Amphiphilic siRNA Conjugates for Co-Delivery of Nucleic Acids and Hydrophobic Drugs.

Combination therapy of nucleic acids and chemical drugs for cancer treatment is a promising strategy to enhance the therapeutic efficacy by simultaneously regulating multiple troublesome pathways. In this study, we report on polyethylene glycol-siRNA-polycaprolactone (PEG-siRNA-PCL) micelles that encapsulate hydrophobic drugs for efficient co-delivery of siRNA and drugs to cancer cells. Amphiphilic PEG-siRNA-PCL copolymers were synthesized by annealing antisense siRNA-PCL conjugates with sense siRNA-PEG conjugates. After paclitaxel encapsulation, PEG-siRNA-PCL micelles containing antiapoptotic Bcl-2-specific siRNA were stabilized with linear polyethylenimine via electrostatic interactions. Stabilized PEG-siRNA-PCL micelles showed superior anticancer effects, assessed by caspase-3 activity analysis, apoptotic cell staining, and a cytotoxicity test, to those of paclitaxel-free PEG-siRNA-PCL micelles and unmodified siRNAs. The strong anticancer activity of paclitaxel-incorporated siRNA micelles can be attributed to the synergistic effect of Bcl-2 siRNA and paclitaxel. This work provides an efficient co-delivery platform for combination anticancer therapy with siRNA and chemotherapy.

Tumor-targeted delivery of paclitaxel using low density lipoprotein-mimetic solid lipid nanoparticles.

Water-insoluble anticancer drugs, including paclitaxel, present severe clinical side effects when administered to patients, primarily associated with the toxicity of reagents used to solubilize the drugs. In efforts to develop alternative formulations of water-insoluble anticancer drugs suitable for intravenous administration, we developed biocompatible anticancer therapeutic solid lipid nanoparticles (SLNs), mimicking the structure and composition of natural particles, low-density lipoproteins (LDLs), for tumor-targeted delivery of paclitaxel. These therapeutic nanoparticles contained water-insoluble paclitaxel in the core with tumor-targeting ligand covalently conjugated on the polyethylene glycol (PEG)-modified surface (targeted PtSLNs). In preclinical human cancer xenograft mouse model studies, the paclitaxel-containing tumor-targeting SLNs exhibited pronounced in vivo stability and enhanced biocompatibility. Furthermore, these SLNs had superior antitumor activity to in-class nanoparticular therapeutics in clinical use (Taxol and Genexol-PM) and yielded long-term complete responses. The in vivo targeted antitumor activities of the SLN formulations in a mouse tumor model suggest that LDL-mimetic SLN formulations can be utilized as a biocompatible, tumor-targeting platform for the delivery of various anticancer therapeutics.

Small-interfering RNA (siRNA)-based functional micro- and nanostructures for efficient and selective gene silencing.

Because of RNA's ability to encode structure and functional information, researchers have fabricated diverse geometric structures from this polymer at the micro- and nanoscale. With their tunable structures, rigidity, and biocompatibility, novel two-dimensional and three-dimensional RNA structures can serve as a fundamental platform for biomedical applications, including engineered tissues, biosensors, and drug delivery vehicles. The discovery of the potential of small-interfering RNA (siRNA) has underscored the applications of RNA-based micro- and nanostructures in medicine. Small-interfering RNA (siRNA), synthetic double-stranded RNA consisting of approximately 21 base pairs, suppresses problematic target genes in a sequence-specific manner via inherent RNA interference (RNAi) processing. As a result, siRNA offers a potential strategy for treatment of many human diseases. However, due to inefficient delivery to cells and off-target effects, the clinical application of therapeutic siRNA has been very challenging. To address these issues, researchers have studied a variety of nanocarrier systems for siRNA delivery. In this Account, we describe several strategies for efficient siRNA delivery and selective gene silencing. We took advantage of facile chemical conjugation and complementary hybridization to design novel siRNA-based micro- and nanostructures. Using chemical crosslinkers and hydrophobic/hydrophilic polymers at the end of siRNA, we produced various RNA-based structures, including siRNA block copolymers, micelles, linear siRNA homopolymers, and microhydrogels. Because of their increased charge density and flexibility compared with conventional siRNA, these micro- and nanostructures can form polyelectrolyte complexes with poorly charged and biocompatible cationic carriers that are both more condensed and more homogenous than the complexes formed in other carrier systems. In addition, the fabricated siRNA-based structures are linked by cleavable disulfide bonds for facile generation of original siRNA in the cytosol and for target-specific gene silencing. These newly developed siRNA-based structures greatly enhance intracellular uptake and gene silencing both in vitro and in vivo, making them promising biomaterials for siRNA therapeutics.

