Tuesday, 13 August 2013

Tumour 'fingerprinting' may help treat bowel cancer

Scientists have found that it is possible to see how advanced a bowel cancer is by looking at its metabolic 'fingerprint'.

Bowel cancer is the third most common type of cancer globally, with over one million new cases diagnosed every year. Accurately determining the stage that a tumour has reached is crucial for deciding which treatments to offer. Metabolic fingerprinting looks at the levels of many different metabolites, which are the products of chemical reactions in the body's cells, in a sample of blood, urine or tissue. This mix of metabolites alters as cancer develops and grows.

The researchers behind the new study, from Imperial College London, suggest that doctors could use metabolic fingerprinting alongside existing imaging technology to give them the most accurate possible analysis of a tumour.

Doctors currently use a combination of CT, MRI and ultrasound scanning to evaluate how advanced a tumour is, but as these scans rely on visual estimations of a tumour's size and location, they are not always sufficiently sensitive or specific. Previous studies have shown that these techniques regularly suggest that a tumour is more advanced, or less advanced, than it really is.

"Working out the stage of a tumour is critical for planning a patient's treatment. Increasingly, before we surgically remove a tumour, we will give therapies to try and shrink it down, but the kinds of therapies we offer depend on our assessment of how advanced that tumour is," said Dr Reza Mirnezami, the lead author of the study from the Department of Surgery and Cancer at ICL. "The more accurate we can be, the better the patient's chances of survival. Our research suggests that using metabolic fingerprinting techniques in addition to scanning could give us the clearest possible picture of how the cancer is progressing," Mirnezami said.

For the new study, researchers analysed the metabolic fingerprint of 44 bowel tumour tissue samples, provided by patients at Imperial College Healthcare NHS Trust, using high-resolution magic angle spinning nuclear magnetic resonance spectroscopy (HR-MAS NMR).

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