New artificial intelligence model reveals invisible multiple sclerosis lesions
· News-MedicalOne of the uncomfortable truths about multiple sclerosis is that the part of the brain likely to reveal the most about the disease and how a patient will be impacted has been mostly invisible to clinicians.
Now, in a paper published in Communications Medicine, a University at Buffalo-led team reports that it has found a way to use artificial intelligence to reveal these otherwise invisible cortical lesions by reviewing existing MRI scans.
The significance of finally being able to see what has been known as one of the most important indicators in MS disease progression cannot be overstated, the researchers say.
"Detecting previously invisible cortical lesions on conventional legacy MRI scans has major implications for MS research and clinical care," says Robert Zivadinov, MD, PhD, senior author on the paper, SUNY Distinguished Professor in the Department of Neurology and director of the Buffalo Neuroimaging Analysis Center (BNAC) in the Jacobs School of Medicine and Biomedical Sciences at UB. "The ability to see for the first time these previously hidden indicators of MS disease progression, including cognitive impairment and disability, is an important advance," he says.
While the involvement of cortical lesions in MS has been known almost since the identification of MS in the late 19th century, they weren't included on diagnostic criteria until the 21st century. And even when they were included, it was noted that their use would be greatly limited due to the current capabilities of clinical MRI.
Ongoing damage that couldn't be seen
"We have all been very frustrated, knowing that these cortical lesions were there but not being able to see them," says Michael G. Dwyer, PhD, first and corresponding author on the paper, associate professor of neurology and biomedical informatics in the Jacobs School and a researcher with BNAC. "There's a lot of ongoing damage that continues to happen in MS that you won't see with conventional MRI, but that histopathologists have been clearly demonstrating for decades on postmortem tissue.
"What this collaboration has been able to accomplish is a real success story for applying AI in the medical arena," he continues. "We now have access to these incredibly useful data on MRI scans that were there but you couldn't see them without using AI to pull them out. The computational methods are finally at the point where we can do this."
The AI approaches the researchers used, building on work from the co-authors from the Netherlands, were designed to extrapolate vital information from the relationships between multiple images that can't be seen on a single image.
The researchers combined multiple image-processing techniques, including a new one they developed called MMCLE, or multimodal cortical lesion enhancement. They then applied these techniques to MRI scans from the large, phase III FDA regulatory ORATORIO clinical trial, a study of the MS drug Ocrelizumab that included more than 700 participants.
More than 11,000 cortical lesions detected
They found that while individual images of a patient's brain revealed mostly white matter lesions, once they applied the AI-based image processing methods to multiple different contrast images, they were able to see anywhere from 15 to 20 cortical lesions for each patient, more than 11,000 for the whole dataset.
Michael G. Dwyer, PhD, first and corresponding author on the paperIf you look on the original scans, you generally can't see the cortical lesions, but generative AI is very powerful because it can look between the scans and detect tiny differences between them. Because it sees those minor discrepancies, AI can reveal that there's something going wrong there, that the tissue is not behaving like healthy tissue. The trained models can view multiple MRI images together and synthesize them, and synthesize what had been missing."
Led by UB, the international research team included scientists and clinicians from academia and industry, including Genentech, which makes Ocrelizumab. Zivadinov notes the collaboration among people with such a breadth of perspectives is what contributed to their success.
"This work, which has revealed that there is so much invisible pathology in the brain, will have tremendous impact for reviewing data from past clinical trials and also for those going forward," he says.
In addition to Zivadinov and Dwyer, UB co-authors include Niels P. Bergsland, PhD, assistant professor of neurology; Alexander Bartnik, PhD, postdoctoral researcher; and Dejan Jakimovski, MD, PhD, research adviser at BNAC.
Other co-authors are Samantha Noteboom, Menno M. Schoonheim and Martijn D. Steenwijk, all of the MS Center Amsterdam, Anatomy and Neurosciences, Vrije Universiteit Amsterdam, and Jinglan Pei and David Clayton of Genentech Inc.
The research was supported in part by Genentech.
Source:
Journal reference: