利用基于可解释多特征的卷积神经网络预测轻度脑外伤患者的脑年龄

IF 4.7 2区 医学 Q1 NEUROIMAGING NeuroImage Pub Date : 2024-07-22 DOI:10.1016/j.neuroimage.2024.120751
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引用次数: 0

摘要

背景:卷积神经网络(CNN卷积神经网络(CNN)可以捕捉基于核磁共振成像的脑衰老结构特征变化,从而准确预测健康人的脑年龄。方法:在此,我们利用大型异构数据集(N = 1464)中的结构数据,建立了一个可解释的三维组合 CNN 模型,用于脑年龄预测。此外,我们还利用细粒度人类脑神经组图谱建立了基于图谱的闭塞分析方案,以揭示健康对照组(HCs)和 mTBI 患者脑年龄预测的年龄分层贡献脑区。此外,还研究了 mTBI 后大脑预测年龄差距(brain-PAG)与个人认知障碍以及血浆神经丝光水平之间的相关性:我们的模型利用从 T1w 数据中提取的多个三维特征作为输入,将 154 名 HCs 的年龄预测平均绝对误差 (MAE) 降低到 3.08 岁,并将皮尔森 r 提高到 0.97。我们模型的强大通用性也在不同中心得到了验证。对高危人群和 mTBI 患者脑年龄预测贡献最大的区域是尾状核和丘脑,而在整个成人生命周期中,贡献区域大多位于皮层下区域。左半球被证实在整个成人生命周期中对脑年龄预测的贡献更大。我们的研究表明,无论是急性期还是慢性期,mTBI 患者的脑-PAG 都明显高于 HC。mTBI 患者脑PAG的增加还与认知障碍和血浆神经丝光(一种神经变性标志物)水平的升高高度相关。较高的脑PAG及其与严重认知障碍的相关性在患者的随访检查中显示出纵向和持续的性质:我们在一个相对较大的数据集上提出了一种可解释的深度学习框架,以准确预测健康人和 mTBI 患者的脑年龄。可解释性分析表明,在健康人和 mTBI 患者的整个成年生命周期中,尾状体和丘脑的作用最大。左半球对脑年龄预测的贡献很大,这可能会启发我们在未来关注神经系统疾病中大脑异常的侧向性。所提出的可解释深度学习框架也为未来测试相关药物和治疗方法的性能带来了希望。
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Brain age prediction using interpretable multi-feature-based convolutional neural network in mild traumatic brain injury

Background

Convolutional neural network (CNN) can capture the structural features changes of brain aging based on MRI, thus predict brain age in healthy individuals accurately. However, most studies use single feature to predict brain age in healthy individuals, ignoring adding information from multiple sources and the changes in brain aging patterns after mild traumatic brain injury (mTBI) were still unclear.

Methods

Here, we leveraged the structural data from a large, heterogeneous dataset (N = 1464) to implement an interpretable 3D combined CNN model for brain-age prediction. In addition, we also built an atlas-based occlusion analysis scheme with a fine-grained human Brainnetome Atlas to reveal the age-sstratified contributed brain regions for brain-age prediction in healthy controls (HCs) and mTBI patients. The correlations between brain predicted age gaps (brain-PAG) following mTBI and individual's cognitive impairment, as well as the level of plasma neurofilament light were also examined.

Results

Our model utilized multiple 3D features derived from T1w data as inputs, and reduced the mean absolute error (MAE) of age prediction to 3.08 years and improved Pearson's r to 0.97 on 154 HCs. The strong generalizability of our model was also validated across different centers. Regions contributing the most significantly to brain age prediction were the caudate and thalamus for HCs and patients with mTBI, and the contributive regions were mostly located in the subcortical areas throughout the adult lifespan. The left hemisphere was confirmed to contribute more in brain age prediction throughout the adult lifespan. Our research showed that brain-PAG in mTBI patients was significantly higher than that in HCs in both acute and chronic phases. The increased brain-PAG in mTBI patients was also highly correlated with cognitive impairment and a higher level of plasma neurofilament light, a marker of neurodegeneration. The higher brain-PAG and its correlation with severe cognitive impairment showed a longitudinal and persistent nature in patients with follow-up examinations.

Conclusion

We proposed an interpretable deep learning framework on a relatively large dataset to accurately predict brain age in both healthy individuals and mTBI patients. The interpretable analysis revealed that the caudate and thalamus became the most contributive role across the adult lifespan in both HCs and patients with mTBI. The left hemisphere contributed significantly to brain age prediction may enlighten us to be concerned about the lateralization of brain abnormality in neurological diseases in the future. The proposed interpretable deep learning framework might also provide hope for testing the performance of related drugs and treatments in the future.

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来源期刊
NeuroImage
NeuroImage 医学-核医学
CiteScore
11.30
自引率
10.50%
发文量
809
审稿时长
63 days
期刊介绍: NeuroImage, a Journal of Brain Function provides a vehicle for communicating important advances in acquiring, analyzing, and modelling neuroimaging data and in applying these techniques to the study of structure-function and brain-behavior relationships. Though the emphasis is on the macroscopic level of human brain organization, meso-and microscopic neuroimaging across all species will be considered if informative for understanding the aforementioned relationships.
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