Clinical dermatology, still relies heavily on manual introspection of fungi within a Potassium Hydroxide (KOH) solution using a brightfield microscope. However, this method takes a long time, is based on the experience of the clinician, and has a low accuracy. With the increase of neural network applications in the field of clinical microscopy it is now possible to automate such manual processes increasing both efficiency and accuracy. This study presents a deep neural network structure that enables the rapid solutions for these problems and can perform automatic fungi detection in grayscale images without colorants. Microscopic images of 81 fungi and 235 ceratine were collected. Then, smaller patches were extracted containing 2062 fungi and 2142 ceratine. In order to detect fungus and ceratine, two models were created one of which was a custom neural network and the other was based on the VGG16 architecture. The developed custom model had 99.84% accuracy, and an area under the curve (AUC) value of 1.00, while the VGG16 model had 98.89% accuracy and an AUC value of 0.99. However, average accuracy and AUC value of clinicians is 72.8% and 0.87 respectively. This deep learning model allows the development of an automated system that can detect fungi within microscopic images.
翻译:临床皮肤学仍然严重依赖使用亮地显微镜在Potassium Hydroxide(KOH)溶液中人工透视真菌。 但是,这种方法需要很长的时间,以临床医生的经验为基础,而且精度低。随着临床显微镜领域神经网络应用的增加,现在有可能使这种人工过程自动化,既提高效率,又准确性。本研究展示了一个深厚的神经网络结构,能够迅速解决这些问题,并在没有色素的灰色图像中进行自动真菌检测。收集了81个真菌和235个西拉廷的微镜图像。随后,提取了包含2062个真菌和2142个西拉廷的小型补丁。为了检测真菌和西拉廷,现已创建了两个模型,其中一种是定制神经网络,另一种是VGG16结构。开发的定制模型准确性达到99.84%,一个在1.00的曲线下区域(AUSC),而VG16模型具有98.89%的微菌图像和23的微拉平面图像。这个模型在AS平均和72个AUC系统内具有0.89的精确度值。
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