Cationic lipid-coated gold nanoparticles as efficient and non-cytotoxic intracellular siRNA delivery vehicles.

PURPOSE: Cationic lipid-coated gold nanoparticles were developed for efficient intracellular delivery of therapeutic siRNA. METHODS: Particle formation was characterized by UV-visible spectroscopy, atomic force microscopy, and dynamic light scattering analysis. Cellular uptake, gene silencing effect, and cytotoxicity were investigated in multiple human cancer cell lines. RESULTS: Nanoparticles had a spherical nanostructure with highly cationic surface charge and could form stable nanosized polyelectrolyte complexes with siRNA via electrostatic interactions; complexes exhibited efficient intracellular uptake and significant gene silencing effect with markedly low cytotoxicity compared to the widely used polycationic carrier, linear polyethyleneimine. CONCLUSIONS: We demonstrated that cationic lipid-coated gold nanoparticles could be widely utilized as efficient and safe siRNA nanocarriers for diverse therapeutic and diagnostic applications.

Antifibrotic effect of MMP13-encoding plasmid DNA delivered using polyethylenimine shielded with hyaluronic acid.

The imbalanced expression of matrix metalloproteinases (MMPs) is associated with liver fibrosis, one of the most common chronic liver diseases. Enhanced expression of MMPs by gene therapy is emerging as a promising antifibrotic strategy, but the effectiveness of this approach depends on reliable systems for delivering MMP genes. Here, we evaluated a newly designed hyaluronic acid (HA)-shielded delivery system for systemic administration of plasmid DNA encoding MMP13 (pMMP13), and tested whether the enhanced expression of MMP13 ameliorates liver fibrosis in mice. In the CCl(4)-induced liver fibrosis model, systemic administration of pMMP13 using HA and polyethylenimine (PEI) significantly increased the expression of MMP13 and reduced collagen deposition. Moreover, following delivery of pMMP13 in a HA-shielded PEI complex, the serum levels of aspartate transaminase were reduced to levels approaching those in untreated normal mice. These results indicate that the delivery of pMMP13 using HA-shielded PEI enhances the efficiency of MMP13 expression in the liver, and highlight the potential of pMMP13 gene therapy as an antifibrotic strategy.

Gene silencing by siRNA microhydrogels via polymeric nanoscale condensation.

The first attempt to prepare biologically active siRNA-based microhydrogels is reported. The self-assembled microhydrogels were fabricated using sense/antisense complementary hybridization between single-stranded linear and Y-shaped trimeric siRNAs. The siRNA microhydrogels were condensed using a popular cationic polymer such as LPEI to form compact, stable siRNA/polymeric nanoparticles that exhibited superb cellular uptake efficiency and gene silencing activity.

Reducible siRNA dimeric conjugates for efficient cellular uptake and gene silencing.

