Cutting-Edge Imaging Pinpoints Where and When Hemorrhagic Stroke Has Occurred

Hemorrhagic stroke, where a weakened vessel in the brain ruptures, can lead to permanent disability or death. Across the globe, over 15 million people are coping with its effects. Time is of the essence when it comes to stroke; the sooner doctors can start treatment, the better the odds they can limit damage. Now, a new study has moved us one step closer to identifying when the bleeding associated with a hemorrhagic stroke starts - critical information for improving patient outcomes.

Using the Mid-IR beamline at the Canadian Light Source (CLS) at the University of Saskatchewan (USask, Saskatoon, Canada), the research team examined brain tissue samples with a special technique called Fourier-transform infrared imaging. The novel approach enabled the researchers to identify changes in the brain specific to hemorrhagic stroke. According to the researchers, the combination of the beamline and infrared imaging made it easy to detect markers of brain damage caused by hemorrhagic stroke.

With synchrotron technology, the team could see where a bleed originated and the extent of oxidative damage it caused – something impossible to do with a microscope or traditional approaches to imaging. Armed with this new approach, and a better understanding of what they are looking for, the researchers will now go back through their extensive “library” of stroke tissue samples to gain a clearer picture of the speed at which oxidative damage begins to ramp up. The team’s findings could eventually enable doctors to use clinical imaging – such as MRI or CT scans – to pinpoint where, and how long ago, a hemorrhagic stroke occurred in the brain. Knowing when bleeding has started can provide clinicians with a clearer picture of the time window they have to act.

“In a sense, this is giving us ‘superhuman vision’ to look at these brains and map out what’s happening metabolically,” said Dr. Jake Pushie, a member of the research team at USask’s College of Medicine.

“Being able to understand what is going on biologically, when we see any kinds of changes in the clinical images, could help doctors provide better care when it comes to minimizing the tissue damage associated with stroke,” added Miranda Messmer, another member of the research team.

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University of Saskatchewan

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