Deep Learning-Based Cell Detection and Extraction in Thin Blood Smears for Malaria Diagnosis.

Deniz Kavzak Ufuktepe, Feng Yang, Yasmin M Kassim, Hang Yu, Richard J Maude, Kannappan Palaniappan, Stefan Jaeger
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Abstract

Malaria is a major health threat caused by Plasmodium parasites that infect the red blood cells. Two predominant types of Plasmodium parasites are Plasmodium vivax (P. vivax) and Plasmodium falciparum (P. falciparum). Diagnosis of malaria typically involves visual microscopy examination of blood smears for malaria parasites. This is a tedious, error-prone visual inspection task requiring microscopy expertise which is often lacking in resource-poor settings. To address these problems, attempts have been made in recent years to automate malaria diagnosis using machine learning approaches. Several challenges need to be met for a machine learning approach to be successful in malaria diagnosis. Microscopy images acquired at different sites often vary in color, contrast, and consistency caused by different smear preparation and staining methods. Moreover, touching and overlapping cells complicate the red blood cell detection process, which can lead to inaccurate blood cell counts and thus incorrect parasitemia calculations. In this work, we propose a red blood cell detection and extraction framework to enable processing and analysis of single cells for follow-up processes like counting infected cells or identifying parasite species in thin blood smears. This framework consists of two modules: a cell detection module and a cell extraction module. The cell detection module trains a modified Channel-wise Feature Pyramid Network for Medicine (CFPNet-M) deep learning network that takes the green channel of the image and the color-deconvolution processed image as inputs, and learns a truncated distance transform image of cell annotations. CFPNet-M is chosen due to its low resource requirements, while the distance transform allows achieving more accurate cell counts for dense cells. Once the cells are detected by the network, the cell extraction module is used to extract single cells from the original image and count the number of cells. Our preliminary results based on 193 patients (including 148 P. Falciparum infected patients, and 45 uninfected patients) show that our framework achieves cell count accuracy of 92.2%.

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基于深度学习的细胞检测与提取,用于疟疾诊断的薄血涂片。
疟疾是由感染红血球的疟原虫引起的主要健康威胁。两种主要的疟原虫是间日疟原虫(间日疟)和恶性疟原虫(恶性疟)。疟疾的诊断通常需要用肉眼显微镜检查血液涂片上的疟原虫。这是一项繁琐、容易出错的目视检查任务,需要显微镜专业技术,而在资源匮乏的环境中往往缺乏这种技术。为了解决这些问题,近年来人们尝试利用机器学习方法实现疟疾诊断自动化。机器学习方法要在疟疾诊断中取得成功,需要应对几个挑战。由于涂片制备和染色方法不同,在不同地点获取的显微镜图像在颜色、对比度和一致性上往往存在差异。此外,细胞接触和重叠也会使红细胞检测过程复杂化,从而导致血细胞计数不准确,进而导致寄生虫血症计算错误。在这项工作中,我们提出了一个红细胞检测和提取框架,以便处理和分析单个细胞,进行后续处理,如计数感染细胞或识别薄血涂片中的寄生虫种类。该框架由两个模块组成:细胞检测模块和细胞提取模块。细胞检测模块训练一个改进的医学通道式特征金字塔网络(CFPNet-M)深度学习网络,该网络将图像的绿色通道和颜色去卷积处理后的图像作为输入,并学习细胞注释的截断距离变换图像。之所以选择 CFPNet-M,是因为它对资源的要求较低,而距离变换则可以实现更精确的密集细胞计数。网络检测到细胞后,细胞提取模块将用于从原始图像中提取单个细胞并计算细胞数量。基于 193 名患者(包括 148 名疟原虫感染患者和 45 名未感染患者)的初步结果显示,我们的框架实现了 92.2% 的细胞计数准确率。
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Axon and Myelin Sheath Segmentation in Electron Microscopy Images using Meta Learning. Deep Learning-Based Cell Detection and Extraction in Thin Blood Smears for Malaria Diagnosis. Patch-Based Semantic Segmentation for Detecting Arterioles and Venules in Epifluorescence Imagery. Confocal Vessel Structure Segmentation with Optimized Feature Bank and Random Forests. The National Library of Medicine Pill Image Recognition Challenge: An Initial Report.
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