Glioblastoma is the most aggressive form of brain cancer.
Despite decades of major efforts and clinical trials, the tumour’s survival rate has remained stagnant.
For years, scientists understood the cells in these tumours as static and relatively fixed.
But recent studies have uncovered that glioblastomas contain active cells moving in complex patterns known as “oncostreams”, which determine how aggressively the tumours grow.
Research led by Michigan Medicine and the University of Michigan, published in Science Advances, suggests that glioblastoma cells are poised near a “critical point” of order and disorder — meaning, the cells possess some form of large-scale coordination throughout the whole tumour that allows them to respond in practical unison to attempts to kill tumour cells, such as chemotherapy or radiation.
“Many people imagine that tumours are made up of different, unconnected cells that invade the normal brain, but we are seeing patterns of organisation that show the tumour working almost like a single entity,” said senior author Pedro Lowenstein, M.D., Ph.D., Richard C. Schneider Collegiate Professor of Neurosurgery at U-M Medical School and member of the U-M Health Rogel Cancer Center.
“This large-scale coordination of brain tumour behaviour may allow tumour cells to resist better against therapies, such as chemotherapy and radiotherapy. Disrupting the large-scale organisation of brain tumours may result in more powerful ways to treat and one day eliminate brain tumours.”
The research team used time-resolved tracking of individual glioblastoma cells and investigated their movement by implanting genetically engineered NPA-green, fluorescent cells into the brains of mice.
Results of the study of the movement of glioma cells initially suggested that the cells may be moving independently.
But through examining cell populations of different sizes, researchers found correlated fluctuations across distances many times the size of a single cell, to close to the size of the whole tumour preparation for imaging tumour movement under a microscope.
“Our results indicate that beneath a weakly ordered façade, brain tumour assemblies actually have some form of collective behaviour on scales of millimeters or more,” said first author Kevin Wood, Ph.D., an associate professor in the Departments of Physics and Biophysics at U-M.
“The work demonstrates that collaboration between biologists and biophycisists working at the frontiers of neuro-oncology and physics can provide new avenues for understanding and potentially treating so far incurable cancers.”
Researchers say more research is needed before any clinical implications are determined.
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