In this study, dimerized siRNAs linked by a cleavable disulfide bond were synthesized for efficient intracellular delivery and gene silencing. The reducible dimerized siRNAs showed far enhanced complexation behaviors with cationic polymers as compared to monomeric siRNA at the same N/P ratio, as demonstrated by microscopic techniques and gel characterization. Dimerized siRNAs targeting green fluorescent protein (GFP) or vascular endothelial growth factor (VEGF) were complexed with linear polyethylenimine (LPEI), and treated to various cell lines to examine gene transfection efficiencies. In comparison to monomer siRNA/LPEI complexes, dimeric siRNA/LPEI complexes showed greatly enhanced cellular uptake and gene silencing effects in vitro. These results were mainly due to the higher charge density and promoted chain flexibility of the dimerized siRNAs, providing more compact and stable siRNA complexes. In addition, the conjugation strategy of reducible siRNA dimers was further extended: poly(ethylene glycol) (PEG)-modified dimerized siRNAs and heterodimers of siRNAs targeting two different genes (e.g., GFP and VEGF) were synthesized, and their gene silencing efficiencies were characterized. The dimerized siRNA complex system holds great potential for in vivo systemic gene therapy.

In vivo specific delivery of c-Met siRNA to glioblastoma using cationic solid lipid nanoparticles.

RNA interference is a powerful strategy that inhibits gene expression through specific mRNA degradation. In vivo, however, the application of small interfering RNAs (siRNAs) is severely limited by their instability and their poor delivery into target cells and tissues. This is especially true with glioblastomas (GBMs), the most frequent and malignant form of brain tumor, that has limited treatment options due to the largely impenetrable blood-brain barrier. Here, cationic solid lipid nanoparticles (SLN), reconstituted from natural components of protein-free low-density lipoprotein, was conjugated to PEGylated c-Met siRNA. The c-Met siRNA-PEG/SLN complex efficiently down-regulated c-Met expression level, as well as decreased cell proliferation in U-87MG in vitro. In orthotopic U-87MG xenograft tumor model, intravenous administration of the complex significantly inhibited c-Met expression at the tumor tissue and suppressed tumor growth without showing any systemic toxicity in mice. Use of Cy5.5 conjugated SLN revealed enhanced accumulation of the siRNA-PEG/SLN complexes specifically in the brain tumor. Our data demonstrates the feasibility of using siRNA-PEG/SLN complexes as a potential carrier of therapeutic siRNAs for the systemic treatment of GBM in the clinic.

Clustered magnetite nanocrystals cross-linked with PEI for efficient siRNA delivery.

Magnetofection has been utilized as a powerful tool to enhance gene transfection efficiency via magnetic field-enforced cellular transport processes. The accelerated accumulation of nucleic acid molecules by applying an external magnetic force enables the rapid and improved transduction efficiency. In this study, we developed magnetite nanocrystal clusters (PMNCs) cross-linked with polyethylenimine (PEI) to magnetically trigger intracellular delivery of small interfering RNA (siRNA). PMNCs were produced by cross-linked assembly of catechol-functionalized branched polyethylenimine (bPEI) around magnetite nanocrystals through an oil-in-water (O/W) emulsion and solvent evaporation method. The physical properties of PMNC were characterized by TEM, DLS, TSA, and FT-IR. Finely tuned formulation of clustered magnetite nanocrystals with controlled size and shape exhibited superior saturation of magnetization value. Magnetite nanocrystal clusters could form nanosized polyelectrolyte complexes with negatively charged siRNA molecules, enabling efficient delivery of siRNA into cells upon exposure to an external magnetic field within a short time. This study introduces a new class of magnetic nanomaterials that can be utilized for magnetically driven intracellular siRNA delivery.

Catechol-functionalized chitosan/pluronic hydrogels for tissue adhesives and hemostatic materials.

Bioinspired from adhesion behaviors of mussels, injectable and thermosensitive chitosan/Pluronic composite hydrogels were synthesized for tissue adhesives and hemostatic materials. Chitosan conjugated with multiple catechol groups in the backbone was cross-linked with terminally thiolated Pluronic F-127 triblock copolymer to produce temperature-sensitive and adhesive sol-gel transition hydrogels. A blend mixture of the catechol-conjugated chitosan and the thiolated Pluronic F-127 was a viscous solution state at room temperature but became a cross-linked gel state with instantaneous solidification at the body temperature and physiological pH. The adhesive chitosan/Pluronic injectable hydrogels with remnant catechol groups showed strong adhesiveness to soft tissues and mucous layers and also demonstrated superior hemostatic properties. These chitosan/Pluronic hydrogels are expected to be usefully exploited for injectable drug delivery depots, tissue engineering hydrogels, tissue adhesives, and antibleeding materials.

