U of G researchers work to improve cancer treatments

Cancer treatment may become more effective thanks to University of Guelph physicists who have developed an innovative way to accurately target radiation therapy.

Radiation therapy aims beams of intense energy at a tumour to kill cancer cells. But if the ultranarrow beam is aimed inaccurately, it can hit healthy cells and “underdose” the target tumour.

Led by Dr. Dennis Mücher, a professor in the Department of Physics, U of G researchers have come up with a technique called a “hadron tumour marker” to make proton radiation therapy more accurate.

The implications of these findings for human cancer therapy are huge

They tested the technique at TRIUMF, Canada’s national laboratory for nuclear and medical physics in Vancouver.

Cancer is the leading cause of death in Canada and half of all cancer patients are treated with radiation therapy.

Cancer radiation therapy using ions, including charged particles such as protons, has become more widespread because it can target tumours and cancer cells with great precision. That makes it especially useful for treating cancers in delicate tissues like the eyes, brain or spinal cord.

In a separate study, U of G scientists harnessed tumour-killing viruses that may one day help treat devastating forms of breast, brain and pancreatic cancer.

We wake up the immune system

A research team led Dr. Sam Workenhe has shown for the first time that a one-two punch of cancer-killing viruses and chemotherapy can help trigger tumour inflammation, stimulating the body’s immune system to control tumour growth.

Workenhe, a professor in the Department of Pathobiology, said the study may ultimately help doctors enlist patients’ immune systems to fight cancers with especially poor treatment outcomes from conventional surgery, chemotherapy or radiation.

“The implications of these findings for human cancer therapy are huge,” he said. “We wake up the immune system.”

Leave a Reply

Your email address will not be published. Required fields are marked *

This site uses Akismet to reduce spam. Learn how your comment data is processed.