Enhancing gene transfection of poly(ß-amino ester)s through modulation of amphiphilicity and chain sequence.

Poly(ß-amino ester)s (PAEs) have emerged as a type of highly safe and efficient non-viral DNA delivery vectors. However, the influence of amphiphilicity and chain sequence on DNA transfection efficiency and safety profile remain largely unexplored. In this study, four PAEs with distinct amphiphilicity and chain sequences were synthesized. Results show that both amphiphilicity and chain sequence significantly affect the DNA binding and condensation ability of PAEs, as well as size, zeta potential and cellular uptake of PAE/DNA polyplexes. PAEs with different amphiphilicity and chain sequence exhibit cell type-dependent transfection capabilities: in human bladder transitional cell carcinoma (UM-UC-3), hydrophilic PAE (P-Philic) and amphiphilic PAE random copolymer (R-Amphilic) exhibit relatively higher gene transfection efficiency, while in human bladder epithelial immortalized cells (SV-HUC-1), hydrophobic PAE (P-Phobic), R-Amphilic, and amphiphilic PAE block copolymer (B-Amphilic) demonstrate higher transfection capability. Regardless of cell types, amphiphilic PAE block copolymer (B-Amphilic) always exhibits much lower gene transfection efficiency. In addition, in human colon cancer cells (HCT-116), P-Philic and R-Amphilic achieved superior gene transfection efficiency at high and low polymer/DNA weight ratios, respectively. Importantly, R-Amphilic can effectively deliver the gene encoding tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) to human chondrosarcoma cells SW1353 to induce their apoptosis, highlighting its potential application in cancer gene therapy. This study not only establishes a new paradigm for enhancing the gene transfection efficiency of PAEs by modulating their amphiphilicity and chain sequence but also identifies R-Amphilic as a potential candidate for the effective delivery of TRAIL gene in cancer gene therapy.

Enhancing the Gene Transfection of Poly(ß-amino ester)/DNA Polyplexes by Modular Manipulation of Amphiphilicity.

Poly(ß-amino ester)s (PAEs) have been widely developed for gene delivery, and hydrophobic modification can further enhance their gene transfection efficiency. However, systematic manipulation of amphiphilicity of PAEs through copolymerization with hydrophobic monomers is time-consuming and, to some extent, uncontrollable. Here, a modular strategy is developed to manipulate the amphiphilicity of the PAE/DNA polyplexes. A hydrophobic polymer (DD-C12-122) and a hydrophilic polymer (DD-90-122) are synthesized separately and used as a hydrophobic module and a hydrophilic module, respectively. The amphiphilicity of polyplexes could be manipulated by changing the ratio of the hydrophobic module and hydrophilic module. Using the modular strategy, the PAE/DNA polyplexes with the highest gene transfection efficiency and safety profile as well as possible mechanisms are identified. The modular strategy provides a novel way to engineer the hydrophobicity of PAEs to improve their gene transfection and can be easily generalized and potentially extended to other polymeric gene delivery systems.

Controllable C-H Alkylation of Polyethers via Iron Photocatalysis.

The efficient conversion of a C-H bond in the polyether chain to other functional groups provides great opportunities for development of novel applications in many research fields. However, this field is quite underdeveloped due to the key challenge on controlling the selectivity of the C-H bond functionalization over the chain cleavage. In this work, we report a controllable C-H bond alkylation of polyethers under mild conditions via photoinduced iron catalysis. The level of functionalization could be controlled by using different amounts of alkenes and various reaction times, while the molecular weight distributions were maintained narrow. A broad scope of electron-deficient alkenes containing nitrile, ester, epoxide, terminal alkynyl, 2,5-dioxotetrafuranyl, and 2,5-dioxopyrrolidinyl groups could be utilized to functionalize the different polyethers with great efficiencies. The potential applications of the modified polyethylene glycols and polyethylene oxides were explored by the preparation of novel hydrogels and solid-state electrolytes with enhancement of lithium ion conductivities. Moreover, the density functional theory calculation disclosed the plausible mechanism and explained the high selectivity for the C-H alkylation.

Genetic Engineering of Adipose-Derived Stem Cells Using Biodegradable and Lipid-Like Highly Branched Poly(ß-amino ester)s.

