Huricha Baigude

Inorganic Nanovehicle for Potential Targeted Drug Delivery to Tumor Cells, Tumor Optical Imaging

In this work, an inorganic multifunctional nanovehicle was tailored as a carrier to deliver anticancer drug for tumor optical imaging and therapy. The nanovehicle could be used as a dually targeted drug nanovehicle by bonded magnetical (passive) and folic acid (active) targeting capabilities. In addition, it was developed using rhodamine 6G (R6G) as a fluorescence reagent, and an α-zirconium phosphate nanoplatform (Zr(HPO4)2·H2O, abbreviated as α-ZrP) as the anticancer drug nanovehicle. The novel drug-release system was designed and fabricated by intercalation of α-ZrP with magnetic Fe3O4 nanoparticles and anticancer drug 5-fluorouracil (5-FU), followed by reacting with a folate acid-chitosan-rhodamine6G (FA-CHI-R6G) complex, and then α-ZrP intercalated with Fe3O4 nanoparticles and 5-fluorouracil (5-FU) was successfully encapsulated into chitosan (CHI). The resultant multifunctional drug delivery system was characterized by scanning electron microscopy, X-ray diffraction, energy-dispersive X-ray analysis, photoluminescence spectra, magnetometry, fluorescence microscopy imaging studies and other characterization methods. Simultaneously, the drug release in vitro on the obtained nanocomposites that exhibited a sustained release behavior was carried out in buffer solution at 37 °C, which demonstrated clearly that the nanocomposites shown a sustained release behavior. Meanwhile, cell culture experiments also indicated that the drug-release system had the potential to be used as an dually targeted drug nanovehicle into the tumor cells.

Fabrication of functional hollow microspheres constructed from MOF shells: Promising drug delivery systems with high loading capacity and targeted transport

An advanced multifunctional, hollow metal-organic framework (MOF) drug delivery system with a high drug loading level and targeted delivery was designed and fabricated for the first time and applied to inhibit tumour cell growth. This hollow MOF targeting drug delivery system was prepared via a simple post-synthetic surface modification procedure, starting from hollow ZIF-8 successfully obtained for the first time via a mild phase transformation under solvothermal conditions. As a result, the hollow ZIF-8 exhibits a higher loading capacity for the model anticancer drug 5-fluorouracil (5-FU). Subsequently, 5-FU-loaded ZIF-8 was encapsulated into polymer layers (FA-CHI-5-FAM) with three components: a chitosan (CHI) backbone, the imaging agent 5-carboxyfluorescein (5-FAM), and the targeting reagent folic acid (FA). Thus, an advanced drug delivery system, ZIF-8/5-FU@FA-CHI-5-FAM, was fabricated. A cell imaging assay demonstrated that ZIF-8/5-FU@FA-CHI-5-FAM could target and be taken up by MGC-803 cells. Furthermore, the as-prepared ZIF-8/5-FU@FA-CHI-5-FAM exhibited stronger cell growth inhibitory effects on MGC-803 cells because of the release of 5-FU, as confirmed by a cell viability assay. In addition, a drug release experiment in vitro indicated that ZIF-8/5-FU@FA-CHI-5-FAM exhibited high loading capacity (51%) and a sustained drug release behaviour. Therefore, ZIF-8/5-FU@FA-CHI-5-FAM could provide targeted drug transportation, imaging tracking and localized sustained release.

PEGylation of 6-amino-6-deoxy-curdlan for efficient in vivo siRNA delivery

RNA interference (RNAi) is an evolutionarily conserved gene-silencing phenomenon that shows great promise for developing new therapies. However, the development of small interfering RNA (siRNA)-based therapies need to establish efficient delivery system that silences target genes with siRNA doses that is clinically feasible in humans. Here we report synthesis and in vivo study of a novel PEGylated curdlan-based nanoparticle, designated as 6AC-100PEG, obtained by conjugation of mPEG 2000 to 6-amino-6-deoxy-curdlan. The complex of siRNA/6AC-100PEG showed homogenous nanoparticles with an average diameter of 200nm. MTT assay indicated that 6AC-100PEG does not have apparent cytotoxicity. Systemic administration of a complex of siapoB/6AC-100PEG significantly reduced the level of apoB mRNA in mouse liver, indicating that 6AC-100PEG can efficiently deliver siRNA to mouse liver and induce RNAi. Administration of siRNA/6AC-100PEG to mouse did not elevate liver enzyme level in the serum, indicating that 6AC-100PEG nanoparticle is a promising in vivo siRNA delivery agent.

