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In Frontiers in neurology

BACKGROUND : Abnormal brain development is common in children with cerebral palsy (CP), but there are no recent reports on the actual brain age of children with CP.

OBJECTIVE : Our objective is to use the brain age prediction model to explore the law of brain development in children with CP.

METHODS : A two-dimensional convolutional neural networks brain age prediction model was designed without segmenting the white and gray matter. Training and testing brain age prediction model using magnetic resonance images of healthy people in a public database. The brain age of children with CP aged 5-27 years old was predicted.

RESULTS : The training dataset mean absolute error (MAE) = 1.85, r = 0.99; test dataset MAE = 3.98, r = 0.95. The brain age gap estimation (BrainAGE) of the 5- to 27-year-old patients with CP was generally higher than that of healthy peers (p < 0.0001). The BrainAGE of male patients with CP was higher than that of female patients (p < 0.05). The BrainAGE of patients with bilateral spastic CP was higher than those with unilateral spastic CP (p < 0.05).

CONCLUSION : A two-dimensional convolutional neural networks brain age prediction model allows for brain age prediction using routine hospital T1-weighted head MRI without segmenting the white and gray matter of the brain. At the same time, these findings suggest that brain aging occurs in patients with CP after brain damage. Female patients with CP are more likely to return to their original brain development trajectory than male patients after brain injury. In patients with spastic CP, brain aging is more serious in those with bilateral cerebral hemisphere injury than in those with unilateral cerebral hemisphere injury.

Zhang Chun-Yu, Yan Bao-Feng, Mutalifu Nurehemaiti, Fu Ya-Wei, Shao Jiang, Wu Jun-Jie, Guan Qi, Biedelehan Song-Hai, Tong Ling-Xiao, Luan Xin-Ping

2022

brain age, brain age gap estimation, cerebral palsy, convolutional neural networks, deep learning