Biodegradable and lipid-like highly branched poly(ß-amino ester)s, HPAESA, were developed to enhance the biological functions of adipose-derived stem cells by gene transfection. Biodegradability reduces the cytotoxicity of HPAESA and enables controlled DNA release. Lipid mimicry enhances cellular uptake and endosomal escape of HPAESA/DNA polyplexes. HPAESA are able to transfect rat adipose-derived stem cells (rADSs) and human ADSCs (hADSCs) with orders of magnitude higher efficiency than commercial gene transfection reagents, with cell viability exceeding 90%. Most importantly, HPAESA can effectively transfer the nerve growth factor (NGF)-encoding plasmid to rADSCs and induce high NGF secretion, which significantly promotes neurite outgrowth of PC12 cells.

Effects of craniotomy clipping and interventional embolization on treatment efficacy, cognitive function and recovery of patients complicated with subarachnoid hemorrhage.

OBJECTIVE: This research was designed to investigate the effects of craniotomy clipping and interventional embolization (IE) on the treatment efficacy, cognitive function and recovery of patients with subarachnoid hemorrhage (SAH). METHODS: A total of 148 patients with aneurysmal subarachnoid hemorrhage (ASAH) who underwent surgery in our hospital from December 2017 to August 2019 were included. They were divided into the clipping group (CG) (68 cases) and intervention group (IG) (80 cases) according to different surgical methods. The former received craniotomy clipping, and the latter underwent IE. The postoperative clinical indexes of patients were observed. The immune function (IgG, IgM, IgA) and inflammatory indexes (TNF-α, IL-8, HS-CRP) were detected before and after operation. The improvement of cognitive function, neurological function and sleep quality before and after operation was evaluated. Three months after operation, the treatment efficacy was evaluated and the postoperative complications were recorded. RESULTS: The time of operation and hospitalization of patients in the IG were dramatically less than those in the CG (P < 0.05). The levels of IgG, IgM and IgA in the IG were higher than those in the CG after operation, while those of TNF-α, IL-8 and hs-CRP in the IG were lower than those in the CG. The MOCA scores of patients in the IG were obviously higher than those in the CG (P < 0.05), and the NIHSS and PSQI scores of patients in the IG were markedly lower than those in the CG. The total effective rate of patients in the IG was remarkably higher than that in the CG (P < 0.05), while the total incidence of postoperative complications in the IG was markedly lower than that in the CG. CONCLUSION: IE is effective in the treatment of SAH patients, reducing the damage of immune, cognitive and nerve functions, with a high efficacy.

Efficient and Robust Highly Branched Poly(ß-amino ester)/Minicircle COL7A1 Polymeric Nanoparticles for Gene Delivery to Recessive Dystrophic Epidermolysis Bullosa Keratinocytes.

Recessive dystrophic epidermolysis bullosa (RDEB) is a severe congenital skin fragility disease caused by COL7A1 mutations that result in type VII collagen (C7) deficiency. Herein, we report a synergistic polyplex system that can efficiently restore C7 expression in RDEB keratinocytes. A highly branched multifunctional poly(ß-amino ester) (HPAE), termed as HC32-122, was optimized systematically as the high-performance gene delivery vector for keratinocytes, achieving much higher transfection capability than polyethylenimine, SuperFect, and Lipofectamine 2000 without inducing obvious cytotoxicity. Concurrently, a 12 kb length minicircle DNA encoding ∼9 kb full-length COL7A1 (MCC7) devoid of bacterial sequence was biosynthesized as the therapeutic gene. Combining the highly potent polymer and the miniaturized gene structure, HC32-122/MCC7 polyplexes achieve 96.4% cellular uptake efficiency, 4019-fold COL7A1 mRNA enhancement, and robust recombinant C7 expression. Structure-property investigations reveal that HC32-122 can effectively condense MCC7 to form small, uniform, compact, and positively charged spherical nanoparticles with high DNA release flexibility. Moreover, formulation study shows that sucrose is conductive to lyophilized HC32-122/DNA polyplexes for maintaining the transfection capability. Direct frozen polyplexes can maintain full gene transfection capability after one-year storage. High efficiency, biocompatibility, facile manipulation, and long-term stability make the HC32-122/MCC7 system a promising bench-to-bed candidate for treating the debilitating RDEB.

Highly branched poly(ß-amino ester) delivery of minicircle DNA for transfection of neurodegenerative disease related cells.

