Braun Addison S, Satoh Ryota, Pham Nha Trang Thu, Singh-Reilly Neha, Ali Farwa, Dickson Dennis W, Lowe Val J, Whitwell Jennifer L, Josephs Keith A
Department of Radiology, Mayo Clinic, Rochester, MN.
Department of Neurology, Mayo Clinic, Rochester, MN.
Ann Neurol. 2025 Aug;98(2):410-420. doi: 10.1002/ana.27265. Epub 2025 May 30.
To determine whether a machine learning model of voxel level [f]fluorodeoxyglucose positron emission tomography (PET) data could predict progressive supranuclear palsy (PSP) pathology, as well as outperform currently available biomarkers.
One hundred and thirty-seven autopsied patients with PSP (n = 42) and other neurodegenerative diseases (n = 95) who underwent antemortem [f]fluorodeoxyglucose PET and 3.0 Tesla magnetic resonance imaging (MRI) scans were analyzed. A linear support vector machine was applied to differentiate pathological groups with sensitivity analyses performed to assess the influence of voxel size and region removal. A radial basis function was also prepared to create a secondary model using the most important voxels. The models were optimized on the main dataset (n = 104), and their performance was compared with the magnetic resonance parkinsonism index measured on MRI in the independent test dataset (n = 33).
The model had the highest accuracy (0.91) and F-score (0.86) when voxel size was 6mm. In this optimized model, important voxels for differentiating the groups were observed in the thalamus, midbrain, and cerebellar dentate. The secondary models found the combination of thalamus and dentate to have the highest accuracy (0.89) and F-score (0.81). The optimized secondary model showed the highest accuracy (0.91) and F-scores (0.86) in the test dataset and outperformed the magnetic resonance parkinsonism index (0.81 and 0.70, respectively).
The results suggest that glucose hypometabolism in the thalamus and cerebellar dentate have the highest potential for predicting PSP pathology. Our optimized machine learning model outperformed the best currently available biomarker to predict PSP pathology. ANN NEUROL 2025;98:410-420.
确定基于体素水平的[F]氟脱氧葡萄糖正电子发射断层扫描(PET)数据的机器学习模型是否能够预测进行性核上性麻痹(PSP)病理,以及是否优于目前可用的生物标志物。
分析了137例生前接受过[F]氟脱氧葡萄糖PET和3.0特斯拉磁共振成像(MRI)扫描的尸检患者,其中PSP患者42例,其他神经退行性疾病患者95例。应用线性支持向量机区分病理组,并进行敏感性分析以评估体素大小和区域去除的影响。还准备了径向基函数以使用最重要的体素创建二级模型。模型在主要数据集(n = 104)上进行优化,并将其性能与在独立测试数据集(n = 33)中MRI测量的磁共振帕金森病指数进行比较。
当体素大小为6mm时,模型具有最高的准确率(0.91)和F值(0.86)。在这个优化模型中,在丘脑、中脑和小脑齿状核中观察到区分组的重要体素。二级模型发现丘脑和齿状核的组合具有最高的准确率(0.89)和F值(0.81)。优化后的二级模型在测试数据集中显示出最高的准确率(0.91)和F值(0.86),并且优于磁共振帕金森病指数(分别为0.81和0.70)。
结果表明,丘脑和小脑齿状核的葡萄糖低代谢在预测PSP病理方面具有最高潜力。我们优化的机器学习模型在预测PSP病理方面优于目前最好的生物标志物。《神经病学纪事》2025年;98:410 - 420。
