Multimodal Applications of Zinc Gallate-Based Persistent Luminescent Nanoparticles in Cancer Treatment: Tumor Margining, Diagnosis, and Boron Neutron Capture Therapy.

On the basis of the boron neutron capture therapy (BNCT) modality, we have designed and synthesized a zinc gallate (ZnGa2O4)-based nanoformulation for developing an innovative theranostic approach for cancer treatment. Initially, the (ZnGa1.995Cr0.005O4 or ZnGa2O4:(0.5%)Cr persistent luminescence nanoparticles (PLNPs) embedded on silica matrix were synthesized. Their surface functionalization was performed using organic synthesis strategies to attach the amine functional moieties which were further coupled with poly(vicinal diol). These diols were helpful for conjugation with 10B(OH)3, which subsequently served to couple with an in-house-synthesized variant of pH-(low)-insertion peptide (pHLIP) finally giving a tumor-targeting nanoformulation. Most importantly, the polymeric diols helped in conjugation of a substantial number of 10B to provide the therapeutic dose required for effective BNCT. This nanoformulation internalized substantially (∼80%) to WEHI-164 cancer cells within 6 h. Tumor homing studies indicated that the accumulation of this formulation at the acidic tumor site was within 2 h. The in vitro evaluation of the formulation against WEHI-164 cancer cells followed by neutron irradiation revealed its potent cytotoxicity with IC50 ∼ 25 µM. In the case of studies on animal models, the melanoma-induced C57BL/6 and fibrosarcoma-induced BALB/c mice were treated with formulations through intratumoral and intravenous injections, respectively, followed by neutron irradiation, leading to a significant killing of the cancer cells, which was evidenced by a reduction in tumor volume (75-80%) as compared with a control tumor. Furthermore, the histopathological studies confirmed a damaging effect only on tumor cells, while there was no sign of damage to the vital organs in treated mice as well as in controls.

Noninvasive Preclinical Evaluation of Targeted Nanoparticles for the Delivery of Curcumin in Treating Pancreatic Cancer.

Conventional therapy regimens for pancreatic cancer (PC) are surgical resection and systemic gemcitabine based chemotherapy. Recent studies showed that curcumin could potentiate the anticancer effect of gemcitabine in PC. However, due to its poor water solubility, effective bioavailability of curcumin is insufficient, resulting in poor efficacy. To address this issue, mesoporous silica nanoparticles (MSN) were prepared by the sol-gel method, then loaded with curcumin (Cur), coated with polyethylene glycol (PEG), and finally conjugated with the targeting moiety transferrin (Tf) to target human PC cells. TEM analysis revealed that uniform sized spherical MSN formed with an average size of 100 nm, which increased to 120 nm after PEG coating on MSN surface. Confocal microscopy proved that curcumin uptake being seven-times higher for MSN-NH2-Cur-PEG-Tf, when compared to free curcumin. The in vitro cytotoxicity study on MIA PaCa-2 cells showed that MSN-NH2-Cur-PEG-Tf exhibited three-fold higher cytotoxicity than free curcumin. On the basis of the encouraging in vitro cytotoxicity results obtained, preclinical assessment of antitumor efficacy in MIA PaCa-2 subcutaneous xenograft model proves that both MSN-NH2-Cur-PEG and MSN-NH2-Cur-PEG-Tf inhibit tumor growth and minimize distant metastasis to major organ sites. The in vitro studies also proved that nanoparticles can enhance the sensitization effect, caused by curcumin on cancer cells, which help the gemcitabine to kill a higher percentage of cancer cells. Hence, we propose that transferrin targeted, PEGylated, mesoporous silica nanoparticles can be used as a carrier to deliver curcumin, and used in addition to gemcitabine to reduce disease burden significantly for pancreatic cancer patients.