Current therapies for most neurodegenerative disorders are only symptomatic in nature and do not change the course of the disease. Gene therapy plays an important role in disease modifying therapeutic strategies. Herein, we have designed and optimized a series of highly branched poly(ß-amino ester)s (HPAEs) containing biodegradable disulfide units in the HPAE backbone (HPAESS) and guanidine moieties (HPAESG) at the extremities. The optimized polymers are used to deliver minicircle DNA to multipotent adipose derived stem cells (ADSCs) and astrocytes, and high transfection efficiency is achieved (77% in human ADSCs and 52% in primary astrocytes) whilst preserving over 90% cell viability. Furthermore, the top-performing candidate mediates high levels of nerve growth factor (NGF) secretion from astrocytes, causing neurite outgrowth from a model neuron cell line. This synergistic gene delivery system provides a viable method for highly efficient non-viral transfection of ADSCs and astrocytes.

A hybrid injectable hydrogel from hyperbranched PEG macromer as a stem cell delivery and retention platform for diabetic wound healing.

The injectable hydrogel with desirable biocompatibility and tunable properties can improve the efficacy of stem cell-based therapy. However, the development of injectable hydrogel remains a great challenge due to the restriction of crosslinking efficiency, mechanical properties, and potential toxicity. Here, we report that a new injectable hydrogel system was fabricated from hyperbranched multi-acrylated poly(ethylene glycol) macromers (HP-PEGs) and thiolated hyaluronic acid (HA-SH) and used as a stem cell delivery and retention platform. The new HP-PEGs were synthesized via in situ reversible addition fragmentation chain transfer (RAFT) polymerization using an FDA approved anti-alcoholic drug-Disulfiram (DS) as the RAFT agent precursor. HP-PEGs can form injectable hydrogels with HA-SH rapidly via thiol-ene click reaction under physiological conditions. The hydrogels exhibited stable mechanical properties, non-swelling and anti-fouling properties. Hydrogels encapsulating adipose-derived stem cells (ADSCs) have demonstrated promising regenerative capabilities such as the maintenance of ADSCs' stemness and secretion abilities. The ADSCs embedded hydrogels were tested on the treatment of diabetic wound in a diabetic murine animal model, showing enhanced wound healing. STATEMENT OF SIGNIFICANCE: Diabetic wounds, which are a severe type of diabetes, have become one of the most serious clinical problems. There is a great promise in the delivery of adipose stem cells into wound sites using injectable hydrogels that can improve diabetic wound healing. Due to the biocompatibility of poly(ethylene glycol) diacrylate (PEGDA), we developed an in situ RAFT polymerization approach using anti-alcoholic drug-Disulfiram (DS) as a RAFT agent precursor to achieve hyperbranched PEGDA (HP-PEG). HP-PEG can form an injectable hydrogel by crosslinking with thiolated hyaluronic acid (HA-SH). ADSCs can maintain their regenerative ability and be delivered into the wound sites. Hence, diabetic wound healing process was remarkably promoted, including inhibition of inflammation, enhanced angiogenesis and re-epithelialization. Taken together, the ADSCs-seeded injectable hydrogel may be a promising candidate for diabetic wound treatment.

Bioreducible Zinc(II)-Coordinative Polyethylenimine with Low Molecular Weight for Robust Gene Delivery of Primary and Stem Cells.

To transform common low-molecular-weight (LMW) cationic polymers, such as polyethylenimine (PEI), to highly efficient gene vectors would be of great significance but remains challenging. Because LMW cationic polymers perform far less efficiently than their high-molecular-weight counterparts, mainly due to weaker nucleic acid encapsulation, herein we report the design and synthesis of a dipicolylamine-based disulfide-containing zinc(II) coordinative module (Zn-DDAC), which is used to functionalize LMW PEI (Mw ≈ 1800 Da) to give a non-viral vector (Zn-PD) with high efficiency and safety in primary and stem cells. Given its high phosphate binding affinity, Zn-DDAC can significantly promote the DNA packaging functionality of PEI1.8k and improve the cellular uptake of formulated polyplexes, which is particularly critical for hard-to-transfect cell types. Furthermore, Zn-PD polymer can be cleaved by glutathione in cytoplasm to facilitate DNA release post internalization and diminish the cytotoxicity. Consequently, the optimal Zn-PD mediates 1-2 orders of magnitude higher gluciferase activity than commercial transfection reagents, Xfect and PEI25k, across diverse cell types, including primary and stem cells. Our findings provide a valuable insight into the exploitation of LMW cationic polymers for gene delivery and demonstrate great promise for the development of next-generation non-viral vectors for clinically viable gene therapy.

Highly Branched poly(5-amino-1-pentanol-co-1,4-butanediol diacrylate) for High Performance Gene Transfection.

