Biodegradable polymers as non-viral carriers for plasmid DNA delivery.

Gene therapy holds a great promise for the treatment of acquired and inherited diseases with a genetic origin that are currently incurable. Non-viral gene delivery systems are gaining recognition as an alternative to viral gene vectors for their potential in avoiding immunogenicity and toxicity problems inherently associated with the use of viral systems. Many cationic polymers have been studied both in vitro and in vivo for gene delivery purposes. However, in recent years there has been a focus on biodegradable carrier systems. The potential advantage of biodegradable carriers as compared to their non-degradable counterparts is their reduced toxicity and the avoidance of accumulation of the polymer in the cells after repeated administration. Also, the degradation of the polymer can be used as a tool to release the plasmid DNA into the cytosol. In this article the recent results obtained with two classes of degradable gene delivery systems, namely those based on water-soluble cationic polymers and on micro- and nanoparticles will be summarized and discussed.

Biodegradable, cationic methacrylamide-based polymers for gene delivery to ovarian cancer cells in mice.

A series of cationic, methacrylamide polymers was tested for use as a biodegradable gene carrier in ovarian cancer. Tumor transfection activity of polyplexes consisting of a reporter gene and different methacrylamide polymers was assessed, after intraperitoneal injection in mice bearing an ovarian cancer xenograft. In this model, polyplexes based on poly(HPMA-DMAE) showed transfection activity similar to polyplexes based on the nondegradable and rather toxic polyethylenimine (PEI22). The tumor transfection activity of the pHPMA-DMAE polyplexes was remarkable considering their poor transfection activity in in vitro assays. Polyplexes based on pHPMA-DMAE were devoid of any cytotoxicity and mediated highest transfection activity at the highest N/P ratio investigated. Tumor cell gene expression after a single administration of these polyplexes rapidly declined within time, at a similar rate to that observed after injection with polyplexes based on PEI22. Incubation of the polyplexes with hyaluronic acid (HA), a polyanion accumulating in the ascitic fluid of ovarian cancer bearing mice, changed the physical characteristics of the pHPMA-DMAE and PEI22 polyplexes. The transfection activity of PEI22-based polyplexes, but not that of pHPMA-DMAE based polyplexes, was strongly impaired by HA. Differences in HA sensitivity might have contributed to the in vivo gene expression activities of pHPMA-DMAE- and PEI22-based polyplexes. pHPMA-DMAE-based polyplexes have potential for use in ovarian cancer therapy due to their considerable transfection activity, their low cytotoxicity, and their HA resistance.

Methacrylamide polymers with hydrolysis-sensitive cationic side groups as degradable gene carriers.

Water-soluble polymers with hydrolyzable cationic side groups (structure of the monomers are shown in Figure 1) were synthesized and evaluated as DNA delivery systems. The polymers, except for pHPMA-NHEM, were able to condense plasmid DNA into positively charged nanosized particles. The rate of hydrolysis at 37 degrees C and pH 7.4 of the side groups differed widely; the fastest rate of hydrolysis was observed for HPMA-DEAE (half-life of 2 h), while HPMA-DMAPr had the lowest rate of hydrolysis (half-life of 70 h). In line with this, pHPMA-DEAE-based polyplexes showed the fastest destabilization of the polyplexes at 37 degrees C and pH 7.4. Polyplexes based on pHPMA-DEAE, pHPMA-DMAE, and pHPMA-MPPM showed release of intact DNA within 24, 48, and 48 h, respectively, after incubation at 37 degrees C and pH 7.4. PHPMA-DEAE and pHPMA-MPPM based polyplexes showed the highest transfection activity (almost twice as active as pEI). Importantly, the pHPMA-DEAE, pHPMA-MPPM, and pHPMA-BDMPAP polyplexes preserved their transfection activity in the presence of serum proteins. All polymers investigated showed a substantial lower in vitro cytotoxicity than pEI. In conclusion, pHPMA-based polyplexes are an attractive class of biodegradable vectors for nonviral gene delivery.

In vivo tumor transfection mediated by polyplexes based on biodegradable poly(DMAEA)-phosphazene.

In recent years, increasing interest is being paid to the design of transfectants based on non-toxic and biodegradable polymers for gene therapy purposes. We recently reported on a novel, biodegradable polymer, poly(2-dimethylamino ethylamino)phosphazene (p(DMAEA)-ppz) for use in non-viral gene delivery. In this study, the biodistribution and in vivo transfection efficiency of polyplexes composed of plasmid DNA and p(DMAEA)-ppz were investigated after intravenous administration in tumor bearing mice. Data were compared with those of polyplexes based on the non-biodegradable polyethylenimine (PEI 22kDa). Both polyplex systems were rapidly cleared from the circulation (<7% ID, at 60 min after administration) and showed considerable disposition in the liver and the lung, all in line with earlier work on cationic polyplex systems. The lung disposition is attributed to aggregates formed by interaction of the polyplexes with blood constituents. Redistribution of the polyplexes from the lung was observed for both polyplex formulations. Importantly, both polyplex systems showed a substantial tumor accumulation of 5% and 8% ID/g for p(DMAEA)-ppz and PEI22 polyplexes, respectively, at 240 min after administration. The tumor disposition of the p(DMAEA)-ppz and PEI22 polyplexes was associated with considerable expression levels of the reporter gene. In contrast to PEI22 polyplexes, p(DMAEA)-ppz polyplexes did not display substantial gene expression in the lung or other organs (organ gene expression<1/100 of tumor gene expression). The observed preferential tumor gene expression mediated by the p(DMAEA)-ppz polyplexes enables the application of this polymer to deliver therapeutic genes to tumors.

A stereodivergent approach to substituted 4-hydroxypiperidines.

A stereodivergent route toward both diastereomeric forms of functionalized 4-hydroxypiperidines has been successfully developed. This route involves biocatalytic generation of the enantiopure starting materials followed by functionalization via N-acyliminium ion-mediated CC-bond formation.