Raman Spectroscopy Used to Detect Radiation Damage in Cells and Tissues During Cancer Treatment at the University of British Columbia

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The Irving K. Barber School of Arts and Sciences at the University of British Columbia, in Canada, hosts a multidisciplinary group of physics, engineering, and radiation oncology scientists.

The Irving K. Barber School of Arts and Sciences at the University of British Columbia, in Canada, hosts a multidisciplinary group of physics, engineering, and radiation oncology scientists. It is interested in detecting and understanding damage in cells and tissues due to ionizing radiation used in cancer treatments. Currently the dose a patient receives is prescribed based on population averages and does not take individual patient radio sensitivity into account. The ultimate aim of the group is to help personalize prescriptions based on an individual's response to radiation.

In some cases, it is possible to use Raman spectroscopic techniques to detect radiation damage in patients. The group is conducting research to find out if it is possible to make an early detection tool based on Raman spectroscopy, either prior to first treatment or within the first few fractions of treatment.

Associate Professor Andrew Jirasek is a physicist by training who has specialized in how to accurately measure radiation treatments for cancer patients. Together with his colleagues, Jirasek was the first to apply Raman spectroscopy to look at the unique cellular changes that occur following radiation. He says, “This is a very powerful technique. We can record and analyze information about how the molecules and cellular constituents change throughout treatment.” Dosage can then be adjusted to be more precise and targeted. He continues, “Previously, the only outcome of treatment was disease status; for example, tumor size. Our hope is that Raman analysis will provide accurate treatment evaluation sooner. Like many other diseases, timing with cancer treatment is everything. The sooner successful therapy is implemented, the better for the patient.” After conducting cell and animal model experiments, the group is now at the point of testing the system on prostate cancer patients.

Describing the choice of the Renishaw inVia Raman microscope for this work, Dr Jirasek said, “We chose the inVia for multiple reasons. The system delivers excellent Raman sensitivity and throughput. It also offers us high potential for automation. Because the system is used by multiple groups and types of users, ease of use is important to maximise our "up time." With several users not being experts in Raman, we have appreciated the excellent customer service support we have had from Renishaw.”

Dr Jirasek's work has been well reported and has recently appeared in several publications as well as presentations at conferences. Notable among these include “A Raman spectroscopic study of cell response to clinical doses of ionizing radiation” (1) and “Raman spectroscopy identifies radiation response in human non-small cell lung cancer xenografts” (2). 

References

  • Harder et al: "A Raman Spectroscopic Study of Cell Response to Clinical Doses of Ionizing Radiation," Applied Spectroscopy 69, 2, 2015.

  • Harder et al: "Raman spectroscopy identifies radiation response in human non- small cell lung cancer xenografts" Scientific Reports, 6:21006, DOI: 10.1038/srep21006.

 

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