一种用于注意缺陷多动障碍检测的多通道深度神经网络模型,该模型分析多尺度功能性脑连接组数据。
A Multichannel Deep Neural Network Model Analyzing Multiscale Functional Brain Connectome Data for Attention Deficit Hyperactivity Disorder Detection.
作者信息
Chen Ming, Li Hailong, Wang Jinghua, Dillman Jonathan R, Parikh Nehal A, He Lili
机构信息
Department of Pediatrics, Perinatal Institute (M.C., H.L., N.A.P., L.H.) and Department of Electronic Engineering and Computing Science, University of Cincinnati, Cincinnati, Ohio (M.C.); and Department of Radiology (J.R.D.), Cincinnati Children's Hospital Medical Center, 3333 Burnet Ave, MLC 7009, Cincinnati, OH 45229; and Departments of Radiology (J.W., J.R.D.) and Pediatrics (N.A.P., L.H.), University of Cincinnati College of Medicine, Cincinnati, Ohio.
出版信息
Radiol Artif Intell. 2019 Dec 11;2(1):e190012. doi: 10.1148/ryai.2019190012.
PURPOSE
To develop a multichannel deep neural network (mcDNN) classification model based on multiscale brain functional connectome data and demonstrate the value of this model by using attention deficit hyperactivity disorder (ADHD) detection as an example.
MATERIALS AND METHODS
In this retrospective case-control study, existing data from the Neuro Bureau ADHD-200 dataset consisting of 973 participants were used. Multiscale functional brain connectomes based on both anatomic and functional criteria were constructed. The mcDNN model used the multiscale brain connectome data and personal characteristic data (PCD) as joint features to detect ADHD and identify the most predictive brain connectome features for ADHD diagnosis. The mcDNN model was compared with single-channel deep neural network (scDNN) models and the classification performance was evaluated through cross-validation and hold-out validation with the metrics of accuracy, sensitivity, specificity, and area under the receiver operating characteristic curve (AUC).
RESULTS
In the cross-validation, the mcDNN model using combined features (fusion of the multiscale brain connectome data and PCD) achieved the best performance in ADHD detection with an AUC of 0.82 (95% confidence interval [CI]: 0.80, 0.83) compared with scDNN models using the features of the brain connectome at each individual scale and PCD, independently. In the hold-out validation, the mcDNN model achieved an AUC of 0.74 (95% CI: 0.73, 0.76).
CONCLUSION
An mcDNN model was developed for multiscale brain functional connectome data, and its utility for ADHD detection was demonstrated. By fusing the multiscale brain connectome data, the mcDNN model improved ADHD detection performance considerably over the use of a single scale.© RSNA, 2019.
目的
基于多尺度脑功能连接组数据开发一种多通道深度神经网络(mcDNN)分类模型,并以注意力缺陷多动障碍(ADHD)检测为例展示该模型的价值。
材料与方法
在这项回顾性病例对照研究中,使用了来自神经局ADHD - 200数据集的现有数据,该数据集包含973名参与者。构建了基于解剖学和功能标准的多尺度功能性脑连接组。mcDNN模型使用多尺度脑连接组数据和个人特征数据(PCD)作为联合特征来检测ADHD,并识别出对ADHD诊断最具预测性的脑连接组特征。将mcDNN模型与单通道深度神经网络(scDNN)模型进行比较,并通过交叉验证和留出验证,以准确率、灵敏度、特异性和受试者操作特征曲线下面积(AUC)等指标评估分类性能。
结果
在交叉验证中,与分别使用各个单尺度脑连接组特征和PCD的scDNN模型相比,使用联合特征(多尺度脑连接组数据与PCD的融合)的mcDNN模型在ADHD检测中表现最佳,AUC为0.82(95%置信区间[CI]:0.80,0.83)。在留出验证中,mcDNN模型的AUC为0.74(95%CI:0.73,0.76)。
结论
开发了一种用于多尺度脑功能连接组数据的mcDNN模型,并展示了其在ADHD检测中的效用。通过融合多尺度脑连接组数据,mcDNN模型在ADHD检测性能上比使用单尺度数据有显著提升。©RSNA,2019。
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