Cell Type-Specific Delivery of RNAi by Ligand-Functionalized Curdlan Nanoparticles: Balancing the Receptor Mediation and the Charge Motivation

Tissue-specific delivery of therapeutic RNAi has great potential for clinical applications. Receptor-mediated endocytosis plays a crucial role in targeted delivery of biotherapeutics including short interfering RNA (siRNA). Previously we reported a novel Curdlan-based nanoparticle for intracellular delivery of siRNA. Here we designed a nanoparticle based on ligand-functionalized Curdlan. Disaccharides were site-specifically conjugated to 6-deoxy-6-amino Curdlan, and the cell line specificity, cellular uptake, cytotoxicity, and siRNA delivery efficiency of the corresponding disaccharide-modified 6-deoxy-6-amino-Curdlan were investigated. Observation by fluorescence microscopy as well as flow cytometry showed that galactose-containing Curdlan derivatives delivered fluorescently labeled short nucleic acid to HepG2 cells expressing ASGPR receptor but not in other cells lacking surface ASGPR protein. Moreover, highly galactose-substituted Curdlan derivatives delivered siRNA specifically to ASGPR-expressing cells and induced RNAi activities, silencing endogenous GAPDH gene expression. Our data demonstrated that galactose-functionalized 6-deoxy-6-amino-Curdlan is a promising carrier for short therapeutic nucleic acids for clinical applications.

Design of Highly Potent Lipid-Functionalized Peptidomimetics for Efficient in Vivo siRNA Delivery.

RNA interference (RNAi) is a highly efficient approach for gene silencing. Regulation of gene expression at post-transcriptional level provides great potential for curing diseases caused by abnormal overexpression of disease-related genes. However, the application of RNAi in the clinic has been hindered by the lack of efficient and biocompatible delivery systems. Therefore, the development of a safe and tissue-targeted double-stranded interfering RNA (siRNA) carrier for clinical application is urgently needed. Here we report the discovery of a highly efficient liposomal siRNA delivery agent based on a novel peptidomimetic built from natural amino acids. Fine tuning of the composition of amino acids, the type of amide linkage in the peptidomimetic, as well as the formulation and the physicochemical parameters of the novel lipoplex resulted in a lipid nanoparticle (LNP) that efficiently encapsulates and carries siRNA to mouse liver. In vivo experiments showed that a single injection of unmodified siRNA complexed to one of the peptidomimetics at a clinically feasible dose induced significant RNAi in mouse liver, resulting in a 90% decrease in apolipoprotein B (ApoB) mRNA level, as well as a 60% decrease in serum ApoB protein level. Analysis of mouse serum by ELISA indicated that the novel peptidomimetic based lipoplex did not elevate the level of liver enzymes (ALT, AST) in the serum. Our novel peptidomimetic-based lipoplex demonstrated great potential for the development of a safe and efficient siRNA delivery agent for clinical applications.

LC analysis and pharmacokinetic study of synthetic piperlonguminine in rat plasma after oral administration

Only one kind of synthesized alkaloid, piperlonguminine, was used to understand the interference of the other alkaloids in pharmacokinetic study using HPLC/UV in rat plasma after oral administration. Compared with the previous report, it was clarified that mixed alkaloids such as piperine and the other extract from Piper longum Linn did not interfere with the results.

Efficient in vivo siRNA delivery by stabilized D-peptide-based lipid nanoparticles

RNA interference (RNAi) has shown great potential for clinical treatment of a variety of diseases. As an effective post-transcriptional regulation, RNAi induces degradation of specific target mRNA, leading to a decreased level of disease related gene product, which could be resistant to conventional small molecule therapeutics. Because of the relatively small size of short interfering RNA (siRNA) as well as its robustness in the design of efficient 20–22 nucleotide sequences targeting any known gene, delivery of siRNA in vitro and in vivo has achieved tremendous success by the design and fabrication of various carrier materials including peptides, lipids, and polymers. While siRNA delivery efficiency of these materials proved to be appreciable, their tissue specificity, biocompatibility and cytotoxicity still need much improvement. We report a novel siRNA delivery material designed by optimization of our previously reported peptidomimetic based lipoplex. The novel lipoplex, which bears a D-amino acid based dipeptide head group, possesses an ideal balance of increased stability in a tissue environment, and enhanced efficiency of tissue specific delivery as well as minimized cytotoxicity. The novel lipoplex carrying siRNA efficiently targeted mouse liver, initiated RNAi and knocked down the apoB dose dependently, which is confirmed by both RT-qPCR and Western blotting. Moreover, the novel lipoplex does not induce any apparent cytotoxicity, as confirmed by the measurement of liver enzyme levels in serum.