Self-assembled and nanostructured siRNA delivery systems.

A wide range of organic and inorganic materials have been used in the development of nano-scale self-assembling gene delivery systems to improve the therapeutic efficacy of nucleic acid drugs. Small interfering RNA (siRNA) has recently been recognized as a promising and potent nucleic acid medicine for the treatment of incurable genetic disorders including cancer; however, siRNA-based therapeutics suffer from the same delivery problems as conventional nucleic acid drugs such as plasmid DNA and antisense oligonucleotides. Many of the delivery strategies developed for nucleic acid drugs have been applied to siRNA therapeutics, but they have not produced satisfactory in vivo gene silencing efficiencies to warrant clinical trials. This review discusses recent progress in the development of self-assembled and nanostructured delivery systems for efficient siRNA-induced gene silencing and their potential application in clinical settings.

Intracellular trafficking and unpacking of siRNA/quantum dot-PEI complexes modified with and without cell penetrating peptide: confocal and flow cytometric FRET analysis.

Cationic quantum dots (QDs) were utilized to complex small interfering RNA (siRNA) for studying intracellular trafficking, unpacking, and gene silencing. Positively charged polyethylenimine (PEI) was covalently conjugated on the surface of QDs to complex with cyanine dye labeled vascular endothelial growth factor siRNA (cy5-VEGF siRNA) for the formation of nanosized polyelectrolyte complexes (PEC). Fluorescence resonance energy transfer (FRET) was achieved between cy5-VEGF siRNA and PEI conjugated QDs (QD625) in the complex. From confocal microscopic analysis, intracellular uptake and release of siRNA from the PEC were visualized as a function of incubation time. The extent of cy5-siRNA release from the PEC was quantitatively evaluated by flow cytometric analysis. In addition, PEI conjugated QDs were further modified with a protein transduction domain (PTD) from human transcriptional factor, Hph-1. The two siRNA/QD-PEI complexes with and without Hph-1 have shown markedly different intracellular uptake behaviors and unpacking kinetics of cy5-siRNA. However, they exhibited similar extent of VEGF gene knockout regardless of Hph-1, but showed much higher gene silencing efficiency than siRNA/PEI complexes. The present study demonstrates that PEI conjugated QDs can be utilized as a useful siRNA carrier to analyze intracellular trafficking and unpacking pathway as well as to effectively silence a target gene.

Thermally triggered cellular uptake of quantum dots immobilized with poly(N-isopropylacrylamide) and cell penetrating peptide.

Thermally sensitive quantum dots (TSQDs) that exhibit an "on-demand" cellular uptake behavior via temperature-induced "shielding/deshielding" of cell penetrating peptides (CPP) on the surface were fabricated. Poly(N-isopropylacrylamide) (PNIPAAm) (M(w) = 11.5K) and CPP were biotinylated at their terminal ends and co-immobilized on to the surface of streptavidin-coated quantum dots (QDs-Strep) through biotin-streptavidin interaction. The cellular contact of CPP was sterically hindered due to hydrated PNIPAAm chains below the lower critical solution temperature (LCST). In contrast, above the LCST, grafted PNIPAAm chains were collapsed to make CPP moieties resurfaced, leading to increased cellular uptake of QDs. The temperature-controlled "shielding/deshielding" of CPP was further applied for a thermally triggered siRNA delivery system, where biotinylated siRNA was additionally conjugated to the surface of TSQDs. The level of gene silencing was significantly enhanced by increasing temperature above the LCST due to the surface exposure of CPP.

Controlled release of paclitaxel from heparinized metal stent fabricated by layer-by-layer assembly of polylysine and hyaluronic acid-g-poly(lactic-co-glycolic acid) micelles encapsulating paclitaxel.

