A rational combination is critical to achieve efficiently synergistic therapeutic efficacy for tumor treatment. Hence, we designed novel antitumor combinations (T-NPs) by integrating the tumor vascular and tumor cells dual-targeting ligand with antiangiogenesis/antitumor agents. The truncated bFGF peptide (tbFGF), which could effectively bind to FGFR1 overexpressed on tumor neovasculature endothelial cells and tumor cells, was selected to modify PLGA nanoparticles (D/P-NPs) simultaneously loaded with PEDF gene and paclitaxel in this study. The obtained T-NPs with better pharmaceutical properties had elevated cytotoxicity and enhanced expression of PEDF and α-tubulin on FGFR1-overexpressing cells. The uptake of T-NPs increased in C26 cells, probably mediated by tbFGF via specific recognization of the overexpressed FGFR1. T-NPs dramatically disrupted the tube formation of primary human umbilical vein endothelial cells (HUVECs) and displayed improved antiangiogenic activity in the transgenic zebrafish model and the alginate-encapsulated tumor cell model. More importantly, T-NPs achieved a markedly higher antitumor efficacy in the C26 tumor-bearing mice model. The antitumor effect involved the inhibition of tumor cell proliferation and angiogenesis, induction of apoptosis, and down-regulation of FGFR1. The enhanced antitumor activity of T-NPs probably resulted from the raised distribution in tumor tissues. In addition, T-NPs had no obvious toxicity as evaluated by weight monitoring, serological/biochemical analyses, and H&E staining. These results revealed that T-NPs, an active targeting gene/chemo-therapy, indeed had superior antitumor efficacy and negligible side effect, suggesting that this novel combination is a potential tumor therapy and a new treatment strategy and that the tbFGF modified nanoparticles could be applied to a wide range of tumor-genetic therapies and/or tumor-chemical therapies.Keywords: active targeting nanoparticles; codelivery; FGF receptors; paclitaxel; pigment epithelium-derived factor gene; truncated bFGF peptide

Combination treatment through simultaneous delivery of DNA and anticancer drugs with nanoparticles has been demonstrated to be an elegant and efficient approach for cancer therapy. Herein, we employed a combination therapy for eliminating both the tumor cells and intratumoral neovascular network based on the nanoplatform we designed. Pigment epithelium-derived factor (PEDF) gene, a powerful antiangiogenic agent, and the clinically widely used chemotherapy agent paclitaxel (PTX) were simultaneously encapsulated in the same nanoparticle by a modified double-emulsion solvent evaporation method. The dual-drug-loaded nanoparticles (D/P-NPs) exhibited a uniform spherical morphology and released PTX and PEDF gene in a sustained manner. D/P-NPs showed an enhanced antitumor effect on C26 and A549 cells and a stronger inhibitory activity on proliferation of HUVECs. Moreover, D/P-NPs could dramatically elevate the PEDF expression levels in both C26 and A549 cells in comparison with PEDF gene loaded nanoparticles and significantly promote the cellular uptake of PTX. Additionally, microtubules were stabilized and G2/M phase arrest along with a higher subG1 cell population was induced by D/P-NPs in contrast to PTX or PTX loaded nanoparticles. Besides, D/P-NPs showed sustained release of PTX and PEDF gene in tumors as well as long-term gene expression. A significantly improved anticancer effect was also demonstrated in a C26 subcutaneous tumor model using this combinational therapy. D/P-NPs could sharply reduce the microvessel density and significantly promoted tumor cell apoptosis in vivo. More importantly, the in vivo distribution, serological and biochemical analysis, and H&E staining revealed that D/P-NPs had no obvious toxicity. Our study suggested that this novel polymeric nanomedicine had great potential for improving the therapeutic efficacy of combined gene/chemotherapy of cancer.

The objective of this study was to investigate the potential of liposomes as an ophthalmic delivery system for brinzolamide (Brz) to enhance the local glaucomatous therapeutic effect. The liposomes of Brz (Brz-LPs) were produced by the thin-film dispersion method with a particle size of 84.33 ± 2.02 nm and an entrapment efficiency of 98.32 ± 1.61%. Differential scanning calorimetry (DSC) and X-ray powder diffraction (XRD) analysis proved that Brz was successfully entrapped into Brz-LPs. Brz-LPs displayed a biphasic release pattern in vitro with burst release initially and sustained release afterwards. The corneal permeability was measured using modified Franz-type diffusion cells, and Brz-LPs showed 6.2-fold increase in the apparent permeability coefficient when compared with the commercial available formulation (Brz-Sus). Moreover, Brz-LPs (1 mg/mL Brz) showed a more sustained and effective intraocular pressure reduction (5–10 mmHg) than Brz-Sus (10 mg/mL Brz) in white New Zealand rabbits. Therefore, Brz-LPs were a hopeful formulation of Brz for glaucoma treatment and worthy of further investigation.

