Dorsal Finger Fold Recognition by Convolutional Neural Networks for the Detection and Monitoring of Joint Swelling in Patients with Rheumatoid Arthritis.

Q1 Computer Science
Digital Biomarkers Pub Date : 2022-06-08 eCollection Date: 2022-05-01 DOI:10.1159/000525061
Thomas Hügle, Leo Caratsch, Matteo Caorsi, Jules Maglione, Diana Dan, Alexandre Dumusc, Marc Blanchard, Gabriel Kalweit, Maria Kalweit
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引用次数: 10

Abstract

Digital biomarkers such as wearables are of increasing interest in monitoring rheumatic diseases, but they usually lack disease specificity. In this study, we apply convolutional neural networks (CNN) to real-world hand photographs in order to automatically detect, extract, and analyse dorsal finger fold lines as a correlate of proximal interphalangeal (PIP) joint swelling in patients with rheumatoid arthritis (RA). Hand photographs of RA patients were taken by a smartphone camera in a standardized manner. Overall, 190 PIP joints were categorized as either swollen or not swollen based on clinical judgement and ultrasound. Images were automatically preprocessed by cropping PIP joints and extracting dorsal finger folds. Subsequently, metrical analysis of dorsal finger folds was performed, and a CNN was trained to classify the dorsal finger lines into swollen versus non-swollen joints. Representative horizontal finger folds were also quantified in a subset of patients before and after resolution of PIP swelling and in patients with disease flares. In swollen joints, the number of automatically extracted deep skinfold imprints was significantly reduced compared to non-swollen joints (1.3, SD 0.8 vs. 3.3, SD 0.49, p < 0.01). The joint diameter/deep skinfold length ratio was significantly higher in swollen (4.1, SD 1.4) versus non-swollen joints (2.1, SD 0.6, p < 0.01). The CNN model successfully differentiated swollen from non-swollen joints based on finger fold patterns with a validation accuracy of 0.84, a sensitivity of 88%, and a specificity of 75%. A heatmap of the original images obtained by an extraction algorithm confirmed finger folds as the region of interest for correct classification. After significant response to disease-modifying antirheumatic drug ± corticosteroid therapy, longitudinal metrical analysis of eight representative deep finger folds showed a decrease in the mean diameter/finger fold length (finger fold index, FFI) from 3.03 (SD 0.68) to 2.08 (SD 0.57). Conversely, the FFI increased in patients with disease flares. In conclusion, automated preprocessing and the application of CNN algorithms in combination with longitudinal metrical analysis of dorsal finger fold patterns extracted from real-world hand photos might serve as a digital biomarker in RA.

基于卷积神经网络的指背识别在类风湿关节炎患者关节肿胀检测与监测中的应用。
可穿戴设备等数字生物标志物在监测风湿病方面越来越受关注,但它们通常缺乏疾病特异性。在这项研究中,我们将卷积神经网络(CNN)应用于现实世界的手部照片,以便自动检测、提取和分析类风湿关节炎(RA)患者近端指间关节肿胀与手指背襞线的相关性。采用智能手机相机对RA患者进行标准化的手拍。总体而言,根据临床判断和超声检查,190个PIP关节分为肿胀或不肿胀。通过裁剪PIP关节和提取手指背襞对图像进行自动预处理。随后,对手指背襞进行测量分析,并训练CNN将手指背线分为肿胀关节和非肿胀关节。在PIP肿胀消退前后和疾病发作患者的一个亚组中,代表性的水平指襞也被量化。在肿胀关节中,与非肿胀关节相比,自动提取的深度皮褶印迹数量显著减少(1.3,SD 0.8 vs. 3.3, SD 0.49, p < 0.01)。肿胀的关节直径/深皮褶长度比(4.1,SD 1.4)明显高于非肿胀的关节(2.1,SD 0.6, p < 0.01)。CNN模型基于手指褶皱模式成功区分了肿胀和非肿胀关节,验证准确率为0.84,灵敏度为88%,特异性为75%。通过提取算法获得的原始图像热图确认手指褶皱是正确分类的兴趣区域。在接受抗风湿药物治疗和皮质类固醇治疗后,8个具有代表性的深指沟纵向测量分析显示,平均直径/指沟长度(指沟指数,FFI)从3.03 (SD 0.68)下降到2.08 (SD 0.57)。相反,疾病发作患者的FFI增加。综上所述,自动预处理和应用CNN算法结合对真实手照中提取的指背褶皱进行纵向测量分析,可能作为RA的数字生物标志物。
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
Digital Biomarkers
Digital Biomarkers Medicine-Medicine (miscellaneous)
CiteScore
10.60
自引率
0.00%
发文量
12
审稿时长
23 weeks
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