Preparation and characterization of 3D human glioblastoma spheroids using an N-octanoyl glycol chitosan hydrogel.

The current 2D culture model systems developed for drug screening are not sufficient to reflect the characteristics of in vivo solid tumors. Therefore, more effective in vitro tumor model systems must be developed for translational studies on therapeutic drug screening and testing. Herein, we report a new ultra-low adhesion (ULA) hydrogel for generating 3D cancer cell spheroids as tumor models in vitro. N-octanoyl glycol chitosan (OGC) was synthesized and coated onto the surface of a typical cell culture dish. Cell spheroids were effectively formed on the OGC-coated surface, and phenotypes of the tumor cells were well maintained during culture. More importantly, U373-MG cells cultured on OGC-coated plates were more resistant to doxorubicin than cells cultured on typical plates. Our OGC-based ULA system may offer a convenient method for 3D cell culture to provide enhanced performance in cancer research, drug screening and toxicology.

Multistimuli-Responsive Polymeric Vesicles for Accelerated Drug Release in Chemo-photothermal Therapy.

Multistimuli-responsive nanomedicines present great potential for cancer therapy, as they can be featured as simple, selective, and smart carriers that can release their payload on-demand. In this study, we prepared a multifunctional polymeric vesicular nanocarrier (PVN) based on robust and triple stimuli-responsive micelles that could encapsulate chemotherapeutic drugs (doxorubicin (DOX)) and photothermal agents (IR780 iodide) for combined chemo-photothermal therapy. The size of the PVNs was stable and uniform (∼100 nm), and its DOX and IR780 loading were high: 26.5 and 16.4 wt %, respectively. Further in vitro investigations suggested that the DOX/IR780 coloaded PVNs presented controlled drug release kinetics upon costimulation with specific endogenous stimuli. Upon laser irradiation, DOX/IR780 coloaded PVNs exhibited prominent photothermal cytotoxicity toward murine colon cancer (CT-26) cells. Intracellular uptake assays indicated that DOX/IR780 coloaded PVNs could be readily uptaken by CT-26 cells, resulting in the release of DOX within the cytoplasm of the cells in response to laser irradiation.

Multifunctional Nanorobot System for Active Therapeutic Delivery and Synergistic Chemo-photothermal Therapy.

Nanorobots are safe and exhibit powerful functionalities, including delivery, therapy, and diagnosis. Therefore, they are in high demand for the development of new cancer therapies. Although many studies have contributed to the progressive development of the nanorobot system for anticancer drug delivery, these systems still face some critical limitations, such as potentially toxic materials in the nanorobots, unreasonable sizes for passive targeting, and the lack of several essential functions of the nanorobot for anticancer drug delivery including sensing, active targeting, controlling drug release, and sufficient drug loading capacity. Here, we developed a multifunctional nanorobot system capable of precise magnetic control, sufficient drug loading for chemotherapy, light-triggered controlled drug release, light absorption for photothermal therapy, enhanced magnetic resonance imaging, and tumor sensing. The developed nanorobot system exhibits an in vitro synergetic antitumor effect of photothermal therapy and chemotherapy and outstanding tumor-targeting efficiency in both in vitro and in vivo environments. The results of this study encourage further explorations of an efficient active drug delivery system for cancer treatment and the development of nanorobot systems for other biomedical applications.

IR 780-loaded hyaluronic acid micelles for enhanced tumor-targeted photothermal therapy.

In this study, we propose using IR 780-loaded, CD44-targeted hyaluronic acid-based micelles (HA-IR 780) for enhanced photothermal therapy (PTT) effects in tumors. Two kinds of HA-C18 micelles were synthesized from different C18 feed ratios with degree of substitution of 3% and 13% respectively. Three different IR 780 weight percentages were used for micelle formation with loading content of 4.6%, 7.9%, and 10.3% respectively. The IC50 value of HA-IR 780 in TC1 cells was 21.89µgmL-1 (32.81µM). Upon irradiation of the tumor site with an 808-nm laser (2Wcm-2) for 2min, the temperature in the tumor in the HA-IR 780-treated groups reached 49.9°C which exceeds the temperature threshold to induce irreversible tissue damage. Toxicity studies showed that HA-IR 780 does not cause any adverse effects in organs, including heart, liver, lungs, kidney and spleen, although it selectively caused cell damage in the tumor region upon laser irradiation. Therefore, the present study suggests that HA-IR 780 can cause selective cell death in tumor regions due to its enhanced tumor-targeting and photothermal capabilities.

PEGylated polyethylenimine for in vivo local gene delivery based on lipiodolized emulsion system.

Polyethylenimine (PEI) is one of the most efficient vectors for non-viral gene delivery, whereas its poor transfection activity, compared to viral vectors, and cytotoxicity need to be improved for in vivo applications. In this study, we prepared two PEI conjugates with 6 and 10 wt.% of poly(ethylene glycol) (PEG) grafts (referred to PEI-PEG-6 and PEI-PEG-10, respectively) in order to investigate the effects of PEGylation on cytotoxicity and transfection activity in vitro. In addition, their suitability as vectors for local gene delivery in vivo was assessed by injecting lipiodolized emulsions containing polymer/DNA complexes into the femoral artery of Sprague-Dawley (SD) rats, occluded by a surgical suture to block inflow of the blood to the leg. Both PEGylated PEIs showed significantly lower cytotoxicity and higher transfection activity in COS-1 cells than PEI taken as a control; in particular, PEI-PEG-10 produced the most promising results. The stable water-in-oil emulsion, composed of aqueous domains containing the complexes and lipiodol as an oil phase, was formed in the presence of a hydrogenated castor oil. From in vivo experiments, it was found that all the complexes, dispersed in the lipiodolized emulsion, delivered effectively gene to muscle, surrounding the injection site, rather than other organs such as liver, spleen, kidney, heart and lung. The in vivo transfection activity of PEI-PEG-10 was 3-folds higher in muscle than that of PEI. Based on these results, it can be concluded that PEGylated PEIs (based on the lipiodolized emulsion system) hold a promising potential for local gene delivery in vivo.