Design of a Machine Learning System to Predict the Thickness of a Melanoma Lesion in a Non-Invasive Way from Dermoscopic Images.

IF 2.3 Q3 MEDICAL INFORMATICS
Ádám Szijártó, Ellák Somfai, András Lőrincz
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引用次数: 2

Abstract

Objectives: Melanoma is the deadliest form of skin cancer, but it can be fully cured through early detection and treatment in 99% of cases. Our aim was to develop a non-invasive machine learning system that can predict the thickness of a melanoma lesion, which is a proxy for tumor progression, through dermoscopic images. This method can serve as a valuable tool in identifying urgent cases for treatment.

Methods: A modern convolutional neural network architecture (EfficientNet) was used to construct a model capable of classifying dermoscopic images of melanoma lesions into three distinct categories based on thickness. We incorporated techniques to reduce the impact of an imbalanced training dataset, enhanced the generalization capacity of the model through image augmentation, and utilized five-fold cross-validation to produce more reliable metrics.

Results: Our method achieved 71% balanced accuracy for three-way classification when trained on a small public dataset of 247 melanoma images. We also presented performance projections for larger training datasets.

Conclusions: Our model represents a new state-of-the-art method for classifying melanoma thicknesses. Performance can be further optimized by expanding training datasets and utilizing model ensembles. We have shown that earlier claims of higher performance were mistaken due to data leakage during the evaluation process.

Abstract Image

Abstract Image

从皮肤镜图像中以无创方式预测黑色素瘤病变厚度的机器学习系统的设计。
目的:黑色素瘤是最致命的皮肤癌,但99%的病例可以通过早期发现和治疗完全治愈。我们的目标是开发一种非侵入性机器学习系统,该系统可以通过皮肤镜图像预测黑色素瘤病变的厚度,这是肿瘤进展的代表。这种方法可作为确定需要治疗的紧急病例的宝贵工具。方法:利用现代卷积神经网络架构(EfficientNet)构建一个模型,该模型能够将皮肤镜下黑色素瘤病变图像根据厚度分为三种不同的类别。我们结合了技术来减少不平衡训练数据集的影响,通过图像增强增强模型的泛化能力,并利用五倍交叉验证来产生更可靠的指标。结果:在247张黑色素瘤图像的小型公共数据集上训练时,我们的方法实现了71%的三向分类平衡准确率。我们还提出了大型训练数据集的性能预测。结论:我们的模型代表了一种新的最先进的黑色素瘤厚度分类方法。通过扩展训练数据集和利用模型集成可以进一步优化性能。我们已经证明,由于评估过程中的数据泄露,早期声称更高性能的说法是错误的。
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来源期刊
Healthcare Informatics Research
Healthcare Informatics Research MEDICAL INFORMATICS-
CiteScore
4.90
自引率
6.90%
发文量
44
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