The top-performing linear poly(ß-amino ester) (LPAE), poly(5-amino-1-pentanol-co-1,4-butanediol diacrylate) (C32), has demonstrated gene transfection efficiency comparable to viral-mediated gene delivery. Herein, we report the synthesis of a series of highly branched poly(5-amino-1-pentanol-co-1,4-butanediol diacrylate) (HC32) and explore how the branching structure influences the performance of C32 in gene transfection. HC32 were synthesized by an "A2 + B3 + C2" Michal addition strategy. Gaussia luciferase (Gluciferase) and green fluorescent protein (GFP) coding plasmid DNA were used as reporter genes and the gene transfection efficiency was evaluated in human cervical cancer cell line (HeLa) and human recessive dystrophic epidermolysis bullosa keratinocyte (RDEBK) cells. We found that the optimal branching structure led to a much higher gene transfection efficiency in comparison to its linear counterpart and commercial reagents, while preserving high cell viability in both cell types. The branching strategy affected DNA binding, proton buffering capacity and degradation of polymers as well as size, zeta potential, stability, and DNA release rate of polyplexes significantly. Polymer degradation and DNA release rate played pivotal parts in achieving the high gene transfection efficiency of HC32-103 polymers, providing new insights for the development of poly(ß-amino ester)s-based gene delivery vectors.

Biodegradable Highly Branched Poly(ß-Amino Ester)s for Targeted Cancer Cell Gene Transfection.

To enhance the gene transfection efficiency to targeted cells while reducing the side effects to untargeted cells is of great significance for clinical gene therapy. Here, biodegradable highly branched poly(ß-amino ester)s (HPAESS) are synthesized and functionalized with folate (HPAESS-FA) and lactobionic acid (HPAESS-Lac) for targeted cancer cell gene transfection. Results show that because of the triggered degradability of the vector and enhanced receptor-mediated cellular uptake of polyplexes, the HPAESS-FA and HPAESS-Lac exhibit superior gene transfection capability in specific cancer cells with negligible cytotoxicity, pointing to their promise as targeted vectors for efficient cancer gene therapy.

Alkylated branched poly(ß-amino esters) demonstrate strong DNA encapsulation, high nanoparticle stability and robust gene transfection efficacy.

A branched poly(ß-amino ester) with numerous alkyl chains (BPA) is designed and synthesized as a safe and efficient non-viral vector. The branching and hydrophobicity synergistically endow BPA with tight DNA condensation, high polyplex stability in serum, high cellular uptake and ultimately robust gene transfection efficiency, largely superior to its linear counterpart (LPA). Our results demonstrate that branching matters for gene delivery by hydrophobic gene vectors.

Development of Branched Poly(5-Amino-1-pentanol-co-1,4-butanediol Diacrylate) with High Gene Transfection Potency Across Diverse Cell Types.

One of the most significant challenges in the development of polymer materials for gene delivery is to understand how topological structure influences their transfection properties. Poly(5-amino-1-pentanol-co-1,4-butanediol diacrylate) (C32) has proven to be the top-performing gene delivery vector developed to date. Here, we report the development of branched poly(5-amino-1-pentanol-co-1,4-butanediol diacrylate) (HC32) as a novel gene vector and elucidate how the topological structure affects gene delivery properties. We found that the branched structure has a big impact on gene transfection efficiency resulting in a superior transfection efficiency of HC32 in comparison to C32 with a linear structure. Mechanistic investigations illustrated that the branched structure enhanced DNA binding, leading to the formation of toroidal polyplexes with smaller size and higher cationic charge. Importantly, the branched structure offers HC32 a larger chemical space for terminal functionalization (e.g., guanidinylation) to further enhance the transfection. Moreover, the optimized HC32 is capable of transfecting a diverse range of cell types including cells that are known to be difficult to transfect such as stem cells and astrocytes with high efficiency. Our study provides a new insight into the rational design of poly(ß-amino ester) (PAE) based polymers for gene delivery.

Highly Branched Poly(ß-amino esters) for Non-Viral Gene Delivery: High Transfection Efficiency and Low Toxicity Achieved by Increasing Molecular Weight.

