Comparative evaluation of interpretation methods in surface-based age prediction for neonates

IF 4.7 2区 医学 Q1 NEUROIMAGING NeuroImage Pub Date : 2024-09-24 DOI:10.1016/j.neuroimage.2024.120861
Xiaotong Wu , Chenxin Xie , Fangxiao Cheng , Zhuoshuo Li , Ruizhuo Li , Duan Xu , Hosung Kim , Jianjia Zhang , Hongsheng Liu , Mengting Liu
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Abstract

Significant changes in brain morphology occur during the third trimester of gestation. The capability of deep learning in leveraging these morphological features has enhanced the accuracy of brain age predictions for this critical period. Yet, the opaque nature of deep learning techniques, often described as "black box" approaches, limits their interpretability, posing challenges in clinical applications. Traditional interpretable methods developed for computer vision and natural language processing may not directly translate to the distinct demands of neuroimaging. In response, our research evaluates the effectiveness and adaptability of two interpretative methods—regional age prediction and the perturbation-based saliency map approach—for predicting the brain age of neonates. Analyzing 664 T1 MRI scans with the NEOCIVET pipeline to extract brain surface and cortical features, we assess how these methods illuminate key brain regions for age prediction, focusing on technical analysis with clinical insight. Through a comparative analysis of the saliency index (SI) with relative brain age (RBA) and the examination of structural covariance networks, we uncover the saliency index's enhanced ability to pinpoint regions vital for accurate indication of clinical factors. Our results highlight the advantages of perturbation techniques in addressing the complexities of medical data, steering clinical interventions for premature neonates towards more personalized and interpretable approaches. This study not only reveals the promise of these methods in complex medical scenarios but also offers a blueprint for implementing more interpretable and clinically relevant deep learning models in healthcare settings.
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比较评估基于表面的新生儿年龄预测的解释方法。
妊娠三个月期间,大脑形态会发生显著变化。深度学习利用这些形态特征的能力提高了这一关键时期脑年龄预测的准确性。然而,深度学习技术的不透明性(通常被称为 "黑盒 "方法)限制了其可解释性,给临床应用带来了挑战。为计算机视觉和自然语言处理开发的传统可解释方法可能无法直接转化为神经成像的独特需求。为此,我们的研究评估了两种解释性方法--区域年龄预测法和基于扰动的显著性图法--预测新生儿脑年龄的有效性和适应性。我们利用 NEOCIVET 管道分析了 664 张 T1 MRI 扫描图像,提取了大脑表面和皮层特征,评估了这些方法如何揭示年龄预测的关键大脑区域,重点关注具有临床洞察力的技术分析。通过对显著性指数(SI)与相对脑年龄(RBA)的比较分析以及对结构协方差网络的研究,我们发现显著性指数具有更强的能力,可以精确定位对准确指示临床因素至关重要的区域。我们的研究结果凸显了扰动技术在处理复杂医疗数据方面的优势,从而引导早产新生儿的临床干预朝着更加个性化和可解释的方向发展。这项研究不仅揭示了这些方法在复杂医疗场景中的应用前景,还为在医疗环境中实施更具可解释性和临床相关性的深度学习模型提供了蓝图。
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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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