Nano-loaded human umbilical cord mesenchymal stem cells as targeted carriers of doxorubicin for breast cancer therapy.

The main challenge of anticancer drugs is poor tumor targeting. Now cellular carriers are widely investigated to deliver anticancer agents. As an ideal cellular candidate, human umbilical cord derived mesenchymal stem cells (hUC-MSCs) possess inherent tropism potential to tumor. Here, we constructed hUC-MSCs carrying transferrin-inspired-nanoparticles that contain doxorubicin(hUC-MSCs-Tf-inspired-NPs) to achieve enhanced anti-tumor efficacy and made an evaluation. Results represented that hUC-MSCs-Tf-inspired-NPs not only exhibit the controlled-release property of Tf-inspired-NPs, but also integrate tumor tropism and penetrative abilities of MSCs. The tumor volume of nude mice bearing breast cancer MCF-7 treated with hUC-MSCs-Tf-inspired-NPs, was remarkably reduced compared to those treated with free drug or Tf-inspired-NPs. Thus, Tf-inspired-NPs loaded hUC-MSCs have a potential to deliver anticancer drugs.

Targeted delivery of doxorubicin by nano-loaded mesenchymal stem cells for lung melanoma metastases therapy.

Poor antigenic presentation of tumor tissues and a lack of specific targets currently limit the success of nanoparticle delivery system. Cellular carrier technique has been recently explored extensively as a substitutive or supplement for traditional targeting delivery system. Here, we demonstrate the usage of mesenchymal stem cells (MSCs) loaded with doxorubicin containing polymer nanoparticles in pulmonary melanoma metastases therapy, as a modified technique of targeted delivery system. The characterizations of prepared nanoparticles and MSCs sensitivity to DOX and PLGA-DOX were measured. In vitro tumor tropism, and in vivo distributions of nanoparticles loaded MSCs were also investigated. The findings have demonstrated that, the modified system not only integrates the controlled-release property of nanoparticles but also exhibits tumor tropism and penetrative characteristics of MSCs. Furthermore, the in vitro and in vivo anti-tumor study has demonstrated that drug loaded MSCs had potent efficacy in lung melanoma metastases treatment.

Mannosylated protamine as a novel DNA vaccine carrier for effective induction of anti-tumor immune responses.

Gene immunotherapy has been developed as a promising strategy for inhibition of tumor growth. In the study, mannosylated protamine sulphate (MPS) was used as a novel DNA vaccine carrier to enhance transfection efficiency and anti-tumor immune responses. Anti-GRP DNA vaccine (pGRP) was selected as a model gene and condensed by MPS to form MPS/pGRP nanoparticles. The cellular uptake and transfection efficiency of MPS/pGRP nanoparticles in macrophages were evaluated. The effect of the nanoparticles in enhancing GRP-specific humoral immune response was then evaluated by nasal vaccination of nanoparticles in mice. The results demonstrated that both the cellular uptake and transfection efficiency of MPS nanoparticles in macrophages were higher than those of protamine nanoparticles. MPS/pGRP nanoparticles stimulated the production of higher titers (3.9×10(3)) of specific antibodies against GRP than those of protamine/pGRP nanoparticles (6.4×10(2), p<0.01) and intramuscular injection pGRP solution (2.5×10(3), p<0.05). Furthermore, the inhibitory rate in MPS/pGRP nanoparticles group (65.80%) was significantly higher than that in protamine/pGRP nanoparticles group (35.13%) and pGRP solution group (43.39%). Hence, it is evident that MPS is an efficient targeting gene delivery carrier which could improve in vitro transfection efficiency as well as anti-tumor immunotherapy in mice.