Drug-eluting stent (DES) has been widely used for effective treatment of obstructive coronary artery disease, preventing the occurrence of restenosis that is mainly caused by hyper-proliferation of smooth muscle cells. Here, we demonstrate the immobilization of heparin on the metal surface via a bioinspired manner and subsequent build-up of a therapeutic layer-by-layer multilayer composed of paclitaxel (PTX) encapsulated poly(lactic-co-glycolic acid) grafted hyaluronic acid (HA-g-PLGA) micelles, heparin, and poly-L-lysine (PLL). It was hypothesized that the heparinized metallic surface would create a nonthrombogenic environment, while controlled release of PTX from the surface could induce antiproliferation of smooth muscle cells. For the surface immobilization of heparin on the surface of cobalt-chromium alloy (L605), dopamine-derivatized heparin was synthesized and anchored on the surface by a mussel-inspired adhesion mechanism. An amphiphilic graft copolymer of HA-g-PLGA was synthesized and utilized for the formation of anionic PTX loaded micelles. A PTX eluting multilayer composed of anionic HA-g-PLGA micelles, heparin, and PLL was self-assembled on the metal surface by a layer-by-layer fashion. The loading amount of PTX on the metal surface could be readily controlled with concomitantly achieving sustained release profiles of PTX over an extended period. The proliferation of human coronary artery smooth muscle cells was successfully arrested by controlled released PTX from the therapeutic multilayer coated on the metallic substrate.

Epidermal growth factor (EGF) receptor targeted delivery of PEGylated adenovirus.

A biotin-polyethylene glycol (PEG)-epidermal growth factor (EGF) conjugate was immobilized onto the surface of avidin-modified adenovirus (ADV-Avi) via biotin-avidin interaction to deliver ADV specifically to EGF receptor over-expressing cancer cells. ADV-Avi/biotin-PEG-EGF complexes showed greatly enhanced intracellular uptake of ADV particles for an EGF receptor positive cell line (A431 cells), compared to naked or PEG alone immobilized ADV. ADV coding an exogenous GFP gene was used to quantitatively evaluate the level of GFP expression. ADV-Avi/biotin-PEG-EGF complexes also exhibited significantly increased extent of GFP expression for A431 cells, but not for MCF-7 cells (an EGF receptor deficient cell line), suggesting that retargeting of ADV to specific cells occurred by tethering of a cell-specific targeting ligand to the distal end of a PEG chain anchored onto the surface of ADV. This study demonstrates that ADV-Avi/biotin-PEG-EGF construct systems can be applied for cell-specific delivery of ADV with simultaneously reducing innate immune responses.

Hyaluronic acid-paclitaxel conjugate micelles: synthesis, characterization, and antitumor activity.

Chemical conjugates of paclitaxel and hyaluronic acid (HA) were synthesized by utilizing a novel HA solubilization method in a single organic phase. Hydrophilic HA was completely dissolved in anhydrous DMSO with addition of poly(ethylene glycol) (PEG) by forming nanocomplexes. Paclitaxel was then chemically conjugated to HA in the DMSO phase via an ester linkage without modifying extremely hydrophilic HA. A series of HA-paclitaxel conjugates with different conjugation percentages were synthesized and characterized. HA-paclitaxel conjugates self-assembled in aqueous solution to form nanosized micellar aggregates, as characterized by dynamic light scattering (DLS), atomic force microscopy (AFM), and transmission electron microscopy (TEM). An intact form of paclitaxel was regenerated from HA-paclitaxel conjugate micelles at acidic pH conditions. HA-paclitaxel conjugate micelles exhibited more pronounced cytotoxic effect for HA receptor overexpressing cancer cells than for HA receptor deficient cells, suggesting that they can be potentially utilized as tumor-specific nanoparticulate therapeutic agents.

LHRH receptor-mediated delivery of siRNA using polyelectrolyte complex micelles self-assembled from siRNA-PEG-LHRH conjugate and PEI.

