About This Project

Survival rates for cancers have seen a 20% increase in the United States over the last thirty years, but brain cancer has not benefited from these increasing survival rates. Less than one out of every ten people diagnosed with Glioblastoma Multiforme (GBM) will survive. GBM remains incredibly hard to treat due to its tentacles that spread throughout the brain. We will be exploring the improvement of hyperthermia therapies using magnetic nanoparticles to increase its efficiency.

Ask the Scientists

What is the context of this research?

Survival rates for cancers have seen a 20% increase in the United States over the last thirty years, yet brain cancer has seen a 1% increase (CDC). Less than one out of every ten people diagnosed with Glioblastoma Multiforme (GBM) will survive (AIHW National Cancer Statistics). GBM remains incredibly hard to treat due to its tentacles that spread throughout the brain and are difficult to eradicate.

We will be exploring the improvement of hyperthermia therapies using magnetic nanoparticles to increase its efficiency. Hyperthermia therapies directly heat the tumor. The increase in temperature causes death of the cancerous tissue while leaving healthy tissue relatively unharmed. Magnetic nanoparticles, like iron and iron oxide, help improve the efficiency of this type of treatment.

What is the significance of this project?

Having this data is immediately valuable because it could determine what particles are best suited for hyperthermia therapies. The data will provide researchers with specific challenges to solve in order to improve these cancer treatments. We want to know what product works the best in order to take advantage of hyperthermia therapies. Knowing what works well will improve the efficacy and reduce side effects of currently untreatable glioblastomas. It will also provide an option to those who cannot or opt not to have surgery and/or radiation and chemotherapy treatments.

What are the goals of the project?

The main goal of this research is to characterize iron and iron oxide nanoparticles of various sizes and coatings to determine which commercially available products are best for hyperthermia treatments of cancer. Our secondary goal includes the synthesis of new iron nanoparticles by our research team tailoring them for use as a hyperthermia agent. These will be included in the study to determine if the nanoparticles developed by our research group have an advantage over what is currently available.