•The brinzolamide HP-β-CD inclusion complex was prepared using a simple method.•BRZ inclusion complex showed higher cornea permeability than the AZOPT®.•Less BRZ in the inclusion complex has similar lowering IOP effect to the AZOPT®.Glaucoma is an accumulative optic neuropathy resulted from increasing intraocular pressure. Brinzolamide (BRZ) is a kind of carbonic anhydrase inhibitors for glaucoma treatment. In this study, brinzolamide-hydroxypropyl-β-cyclodextrin (BRZ-HP-β-CD) inclusion complex was prepared by solvent evaporation method to improve the solubility of BRZ and enhance the therapeutic effect of BRZ. The formation of the inclusion complex was confirmed by Fourier transform infrared spectroscopy, differential scanning calorimeter and nuclear magnetic resonance spectroscopy. The solubility of BRZ increased about 10-fold after the formation of the BRZ-HP-β-CD inclusion complex. The in vitro corneal accumulative permeability of the inclusion complex increased 2.91-fold compared to the commercial available formulation (AZOPT®). In addition, BRZ-HP-β-CD inclusion complex (0.5% BRZ) had an equivalent efficiency of lowering intraocular pressure with AZOPT® (1% BRZ) in vivo. These results identified the BRZ-HP-β-CD inclusion complex might have a promising future as a novel formulation of BRZ for glaucoma treatment.

In this paper, a novel chitosan-g-(-O-methyl poly (ethylene glycol))-g-(-N-Tat peptide) (CS-mPEG-Tat) copolymer was synthesized. The synthesized intermediates and final products were characterized and confirmed by Fourier transform infrared spectrum, 1H nuclear magnetic resonance spectrum, and X-ray diffraction, respectively. The particle sizes, size distributions, and zeta potentials can also be determined by dynamic light scattering. Agarose gel electrophoresis study showed effective DNA-binding ability of CS-mPEG-Tat. In vitro cytotoxicity assay indicated that CS-mPEG-Tat copolymers were low toxic and cell compatible as the polymer concentration was smaller than 5 mg/ml. This work provides a facile approach to prepare biocompatible PEG-peptide-chitosan copolymer nanoparticles with controllable performances. In conclusion, the obtained CS-mPEG-Tat copolymer might be attractive cationic polymers for nonviral gene therapy.

To promote the application of methoxy poly(ethylene glycol)-cholesterol (mPEG—Chol), mPEG–Chol was used to prepare core-shell micelles encapsulating poorly water-soluble docetaxel (DTX-PM) by modified cosolvent evaporation method. Approaches to enhance DTX entrapment efficiency (EE) and minimize particle size were investigated in detail, including organic and aqueous phase composition, organic/aqueous phase ratio, and polymer concentration. In optimal formulation, micelles had higher EE (97.6%) and drug loading (4.76%) with the diameter of 13.76 ± 0.68 nm and polydispersity index of 0.213 ± 0.006. Transmission electron microscopy (TEM) showed that the micelles were spherical, and differential scanning calorimetry (DSC) analysis proved that DTX was successfully entrapped into mPEG–Chol micelles. The in vitro cytotoxicity experiments displayed that blank micelles had no effect on the growth of SKOV-3, BXPC-3, A549, and HepG-2 cells, demonstrating that mPEG–Chol was one of the biocompatible biomaterials. The half inhibition concentration of DTX-PM on SKOV-3, BXPC-3, A549, and HepG-2 cells were 10.08, 7.6, 28.37, and 125.75 ng/mL, respectively. DTX-PM had the similar antitumor activity to free DTX, indicating that mPEG–Chol was a promising micellar vector for hydrophobic drug delivery. In addition, this work provided a new and facile approach to prepare drug-loaded micelles with controllable performances. © 2012 Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 102:1054–1062, 2013