Efficient Induction of Apoptosis in Lung Cancer Cells Using Bismuth Sulfide Nanoparticles.

Background: The use of nanomaterial-based radiosensitizers to improve the therapeutic ratio has gained attraction in radiotherapy. Increased radiotoxicity applied to the tumor region may result in adverse impact on the unexposed normal cells to the radiation, a phenomenon known as radiation-induced bystander effect (RIBE). Objectives: This study aimed to investigate the effect of Bi2S3@BSA nanoparticles (NPs) as radiosensitizers on the enhancement of bystander response in non-irradiated cells. Materials and Methods: Lung carcinoma epithelial cells were exposed to 6 MV x-ray photons at different doses of 2 and 8 Gy, with and without Bi2S3@BSA NPs. The irradiated-cell's conditioned medium (ICCM) was collected and incubated with MCR-5 human fetal lung fibroblasts. Results: This study showed that ICCM collected from 2-Gy-irradiated A549 cells in the presence of Bi2S3@BSA NPs reduced the cell viability of MCR-5 bystander cells more than ICCM collected from irradiated cells without NPs (P<0.05), whereas such a difference was not observed after 8-Gy radiation. The mRNA expression of the BAX and XPA genes, as well as the cell death rate in MCR-5 bystander cells, revealed that the Bi2S3@BSA NPs significantly improved bystander response at 2-Gy (P<0.05), but the efficacy was not statistically significant after 8-Gy Irradiation. Conclusion: The results indicated that the presence of NPs did not affect bystander response enhancement at higher concentrations. These findings highlighted the potential use of radiation-enhancing agents and their benefits in radiotherapy techniques with high doses per fraction.

Radio-sensitivity enhancement in HT29 cells through magnetic hyperthermia in combination with targeted nano-carrier of 5-Flourouracil.

Normal tissue complication and development of radioresistance in cancer cells are known as the main challenges of ionizing radiation treatment. In the current study, we intended to induce selective radiosensitization in HT29 cancer cells by developing folic acid modified magnetic triblock copolymer nanoparticles as carrier of 5-Flourouracil (5-FU) which was further used in combination with hyperthermia. The aforementioned nanoparticles were synthesized and characterized by differential scanning calorimetric analysis (DSC), UV-visible spectroscopy, dynamic light scattering (DLS), zeta sizer, and transmission electron microscopy (TEM). These nanoparticles were also assessed to determine drug loading capacity (DLC %) and drug release profile. The cytotoxicity of nanoparticles was evaluated on two different cell lines: HUVEC and HT29. Furthermore, radiosensitivity induction of the nanoparticles with and without exposure of alternative magnetic field was investigated. MTT-based cytotoxicity assay demonstrated that the therapeutic ratio was enhanced in response to using 5-FU-loaded nanoparticles as compared to 5-FU. Various characterizations including gene expression study, measurement of reactive oxygen species (ROS) generation, Annexin V/PI staining, and clonogenic assay revealed that ionizing radiation in combination with hyperthermia in the presence of the synthesized nanoparticles led to maximal anti-cancer effects as compared to other single (P < 0.001) and combined treatments (P < 0.01). Our results suggested that combined treatment based on using folic acid modified magnetic copolymer nanoparticle as carrier of 5-FU accompanied with hyperthermia could be proposed as an efficient approach to enhance radiation effects in cancer cells.

Magnetic Hyperthermia as an adjuvant cancer therapy in combination with radiotherapy versus radiotherapy alone for recurrent/progressive glioblastoma: a systematic review.

INTRODUCTION: Hyperthermia therapy (HT) is a recognized treatment modality, that can sensitize tumors to the effects of radiotherapy (RT) and chemotherapy by heating up tumor cells to 40-45 °C. The advantages of noninvasive inductive magnetic hyperthermia (MH) over RT or chemotherapy in the treatment of recurrent/progressive glioma have been confirmed by several clinical trials. Thus, here we have conducted a systematic review to provide a concise, albeit brief, account of the currently available literature regarding this topic. METHODS: Five databases, PubMed/Medline, Embace, Ovid, WOS, and Scopus, were investigated to identify clinical studies comparing overall survival (OS) following RT/chemotherapy versus RT/chemotherapy + MH. RESULTS: Eleven articles were selected for this systematic review, including reports on 227 glioma patients who met the study inclusion criteria. The papers included in this review comprised nine pilot clinical trials, one non-randomized clinical trial, and one retrospective investigation. As the clinical trials suggested, MH improved OS in primary glioblastoma (GBM), however, in the case of recurrent glioblastoma, no significant change in OS was reported. All 11 studies ascertained that no major side effects were observed during MH therapy. CONCLUSION: Our systematic review indicates that MH therapy as an adjuvant for RT could result in improved survival, compared to the therapeutic outcomes achieved with RT alone in GBM, especially by intratumoral injection of magnetic nanoparticles. However, heterogeneity in the methodology of the most well-known studies, and differences in the study design may significantly limit the extent to which conclusions can be drawn. Thus, further investigations are required to shed more light on the efficacy of MH therapy as an adjuvant treatment modality in GBM.

Malignancy probability map as a novel imaging biomarker to predict malignancy distribution: employing MRS in GBM patients.

The main aim of this study was to propose a new statistical method for evaluation of spatial malignancy distribution within Magnetic Resonance Spectroscopy (MRS) grid in Glioblastoma Multiforme patients. Voxels with different malignancy probabilities were presented as a novel MRS-based Malignancy Probability Map (MPM). For this purpose, a predictive probability-based clustering approach was developed, including the two following steps: (1) Gaussian Mixture Model, (2) Quadratic Discriminate Analysis coupled with Genetic Algorithm. Clustered probability values from two methods were then integrated to exploit the MPM. Results show that the suggested method is able to estimate the malignancy distribution with over 90% sensitivity and specificity. The proposed MRS-based MPM has an acceptable accuracy for providing useful complementary information about regional diffuse glioma malignancy, with the potential to lead to better detection of tumoral regions with high probability of malignancy. So, it also may encourage the use of additional information of this map as a tool for dose painting.