Researchers combine deep learning and physics to fix motion-corrupted MRI scans

MIT researchers combine deep learning and physics to fix motion-corrupted MRI scans

Compared to other imaging modalities like X-rays or CT scans, MRI scans provide high-quality soft tissue contrast. Unfortunately, MRI is highly sensitive to motion, with even the smallest of movements resulting in image artifacts. These artifacts put patients at risk of misdiagnoses or inappropriate treatment when critical details are obscured from the physician. But researchers at MIT may have developed a deep learning model capable of motion correction in brain MRI.

“Motion is a common problem in MRI,” explains Nalini Singh, an Abdul Latif Jameel Clinic for Machine Learning in Health (Jameel Clinic)-affiliated Ph.D. student in the Harvard-MIT Program in Health Sciences and Technology (HST) and lead author of the paper. “It’s a pretty slow imaging modality.”

MRI sessions can take anywhere from a few minutes to an hour, depending on the type of images required. Even during the shortest scans, small movements can have dramatic effects on the resulting image. Unlike camera imaging, where motion typically manifests as a localized blur, motion in MRI often results in artifacts that can corrupt the whole image. Patients may be anesthetized or requested to limit deep breathing in order to minimize motion.

However, these measures often cannot be taken in populations particularly susceptible to motion, including children and patients with psychiatric disorders.

The paper, available on the arXiv preprint server and titled “Data Consistent Deep Rigid MRI Motion Correction,” was recently awarded best oral presentation at the Medical Imaging with Deep Learning conference (MIDL) in Nashville, Tennessee. The method computationally constructs a motion-free image from motion-corrupted data without changing anything about the scanning procedure. “Our aim was to combine physics-based modeling and deep learning to get the best of both worlds,” Singh says.

The importance of this combined approach lies within ensuring consistency between the image output and the actual measurements of what is being depicted, otherwise the model creates “hallucinations”—images that appear realistic, but are physically and spatially inaccurate, potentially worsening outcomes when it comes to diagnoses.

Procuring an MRI free of motion artifacts, particularly from patients with neurological disorders that cause involuntary movement, such as Alzheimer’s or Parkinson’s disease, would benefit more than just patient outcomes.

A study from the University of Washington Department of Radiology estimated that motion affects 15 percent of brain MRIs. Motion in all types of MRI that leads to repeated scans or imaging sessions to obtain images with sufficient quality for diagnosis results in approximately $115,000 in hospital expenditures per scanner on an annual basis.

According to Singh, future work could explore more sophisticated types of head motion as well as motion in other body parts. For instance, fetal MRI suffers from rapid, unpredictable motion that cannot be modeled only by simple translations and rotations.

“This line of work from Singh and company is the next step in MRI motion correction. Not only is it excellent research work, but I believe these methods will be used in all kinds of clinical cases: children and older folks who can’t sit still in the scanner, pathologies which induce motion, studies of moving tissue, even healthy patients will move in the magnet,” says Daniel Moyer, an assistant professor at Vanderbilt University. “In the future, I think that it likely will be standard practice to process images with something directly descended from this research.”

More information:
Nalini M. Singh et al, Data Consistent Deep Rigid MRI Motion Correction, arXiv (2023). DOI: 10.48550/arxiv.2301.10365

Journal information:
arXiv

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