A successful polymeric gene delivery vector is denoted by both transfection efficiency and biocompatibility. However, the existing vectors with combined high efficacy and minimal toxicity still fall short. The most widely used polyethylene imine (PEI), polyamidoamine (PAMAM) and poly(dimethylaminoethyl methacrylate) (PDMAEMA) suffer from the correlation: either too toxic or little effective. Here, we demonstrate that with highly branched poly(ß-amino esters) (HPAEs), a type of recently developed gene delivery vector, the high gene transfection efficiency and low cytotoxicity can be achieved simultaneously at high molecular weight (MW). The interactions of HPAE/DNA polyplexes with cell membrane account for the favorable correlation between molecular weight and biocompatibility. In addition to the effect of molecular weight, the molecular configuration of linear and branched segments in HPAEs is also pivotal to endow high transfection efficiency and low cytotoxicity. These findings provide renewed perspective for the further development of clinically viable gene delivery vectors.

The transition from linear to highly branched poly(ß-amino ester)s: Branching matters for gene delivery.

Nonviral gene therapy holds great promise but has not delivered treatments for clinical application to date. Lack of safe and efficient gene delivery vectors is the major hurdle. Among nonviral gene delivery vectors, poly(ß-amino ester)s are one of the most versatile candidates because of their wide monomer availability, high polymer flexibility, and superior gene transfection performance both in vitro and in vivo. However, to date, all research has been focused on vectors with a linear structure. A well-accepted view is that dendritic or branched polymers have greater potential as gene delivery vectors because of their three-dimensional structure and multiple terminal groups. Nevertheless, to date, the synthesis of dendritic or branched polymers has been proven to be a well-known challenge. We report the design and synthesis of highly branched poly(ß-amino ester)s (HPAEs) via a one-pot "A2 + B3 + C2"-type Michael addition approach and evaluate their potential as gene delivery vectors. We find that the branched structure can significantly enhance the transfection efficiency of poly(ß-amino ester)s: Up to an 8521-fold enhancement in transfection efficiency was observed across 12 cell types ranging from cell lines, primary cells, to stem cells, over their corresponding linear poly(ß-amino ester)s (LPAEs) and the commercial transfection reagents polyethyleneimine, SuperFect, and Lipofectamine 2000. Moreover, we further demonstrate that HPAEs can correct genetic defects in vivo using a recessive dystrophic epidermolysis bullosa graft mouse model. Our findings prove that the A2 + B3 + C2 approach is highly generalizable and flexible for the design and synthesis of HPAEs, which cannot be achieved by the conventional polymerization approach; HPAEs are more efficient vectors in gene transfection than the corresponding LPAEs. This provides valuable insight into the development and applications of nonviral gene delivery and demonstrates great prospect for their translation to a clinical environment.

Highly branched poly(ß-amino ester)s for skin gene therapy.

Poly(ß-amino ester)s (PAEs) have emerged as a promising class of gene delivery vectors with performances that can even be compared to viruses. However, all of the transfection studies (over 2350 PAEs) have been limited to linear poly(ß-amino ester)s (LPAEs) despite increasing evidence that polymer structure significantly affects performance. Herein, we describe the development of highly branched poly(ß-amino ester)s (HPAEs) via a new "A2+B3+C2" Michael addition approach demonstrating 2 to 126-fold higher in vitro transfection efficiencies of different cell types in comparison to their linear LPAE counterparts as well as greatly out-performing the leading transfection reagents SuperFect and the "gold-standard" polyethyleneimine (PEI) - especially on skin epidermal cells. More importantly, the ability to correct a skin genetic defect is demonstrated in vivo utilizing a recessive dystrophic epidermolysis bullosa (RDEB) knockout mouse model. Our results provide evidence that the "A2+B3+C2" approach can be controlled and offers sufficient flexibility for the synthesis of HPAEs. The branched structures can significantly improve the transfection efficiency and safety of PAEs highlighting the great promise for the successful application of non-viral gene therapy in skin disease.

Multifunctional oligomer incorporation: a potent strategy to enhance the transfection activity of poly(l-lysine).