“Click” chemistry mediated construction of cationic curdlan nanocarriers for efficient gene delivery

A cationic group has been quantitatively and selectively introduced into C6 position of each glucose units of Curdlan by Click Chemistry successfully. The resulting cationic Curdlan-Imidazole-lysine polymers (Cur-6-100Lys) exhibit excellent water solubility. Structure of the Cur-6-100Lys complexes was verified by FTIR and NMR spectroscopic measurements, and analysis of Cur-6-100Lys by GPC, DLS and SEM revealed that they have stoichiometric, nanosized spheroidal structures. Cytotoxicity measurement, electrophoretic mobility shift assay and EGFP-pDNA transfection have been carried out respectively. The results clearly show that Cur-6-100Lys nanocarriers have bound to dsDNA promptly, are less cytotoxic to both 7901 cells and HeLa cells, and are readily able to transport EGFP-pDNA into HepG2 cells. Our studies indicated that Cur-6-100Lys can potentially be used as a versatile nano platform for efficient gene delivery in living cells.

Design of Mannose-Functionalized Curdlan Nanoparticles for Macrophage-Targeted siRNA Delivery

6-Amino-6-deoxy-curdlan is a promising nucleic acid carrier that efficiently delivers plasmid DNA as well as short interfering RNA (siRNA) to various cell lines. The highly reactive C6-NH2 groups of 6-amino-6-deoxy-curdlan prompt conjugation of various side groups including tissue-targeting ligands to enhance cell-type-specific nucleic acid delivery to specific cell lines. Herein, to test the primary-cell-targeting efficiency of the curdlan derivative, we chemically conjugated a macrophage-targeting ligand, mannose, to 6-amino-6-deoxy-curdlan. The resulting curdlan derivative (denoted CMI) readily complexed with siRNA and formed nanoparticles with a diameter of 50-80 nm. The CMI nanoparticles successfully delivered a dye-labeled siRNA to mouse peritoneal macrophages. The delivery efficiency was blocked by mannan, a natural ligand for a macrophage surface mannose receptor (CD206), but not by zymosan, a ligand for the dectin-1 receptor, which is also present on the surface of macrophages. Moreover, CMI nanoparticles were internalized by macrophages only at 37 °C, suggesting that the cellular uptake of CMI nanoparticles was energy-dependent. Furthermore, CMI nanoparticle efficiently delivered siRNA against tumor necrosis factor α (TNFα) to lipopolysaccharide-stimulated primary mouse peritoneal macrophages. In vivo experiments demonstrated that CMI nanoparticles successfully delivered siTNFα to mouse peritoneal macrophages, liver, and lung and induced significant knockdown of the TNFα expression at both messenger RNA and protein levels. Therefore, our design of CMI may be a promising siRNA carrier for targeting CD206-expressing primary cells such as macrophage and dendritic cells.

Synthesis of amphoteric curdlan derivatives for delivery of therapeutic nucleic acids

Cationic polymers are powerful carriers for intracellular delivery of therapeutic nucleic acids. However, the positively charged macromolecules have considerable cytotoxicity and often induce irreversible damages to the cells and tissues, which greatly negate the clinical application of such materials as drug delivery system. Herein, we report the synthesis of novel amphoteric polymers based on curdlan, and the evaluation of their cytotoxicity as well as the nucleic acid delivery efficiency. β-(1,3)-polyglucuronic acid, a TEMPO-oxidized derivative of curdlan, was chemically modified by conjugation of tetraethylenepentamine. The resulting amphoteric polymers, denoted tetraethylenepentamine-curdlan (TEPAC) polymers have the degree of substitution (DS) ranging from 25% to 48%. The result of MTT assay indicated that TEPAC polymers have negligible cytotoxicity on HeLa cells and A549 cells. The novel amphoteric polymers efficiently bound with plasmid DNA and delivered pcDNA-eGFP plasmid to 293T cells and induced expression of GFP 48h after the transfection. Moreover, TEPAC polymers delivered siRNA to HeLa cells and HepG2 cells in high efficiency, and induced significant RNAi for the expression of an endogenous gene. Collectively, our data demonstrate that the novel curdlan-based amphoteric polymers are biocompatible and may provide a highly efficient system for the delivery of therapeutic nucleic acids.