Predictive and Explainable Artificial Intelligence for Neuroimaging Applications.

IF 3 3区 医学 Q1 MEDICINE, GENERAL & INTERNAL Diagnostics Pub Date : 2024-10-27 DOI:10.3390/diagnostics14212394
Sekwang Lee, Kwang-Sig Lee
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Abstract

Background: The aim of this review is to highlight the new advance of predictive and explainable artificial intelligence for neuroimaging applications.

Methods: Data came from 30 original studies in PubMed with the following search terms: "neuroimaging" (title) together with "machine learning" (title) or "deep learning" (title). The 30 original studies were eligible according to the following criteria: the participants with the dependent variable of brain image or associated disease; the interventions/comparisons of artificial intelligence; the outcomes of accuracy, the area under the curve (AUC), and/or variable importance; the publication year of 2019 or later; and the publication language of English.

Results: The performance outcomes reported were within 58-96 for accuracy (%), 66-97 for sensitivity (%), 76-98 for specificity (%), and 70-98 for the AUC (%). The support vector machine and the convolutional neural network registered the best performance (AUC 98%) for the classifications of low- vs. high-grade glioma and brain conditions, respectively. Likewise, the random forest delivered the best performance (root mean square error 1) for the regression of brain conditions. The following factors were discovered to be major predictors of brain image or associated disease: (demographic) age, education, sex; (health-related) alpha desynchronization, Alzheimer's disease stage, CD4, depression, distress, mild behavioral impairment, RNA sequencing; (neuroimaging) abnormal amyloid-β, amplitude of low-frequency fluctuation, cortical thickness, functional connectivity, fractal dimension measure, gray matter volume, left amygdala activity, left hippocampal volume, plasma neurofilament light, right cerebellum, regional homogeneity, right middle occipital gyrus, surface area, sub-cortical volume.

Conclusion: Predictive and explainable artificial intelligence provide an effective, non-invasive decision support system for neuroimaging applications.

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用于神经成像应用的预测性和可解释性人工智能。
背景本综述旨在强调预测性和可解释性人工智能在神经成像应用中的新进展:数据来自PubMed上的30项原始研究,搜索关键词如下:"神经成像"(标题)和 "机器学习"(标题)或 "深度学习"(标题)。这30项原创研究符合以下标准:参与者的因变量为脑图像或相关疾病;人工智能干预/比较;结果为准确率、曲线下面积(AUC)和/或变量重要性;发表年份为2019年或之后;发表语言为英语:报告的性能结果为:准确率(%)在 58-96 之间,灵敏度(%)在 66-97 之间,特异性(%)在 76-98 之间,AUC(%)在 70-98 之间。支持向量机和卷积神经网络在低级别胶质瘤和高级别胶质瘤以及脑部状况的分类中分别获得了最佳性能(AUC 98%)。同样,随机森林在脑部状况回归方面表现最佳(均方根误差为 1)。研究发现,以下因素是脑图像或相关疾病的主要预测因素:(人口统计学)年龄、教育程度、性别;(健康相关)α不同步、阿尔茨海默病分期、CD4、抑郁、痛苦、轻度行为障碍、RNA 序列;(神经影像学)异常淀粉样蛋白-β、低频波动幅度、皮层厚度、功能连接、分形维度测量、灰质体积、左侧杏仁核活动、左侧海马体积、血浆神经丝光、右侧小脑、区域均匀性、右侧枕中回、表面积、皮层下体积。结论预测性和可解释性人工智能为神经成像应用提供了一个有效、非侵入性的决策支持系统。
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来源期刊
Diagnostics
Diagnostics Biochemistry, Genetics and Molecular Biology-Clinical Biochemistry
CiteScore
4.70
自引率
8.30%
发文量
2699
审稿时长
19.64 days
期刊介绍: Diagnostics (ISSN 2075-4418) is an international scholarly open access journal on medical diagnostics. It publishes original research articles, reviews, communications and short notes on the research and development of medical diagnostics. There is no restriction on the length of the papers. Our aim is to encourage scientists to publish their experimental and theoretical research in as much detail as possible. Full experimental and/or methodological details must be provided for research articles.
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