Polyelectrolyte complex (PEC) micelles modified with cancer cell targeting moieties were prepared for intracellular delivery of vascular endothelial growth factor (VEGF) small interfering RNA (siRNA). A luteinizing hormone-releasing hormone (LHRH) peptide analogue was coupled as a cancer targeting ligand to the distal end of the poly(ethylene glycol) (PEG)-siRNA conjugate. The siRNA-PEG-LHRH conjugate self-assembled to form nanosized PEC micelles upon mixing with poly(ethylenimine) (PEI) via ionic interactions. The PEC micelles showed spherical morphology with a hydrodynamic diameter of ca. 150 nm. For LHRH receptor overexpressing ovarian cancer cells (A2780), the PEC micelles with LHRH exhibited enhanced cellular uptake compared to those without LHRH, resulting in increased VEGF gene silencing efficiency via receptor-mediated endocytosis. This study showed that PEC micelles decorated with specific cell-recognizable targeting ligands could be used for targeted delivery of siRNA.

Synthesis, characterization, and intracellular delivery of reducible heparin nanogels for apoptotic cell death.

Reducible heparin nanogels cross-linked with disulfide linkages were developed for efficient cellular uptake of therapeutic heparin to induce apoptotic cell death. The heparin nanogels were synthesized by forming nanocomplexes between thiolated heparin and poly(ethylene glycol) in a selected organic solvent, and subsequently producing intermolecular disulfide bonds between thiolated heparin molecules by ultrasonication. The resultant heparin nanogels had a stable structure with an average diameter of 248.7+/-26.8nm in aqueous solution. However, they rapidly disintegrated and released free heparin molecules under reductive environments, such as intracellular cytosol, through the cleavage of disulfide cross-links within their network structure. Confocal laser scanning microscopy and flow cytometric analysis revealed that these heparin nanogels significantly inhibited proliferation of mouse melanoma cells by inducing caspase-mediated apoptotic cell death. The present study suggested that the reducible heparin nanogels exhibiting a remarkable apoptotic activity could be potentially applied for cancer cell targeted delivery when combined with various therapeutic and diagnostic agents.

Water-free microencapsulation of proteins within PLGA microparticles by spray drying using PEG-assisted protein solubilization technique in organic solvent.

Poly(d,l-lactic-co-glycolic acid) (PLGA) microparticles encapsulating therapeutic proteins were prepared under a water-free formulation condition. Bovine serum albumin (BSA) and recombinant human growth hormone (rhGH) were homogeneously solubilized as nano-scale complexes in methylene chloride phase by using polyethylene glycol (PEG) as a complex-forming agent. The organic phase containing dissolved PLGA and PEG/protein complexes was directly spray dried to obtain PLGA microparticles encapsulating proteins. They exhibited sustained release profiles of BSA and rhGH up to 30 days with reduced initial bursts. The released protein molecules from the microparticles maintained structural integrity without aggregation, suggesting that the current single-step protein microencapsulation method without using water could be potentially applied for sustained delivery of a wide range of therapeutic protein drugs that are not soluble in organic solvents.

Direct plasmid DNA encapsulation within PLGA nanospheres by single oil-in-water emulsion method.

Plasmid DNA was encapsulated within poly(d,l-lactic-co-glycolic acid) (PLGA) nanospheres by using polyethylene glycol (PEG) assisted solubilization technique of plasmid DNA in organic solvents. Plasmid DNA was solubilized in an organic solvent mixture composed of 80% methylene chloride and 20% DMSO by producing PEG/DNA nano-complexes having an average diameter less than 100 nm. DNA could be solubilized in the organic solvent mixture to a greater extent with increasing the weight ratio of PEG/DNA. PLGA nanospheres encapsulating DNA were successfully prepared by the single O/W emulsion method. They exhibited greater loading efficiency and better structural integrity, compared to those prepared by the W/O/W double emulsion method. Plasmid DNA could be successfully delivered to macrophage cells to express an exogenous gene. This new formulation enabled high loading of intact plasmid DNA within PLGA nanospheres useful for DNA vaccines.