levels of PEG. This was confirmed through cell migration studies wherein cell speed values increased from 11 to 22 microm/h as the PEG concentration was increased from 0 to 4 mol %. Unexpectedly, however, high cell motility rates were sustained at 8 mol % PEG despite diminished levels of initial CBD exposure beyond 4 mol % PEG, suggesting that factors other than the initial CBD exposure may additionally have a role in activating cell migration at higher levels of PEG. Through studies of direct ligand mobility, cell-ligand-polymer interactions via atomic force microscopy, and CBD variation and integrin receptor roles in ligand remodeling, we offer evidence that cell motility is enhanced by a new mechanism for the regimen of higher PEG concentration: upon cell attachment and spreading, the ligand exhibits greater "slippage" at the polymer interface, and undergoes cell-engendered remodeling, which further activates cell motility, likely through enhanced exposure of hitherto encrypted sites for cell binding and signaling. 相似文献
[η]/M?n relationships at 25°C. have been found for low molecular weight fractions of poly(vinyl acetate) (PV Ac) in chlorobenzene and poly(methyl methacrylate) (PMMA) in toluene. The PMMA used contains about 75% of syndiotactic form. Due to the difficulties of PMMA fractionation, the constants in the equation [η] = K M? refer to an average degree of polydispersity equal to M?w/M?n = 1.2. For both PVAc and PMMA there is a range of molecular weight where a = 0.5; in these ranges [η] is practically indistinguishable from [η]Θ. 相似文献
