advertisement
Science News
from research organizations

Artificial intelligence boosts MRI detection of ADHD

Date:
December 11, 2019
Source:
Radiological Society of North America
Summary:
深入学习,一种人工强度lligence, can boost the power of MRI in predicting attention deficit hyperactivity disorder (ADHD), according to a new study. Researchers said the approach could also have applications for other neurological conditions.
Share:
advertisement

FULL STORY

深入学习,一种人工强度lligence, can boost the power of MRI in predicting attention deficit hyperactivity disorder (ADHD), according to a study published inRadiology: Artificial Intelligence. Researchers said the approach could also have applications for other neurological conditions.

The human brain is a complex set of networks. Advances in functional MRI, a type of imaging that measures brain activity by detecting changes in blood flow, have helped with the mapping of connections within and between brain networks. This comprehensive brain map is referred to as the connectome.

Increasingly, the connectome is regarded as key to understanding brain disorders like ADHD, a condition that makes it difficult for a person to pay attention and control restless behavior.

According to the National Survey of Children's Health, approximately 9.4% of U.S. children, ages 2 to 17 years (6.1 million) in 2016 have been diagnosed with ADHD. The disorder cannot yet be definitively diagnosed in an individual child with a single test or medical imaging exam. Instead, ADHD diagnosis is based on a series of symptoms and behavior-based tests.

Brain MRI has a potential role in diagnosis, as research suggests that ADHD results from some type of breakdown or disruption in the connectome. The connectome is constructed from spatial regions across the MR image known as parcellations. Brain parcellations can be defined based on anatomical criteria, functional criteria, or both. The brain can be studied at different scales based on different brain parcellations.

之前的研究都集中在所谓的单身-scale approach, where the connectome is constructed based on only one parcellation. For the new study, researchers from the University of Cincinnati College of Medicine and Cincinnati Children's Hospital Medical Center took a more comprehensive view. They developed a multi-scale method, which used multiple connectome maps based on multiple parcellations.

To build the deep learning model, the researchers used data from the NeuroBureau ADHD-200 dataset. The model used the multi-scale brain connectome data from the project's 973 participants along with relevant personal characteristics, such as gender and IQ.

The multi-scale approach improved ADHD detection performance significantly over the use of a single-scale method.

"Our results emphasize the predictive power of the brain connectome," said study senior author Lili He, Ph.D., from the Cincinnati Children's Hospital Medical Center. "The constructed brain functional connectome that spans multiple scales provides supplementary information for the depicting of networks across the entire brain."

By improving diagnostic accuracy, deep-learning-aided MRI-based diagnosis could be critical in implementing early interventions for ADHD patients. Approximately 5% of American pre-school and school-aged children have been diagnosed with ADHD. These children and adolescents face a high risk of failing in academic study and building social relationships, which can result in financial hardship for families and create a tremendous burden on society.

The approach also has potential beyond ADHD, according to Dr. He.

"This model can be generalized to other neurological deficiencies," she said. "We already use it to predict cognitive deficiency in pre-term infants. We scan them soon after birth to predict neurodevelopmental outcomes at two years of age."

In the future, the researchers expect to see the deep learning model improve as it is exposed to larger neuroimaging datasets. They also hope to better understand the specific breakdowns or disruptions in the connectome identified by the model that are associated with ADHD.

advertisement

Story Source:

Materialsprovided byRadiological Society of North America.Note: Content may be edited for style and length.


Journal Reference:

  1. Ming Chen, Hailong Li, Jinghua Wang, Jonathan R. Dillman, Nehal A. Parikh, Lili He.A Multichannel Deep Neural Network Model Analyzing Multiscale Functional Brain Connectome Data for Attention Deficit Hyperactivity Disorder Detection.Radiology: Artificial Intelligence, 2019; 2 (1): e190012 DOI:10.1148/ryai.2019190012

Cite This Page:

Radiological Society of North America. "Artificial intelligence boosts MRI detection of ADHD." ScienceDaily. ScienceDaily, 11 December 2019. .
Radiological Society of North America. (2019, December 11). Artificial intelligence boosts MRI detection of ADHD.ScienceDaily. Retrieved July 1, 2023 from www.koonmotors.com/releases/2019/12/191211145609.htm
Radiological Society of North America. "Artificial intelligence boosts MRI detection of ADHD." ScienceDaily. www.koonmotors.com/releases/2019/12/191211145609.htm (accessed July 1, 2023).

Explore More
from ScienceDaily

RELATED STORIES

advertisement