Multifunctional nanoparticles delivering small interfering RNA and doxorubicin overcome drug resistance in cancer.

Drug resistance is a major challenge to the effective treatment of cancer. We have developed two nanoparticle formulations, cationic liposome-polycation-DNA (LPD) and anionic liposome-polycation-DNA (LPD-II), for systemic co-delivery of doxorubicin (Dox) and a therapeutic small interfering RNA (siRNA) to multiple drug resistance (MDR) tumors. In this study, we have provided four strategies to overcome drug resistance. First, we formed the LPD nanoparticles with a guanidinium-containing cationic lipid, i.e. N,N-distearyl-N-methyl-N-2-(N'-arginyl) aminoethyl ammonium chloride, which can induce reactive oxygen species, down-regulate MDR transporter expression, and increase Dox uptake. Second, to block angiogenesis and increase drug penetration, we have further formulated LPD nanoparticles to co-deliver vascular endothelial growth factor siRNA and Dox. An enhanced Dox uptake and a therapeutic effect were observed when combined with vascular endothelial growth factor siRNA in the nanoparticles. Third, to avoid P-glycoprotein-mediated drug efflux, we further designed another delivery vehicle, LPD-II, which showed much higher entrapment efficiency of Dox than LPD. Finally, we delivered a therapeutic siRNA to inhibit MDR transporter. We demonstrated the first evidence of c-Myc siRNA delivered by the LPD-II nanoparticles down-regulating MDR expression and increasing Dox uptake in vivo. Three daily intravenous injections of therapeutic siRNA and Dox (1.2 mg/kg) co-formulated in either LPD or LPD-II nanoparticles showed a significant improvement in tumor growth inhibition. This study highlights a potential clinical use for the multifunctional nanoparticles with an effective delivery property and a function to overcome drug resistance in cancer. The activity and the toxicity of LPD- and LPD-II-mediated therapy are compared.

Enhanced intravenous transgene expression in mouse lung using cyclic-head cationic lipids.

Herein, we report enhanced intravenous mouse lung transfection using novel cyclic-head-group analogs of usually open-head cationic transfection lipids. Design and synthesis of the new cyclic-head lipid N,N-di-n-tetradecyl-3,4-dihydroxy-pyrrolidinium chloride (lipid 1) and its higher alkyl-chain analogs (lipids 2-4) and relative in vitro and in vivo gene transfer efficacies of cyclic-head lipids 1-4 to their corresponding open-head analogs [lipid 5, namely N,N-di-n-tetradecyl-N,N-(2-hydroxyethyl)ammonium chloride and its higher alkyl-chain analogs, lipids 6-8] have been described. In stark contrast to comparable in vitro transfection efficacies of both the cyclic- and open-head lipids, lipids 1-4 with cyclic heads were found to be significantly more efficient (by 5- to 11-fold) in transfecting mouse lung than their corresponding open-head analogs (5-8) upon intravenous administration. The cyclic-head lipid 3 with di-stearyl hydrophobic tail was found to be the most promising for future applications.

Targeted cancer therapy with novel high drug-loading nanocrystals.

A novel nanocrystal formulation of hydrophobic drugs has been developed for cancer therapy. The new method, called a three-phase nanoparticle engineering technology (3PNET), includes three phases: phase 1, amorphous precipitate; phase 2, hydrated amorphous aggregate; and phase 3, stabilized nanocrystal. The 3PNET has been applied to two anticancer drugs, paclitaxel (PTX) and camptothecin (CPT), using Pluronic F127 (F127) polymer as a single excipient. The nanocrystals encapsulated over 99% of the drug with a high ratio of drug to excipient. The nanocrystal formulation of PTX did not induce hemolysis at pharmacologically relevant concentrations. Antitumor activity in two tumor models, human lung cancer and murine breast cancer, demonstrated that intravenously injected nanocrystals significantly inhibited the tumor growth. The nanocrystals also showed significant therapeutic effects via oral administration. In addition, the nanocrystals could be further modified for targeted delivery of PTX by conjugating a folate ligand to F127. The new nanomedicine formulations show clear potential for clinical development because of the excellent antitumor activity, low toxicity, and the ease of scale-up manufacture. The formulation method may apply to other hydrophobic drugs.

Novel cationic lipid that delivers siRNA and enhances therapeutic effect in lung cancer cells.

We have developed lipid-polycation-DNA (LPD) nanoparticles containing DOTAP and targeted with polyethylene glycol (PEG) tethered with anisamide (AA) to specifically deliver siRNA to H460 human lung carcinoma cells which express the sigma receptor. A novel non-glycerol based cationic lipid which contains both a guanidinium and a lysine residue as the cationic headgroup, i.e. DSGLA, downregulated pERK more efficiently in H460 cells than DOTAP. As demonstrated by using fluorescently labeled siRNA, LPD-PEG-AA prepared with DSGLA efficiently delivered siRNA to the cytoplasm of the H460 cells. Although the siRNA delivered by LPD-PEG-AA containing either DOTAP or DSGLA could effectively silence EGFR expression, a synergistic cell killing effect in promoting cellular apoptosis was only observed with DSGLA. The fluorescently labeled siRNA was efficiently delivered into the cytoplasm of H460 xenograft tumor by the LPD-PEG-AA containing either DOTAP or DSGLA 4 h after intravenous injection. Three daily injections (0.6 mg/kg) of siRNA formulated in the LPD-PEG-AA containing either DOTAP or DSGLA could effectively silence the epidermal growth factor receptor (EGFR) in the tumor, but the formulation containing DSGLA could induce more cellular apoptosis. A significant improvement in tumor growth inhibition was observed after dosing with LPD-PEG-AA containing DSGLA. Thus, DSGLA served as both a formulation component as well as a therapeutic agent which synergistically enhanced the activity of siRNA.