基于纹理的机器学习方法在新生儿黄疸早期检测中的可行性研究。

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-02-22 DOI:10.1038/s41598-025-89528-6

Nanthida Phattraprayoon, Teerapat Ungtrakul, Patiparn Kummanee, Sunisa Tavaen, Tanin Pirunnet, Todsaporn Fuangrod

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引用次数: 0

摘要

未经治疗的新生儿黄疸可造成严重后果。有效的新生儿黄疸筛查可以预防婴儿的长期并发症。在资源有限的情况下，非侵入性方法可能是有益的。本可行性研究探讨了一种基于纹理的机器学习方法用于新生儿黄疸的早期检测。使用新生儿黄疸筛查和评估板从四个身体部位采集了200名婴儿的临床数据和皮肤图像。数据被分成训练/验证（n = 160）和盲测（n = 40）数据集。图像处理后提取了92个特征（3个临床特征，89个基于纹理特征）。比较了8种机器学习模型对胆红素水平的预测。在基于web的应用程序（AmberSNAP）中实现了性能最好的模型支持向量机（SVM），并使用盲测试数据集进行了测试。支持向量机与RRelief-F特征选择相结合，对头部和胸骨的测量效果最佳，而支持向量机与单变量回归相结合，对腹部和小腿的测量效果最好。盲法测试在胆红素水平预测方面表现良好(平均绝对误差：1.675 mg/dL；均方根误差：2.192 mg/dL)，预测值与实测值呈正相关(r = 0.644, p

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Feasibility study of texture-based machine learning approach for early detection of neonatal jaundice.

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Feasibility study of texture-based machine learning approach for early detection of neonatal jaundice.

Untreated neonatal jaundice can have severe consequences. Effective screening for neonatal jaundice can prevent long-term complications in infants. Non-invasive approaches may be beneficial in settings with limited resources. This feasibility study explores a texture-based machine learning approach for early detection of neonatal jaundice. Clinical data and skin images of 200 infants were captured from four body locations using the Neonatal Jaundice Screening and Assessment Plate. Data were split into training/validating (n = 160) and blind testing (n = 40) datasets. Ninety-two features (three clinical, 89 texture-based) were extracted after image processing. Eight machine learning models were compared for bilirubin level prediction. The best performing model, Support Vector Machine (SVM), was implemented in a web-based application (AmberSNAP) and tested using blind testing dataset. SVM paired with RRelief-F feature selection achieved optimal performance for head and sternum measurements, while SVM with Univariate Regression performed best for abdomen and lower leg measurements. Blind testing demonstrated good performance in bilirubin level prediction (mean absolute error: 1.675 mg/dL; root mean square error: 2.192 mg/dL), with moderate correlation between predicted and measured values (r = 0.644, p < 0.001). These findings suggest that texture-based machine learning is a feasible approach for neonatal jaundice screening in low-resource settings.

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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