Researchers Create Nanoparticles for Transporting Brain Cancer Therapy
University of Queensland researchers have developed a nanoparticle to take a chemotherapy drug into fast growing, aggressive brain tumors.
Research team lead Dr. Taskeen Janjua from UQ's School of Pharmacy said the new silica nanoparticle can be loaded with temozolomide, a small molecule drug used to treat tumors known as glioblastoma.
"This chemotherapy drug has limitations—it doesn't stay in the blood for very long, it can be pushed out of the brain, and it doesn't have high penetration from blood into the brain," Dr. Janjua said.
"To make the drug more effective, we developed an ultra-small, large pore nanoparticle to help it move through the blood-brain barrier and penetrate the tumor while also reducing unwanted patient side effects.
"This strategy could be a more effective way to treat brain cancer and prevent it from coming back."
The nanoparticle delivery was trialed using 3D spheroids, multi-cellular structures created to mimic the brain tumor cell responses and interactions.
The study results showed that in mice, the nanoparticles successfully accumulated in the brain within a few hours without any negative effects on vital organs.
Brain cancer affects thousands of people every year and the chances of surviving at least five years is less than 23%.
Cancer Australia data showed it was the ninth most common cause of cancer death in Australia in 2020.
Study co-author Associate Professor Amirali Popat said while there is still more research to be done, the results are promising for people with brain cancer.
"This innovative drug delivery system has the potential to improve the effectiveness of brain cancer treatment and could lead to new and better treatments for this devastating disease," Dr. Popat said.
"This preclinical research will accelerate future clinical development of a promising health technology and further the goal of improving outcomes for patients with brain cancer."
UQ School of Pharmacy researchers collaborated with colleagues from UQ's Australian Institute for Bioengineering and Nanotechnology and The University of New South Wales to deliver the research.