Shouping Ji

Reduction-degradable linear cationic polymers as gene carriers prepared by Cu(I)-catalyzed azide-alkyne cycloaddition.

Linear reduction-degradable cationic polymers with different secondary amine densities (S2 and S3) and their nonreducible counterparts (C2 and C3) were synthesized by Cu(I)-catalyzed azide-alkyne cycloaddition (CuAAC) step-growth polymerization of the dialkyne-oligoamine monomers and the diazide monomers. These polymers were studied with a goal of developing a set of new gene carriers. The buffering capacity and DNA binding ability of these polymers were evaluated by acid-base titration, gel retardation, and ethidium bromide (EB) exclusion assay. The polymers with lower amine density exhibit a weaker DNA-binding ability but a stronger buffering capacity in the range of pH 5.1 and 7.4. Particle size and zeta-potential measurements demonstrate that the polymers with higher amine density condense pDNA to form polyplexes with smaller sizes, while the disulfide bond in the backbone shows a negative effect on the condensing capability of the polymers, resulting in the formation of polyplexes with large size and nearly neutral surface. The reduction-sensitive polyplexes formed by polymer S2 or S3 can be disrupted by dithiothreitol (DTT) to release free DNA, which has been proven by the combination of gel retardation, EB exclusion assay, particles sizing, and zeta potential measurements. Cell viability measurements by MTT assay demonstrate that the reduction-degradable polymers (S2 and S3) have little cytotoxicity while the nonreducible polymers (C2 and C3) show obvious cytotoxicity, in particular, at high N/P ratios. In vitro transfection efficiencies of these polymers were evaluated using EGFP and luciferase plasmids as the reporter genes. Polymers S3 and S2 show much higher efficiencies than the nonreducible polymers C3 and C2 in the absence of 10% serum; unexpectedly, the lowest transfection efficiency has been observed for polymer S3 in the presence of serum.

Biocompatible acid-labile polymersomes from PEO-b-PVA derived amphiphilic block copolymers

A family of amphiphilic block copolymers with pendent ortho ester groups were synthesized by modifying the double hydrophilic block copolymer PEO114-b-PVA240 with 2-ethylidene-4-methyl-1,3-dioxolane (EMD) under mild conditions (30 °C). The degree of modification (DM) of the ortho ester groups can be tuned by simply varying the feed ratio of EMD to the hydroxyl groups in the PVA block. These block copolymers are stable in an anhydrous environment. Laser light scattering (LLS) and transmission electron microscopy (TEM) measurements revealed that in weakly basic aqueous buffer, these amphiphilic block copolymers self-assembled into aggregates with different size and morphology, ranging from solid-like spherical nanoparticles to polymersomes as the DM increased. The acid-triggered dissociation behaviour of the aggregates were studied by LLS, nile red (NR) fluorescence and TEM. The copolymer aggregates dissociated faster in a buffer with the lower pH; the dissociation rate of the aggregates became faster for the copolymers with lower DM. The polymersomes can load both hydrophilic biomacromolecules like lysozyme and hydrophobic anticancer drug doxorubicin (DOX). The drug-loaded polymersomes were stable in neutral phosphate buffer for at least 6 h with a payload leakage of less than 25% in 12 h at 37 °C; however, significant acid-triggered payload release was accomplished even at a mildly acidic pH (6.0). Finally, the DOX-loaded polymersomes exhibited a concentration-dependent toxicity to MCF-7 and HeLa cells while the copolymers themselves are non-toxic.

Thermoresponsive Gene Carriers Based on Polyethylenimine‐graft‐Poly[oligo(ethylene glycol) methacrylate]

A family of thermoresponsive cationic copolymers (TCPs) that contain branched PEI 25 K as the cationic segment and poly(MEO(2)MA-co-OEGMA(475)) as the thermosensitive block (TP) is prepared. The DNA binding capability, physicochemical properties, and biological performance of the TCPs are studied. All of these TCPs can condense DNA to form polyplexes with diameters of 150-300 nm and zeta potentials of 7-32 mV at N/P ratios between 12 and 36. The length of TP block is a key factor for shielding the positive surface charge of the polyplexes and protecting them against protein adsorption. TCPs with a higher TP content have a lower cytotoxicity while the best transfection performance is achieved by the TCPs with longest TP length, reaching a level of the intact PEI 25 K in the presence of serum.