Comprehensive Morphometric Analysis to Identify Key Neuroimaging Biomarkers for the Diagnosis of Adult Hydrocephalus Using Artificial Intelligence.

IF 3.9 2区医学 Q1 CLINICAL NEUROLOGY

Neurosurgery Pub Date : 2024-11-07 DOI:10.1227/neu.0000000000003248

Seifollah Gholampour, Jacob Benjamin Rosen, Michelangelo Pagan, Sonja Chen, Ibrahim Gomaa, Arshia Dehghan, Mark Graham Waterstraat

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引用次数: 0

Abstract

Background and objectives: Hydrocephalus involves abnormal cerebrospinal fluid accumulation in brain ventricles. Early and accurate diagnosis is crucial for timely intervention and preventing progressive neurological deterioration. The aim of this study was to identify key neuroimaging biomarkers for the diagnosis of hydrocephalus using artificial intelligence to develop practical and accurate diagnostic tools for neurosurgeons.

Methods: Fifteen 1-dimensional (1-D) neuroimaging parameters and ventricular volume of adult patients with non-normal pressure hydrocephalus and healthy subjects were measured using manual image processing, and 10 morphometric indices were also calculated. The data set was analyzed using 8 machine, ensemble, and deep learning classifiers to predict hydrocephalus. SHapley Additive exPlanations (SHAP) feature importance analysis identified key neuroimaging diagnostic biomarkers.

Results: Gradient Boosting achieved the highest performance, with an accuracy of 0.94 and an area under the curve of 0.97. SHAP analysis identified ventricular volume as the most important parameter. Given the challenges of measuring volume for clinicians, we identified key 1-D morphometric biomarkers that are easily measurable yet provide similar classifier performance. The results showed that the frontal-temporal horn ratio, modified Evan index, modified cella media index, sagittal maximum lateral ventricle height, and coronal posterior callosal angle are key 1-D diagnostic biomarkers. Notably, higher modified Evan index, modified cella media index, and sagittal maximum lateral ventricle height, and lower frontal-temporal horn ratio and coronal posterior callosal angle values were associated with hydrocephalus prediction. The results also elucidated the relationships between these key 1-D morphometric parameters and ventricular volume, providing potential diagnostic insights.

Conclusion: This study highlights the importance of a multifaceted diagnostic approach incorporating 5 easily measurable 1-D neuroimaging biomarkers for neurosurgeons to differentiate non-normal pressure hydrocephalus from healthy subjects. Incorporating our artificial intelligence model, interpreted through SHAP analysis, into routine clinical workflows may transform the diagnostic landscape for hydrocephalus by standardizing diagnosis and overcoming the limitations of visual evaluations, particularly in early stages and challenging cases.

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利用人工智能进行综合形态计量分析以确定诊断成人脑积水的关键神经影像生物标记物

背景和目的：脑积水是指脑室中脑脊液异常积聚。早期准确的诊断对于及时干预和防止神经系统进行性恶化至关重要。本研究旨在利用人工智能识别诊断脑积水的关键神经影像生物标志物，为神经外科医生开发实用、准确的诊断工具：采用人工图像处理方法测量了非正常压力脑积水成年患者和健康人的15个一维（1-D）神经影像参数和脑室容积，并计算了10个形态指数。使用 8 个机器、集合和深度学习分类器对数据集进行分析，以预测脑积水。SHapley Additive exPlanations（SHAP）特征重要性分析确定了关键的神经影像诊断生物标志物：梯度提升法的性能最高，准确率为 0.94，曲线下面积为 0.97。SHAP分析确定心室容积是最重要的参数。考虑到临床医生在测量容积方面面临的挑战，我们确定了一些关键的一维形态计量生物标志物，它们既易于测量，又能提供类似的分类器性能。结果表明，额颞角比率、改良埃文指数、改良细胞介质指数、矢状面最大侧脑室高度和冠状面后胼胝体角是关键的一维诊断生物标志物。值得注意的是，较高的改良埃文指数、改良细胞介质指数和矢状面最大侧脑室高度，以及较低的额颞角比率和冠状面后胼胝体角值与预测脑积水有关。研究结果还阐明了这些关键的一维形态测量参数与脑室容量之间的关系，为诊断提供了潜在的见解：本研究强调了结合 5 种易于测量的一维神经影像生物标志物的多方面诊断方法对于神经外科医生区分非正常压力脑积水和健康受试者的重要性。将我们通过 SHAP 分析解读的人工智能模型纳入常规临床工作流程，可通过标准化诊断和克服视觉评估的局限性来改变脑积水的诊断格局，尤其是在早期阶段和具有挑战性的病例中。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neurosurgery 医学-临床神经学

CiteScore

8.20

自引率

6.20%

发文量

898

审稿时长

2-4 weeks

期刊介绍： Neurosurgery, the official journal of the Congress of Neurological Surgeons, publishes research on clinical and experimental neurosurgery covering the very latest developments in science, technology, and medicine. For professionals aware of the rapid pace of developments in the field, this journal is nothing short of indispensable as the most complete window on the contemporary field of neurosurgery. Neurosurgery is the fastest-growing journal in the field, with a worldwide reputation for reliable coverage delivered with a fresh and dynamic outlook.