Natural polycations, such as poly(l-lysine) (PLL) and chitosan (CS), have inherent superiority as non-viral vectors due to their unparalleled biocompatibility and biodegradability. However, the application was constrained by poor transfection efficiency and safety concerns. Since previous modification strategies greatly weakened the inherent advantages of natural polycations, developing a strategy for functional group introduction with broad applicability to enhance the transfection efficiency of natural polycations without compromising their cationic properties is imperative. Herein, two uncharged functional diblock oligomers P(DMAEL-b-NIPAM) and P(DMAEL-b-Vlm) were prepared from a lactose derivative, N-iso-propyl acrylamide (NIPAM) as well as 1-vinylimidazole (Vlm) and further functionalized with four small ligands folate, glutathione, cysteine and arginine, respectively, aiming to enhance the interactions of complexes with cells, which were quantified utilizing a quartz crystal microbalance (QCM) biosensor, circumventing the tedious material screening process of cell transfection. Upon incorporation with PLL and DNA, the multifunctional oligomers endow the formulated ternary complexes with great properties suitable for transfection, such as anti-aggregation in serum, destabilized endosome membrane, numerous functional sites for promoted endocytosis and therefore robust transfection activity. Furthermore, different from the conventional strategy of decreasing cytotoxicity by reducing the charge density, the multifunctional oligomer incorporation strategy maintains the highly positive charge density, which is essential for efficient cellular uptake. This system develops a new platform to modify natural polycations towards clinical gene therapy.

Anticancer Drug Disulfiram for In Situ RAFT Polymerization: Controlled Polymerization, Multifacet Self-Assembly, and Efficient Drug Delivery.

Here we report the synthesis of a well-defined amphiphilic conjugate, tetraethylthiuram disulfide (disulfiram, DS)-poly(ethylene glycol) methyl ether acrylate (DS-PEGMEA), and its multifacet self-assembly in aqueous solutions and application in DS drug delivery to melanoma cells. The DS-PEGMEA was synthesized via the reversible addition-fragmentation chain transfer (RAFT) polymerization utilizing DS, a 90 year old anticancer drug, as a precursor to generate RAFT agent in situ. Results demonstrate that the in situ formed RAFT can effectively control the polymerization of PEGMEA. Depending on the concentration in aqueous solution, the amphiphilic DS-PEGMEA conjugate can self-assemble to form layered, toroidal, hairy, or spherical nanostructures, respectively. Moreover, DS drug can be further encapsulated by DS-PEGMEA to formulate core-shell structured DS/DS-PEGMEA nanoparticles mediating the apoptosis of melanoma cells (A375) while inducing minimal cytotoxicity to normal (hADSC and NIH fibroblast) cells. Both DS and PEGMEA are approved by the American Food and Drug Administration (FDA); therefore, the DS-PEGMEA has great potential for application in clinical drug delivery to melanoma.

Gene delivery of PEI incorporating with functional block copolymer via non-covalent assembly strategy.

A novel functional diblock polymer P(PEGMA-b-MAH) is prepared and incorporated to improve the gene delivery efficiency of poly(ethyleneimine) PEI via non-covalent assembly strategy. First, P(PEGMA-b-MAH) is prepared from l-methacrylamidohistidine methyl ester (MAH) by reversible addition fragmentation chain transfer polymerization, with poly[poly(ethylene glycol) methyl ether methacrylate] (P(PEGMA)) as the macroinitiator. Then P(PEGMA-b-MAH) is assembled with plasmid DNA (pDNA) and PEI (M(w)=10kDa) to form PEI/P(PEGMA-b-MAH)/pDNA ternary complexes. The agarose gel retardation assay shows that the presence of P(PEGMA-b-MAH) does not interfere with DNA condensation by the PEI. Dynamic light scattering tests show that PEI/P(PEGMA-b-MAH)/pDNA ternary complexes have excellent serum stability. In vitro transfection indicates that, compared to the P(PEGMA-b-MAH) free PEI-25k/pDNA binary complexes, PEI-10k/P(PEGMA-b-MAH)/pDNA ternary complexes have lower cytotoxicity and higher gene transfection efficiency, especially under serum conditions. The ternary complexes proposed here can inspire a new strategy for the development of gene and drug delivery vectors.

Glycopolymer modification on physicochemical and biological properties of poly(L-lysine) for gene delivery.

Poly(L-lysine) (PLL) has excellent plasmid DNA (pDNA) condensation capacity. However, the relatively high cytotoxicity and low transfection efficiency limit its application as gene delivery vectors. Here, well-defined glycopolymers are synthesized by reversible addition fragmentation transfer polymerization and grafted onto PLL to improve the gene delivery performance. After glycopolymer modification, PLL shows reduced cytotoxicity. By regulating the glycopolymer length and amino group substitution degree, the glycopolymer modified PLL can condense pDNA with proper strength, protect the condensed pDNA from degradation and release them in time. Transfection with NIH3T3 and HepG2 cells shows that the glycopolymer modified PLL has improved transfection efficiencies. The low cytotoxicity, effective pDNA protection and enhanced transfection efficiencies indicate that glycopolymer modification would be an effective strategy to improve the polycation properties for gene delivery.