Related papers: A survey on automated detection and classification of acute leukemia and WBCs in microscopic blood cells

A survey on automated detection and classification of acute leukemia and WBCs in microscopic blood cells

URL: http://arxiv.org/abs/2303.03916v2
Date: Wed, 8 Mar 2023 19:56:08 GMT
Title: A survey on automated detection and classification of acute leukemia and WBCs in microscopic blood cells
Authors: Mohammad Zolfaghari and Hedieh Sajedi
Abstract summary: Leukemia (blood cancer) is an unusual spread of White Blood Cells or Leukocytes (WBCs) in the bone marrow and blood. Traditional machine learning and deep learning techniques are practical roadmaps that increase the accuracy and speed in diagnosing and classifying medical images. This paper provides a comprehensive analysis of the detection and classification of acute leukemia and WBCs in the microscopic blood cells.
Score: 6.117084972237769
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: Leukemia (blood cancer) is an unusual spread of White Blood Cells or Leukocytes (WBCs) in the bone marrow and blood. Pathologists can diagnose leukemia by looking at a person's blood sample under a microscope. They identify and categorize leukemia by counting various blood cells and morphological features. This technique is time-consuming for the prediction of leukemia. The pathologist's professional skills and experiences may be affecting this procedure, too. In computer vision, traditional machine learning and deep learning techniques are practical roadmaps that increase the accuracy and speed in diagnosing and classifying medical images such as microscopic blood cells. This paper provides a comprehensive analysis of the detection and classification of acute leukemia and WBCs in the microscopic blood cells. First, we have divided the previous works into six categories based on the output of the models. Then, we describe various steps of detection and classification of acute leukemia and WBCs, including Data Augmentation, Preprocessing, Segmentation, Feature Extraction, Feature Selection (Reduction), Classification, and focus on classification step in the methods. Finally, we divide automated detection and classification of acute leukemia and WBCs into three categories, including traditional, Deep Neural Network (DNN), and mixture (traditional and DNN) methods based on the type of classifier in the classification step and analyze them. The results of this study show that in the diagnosis and classification of acute leukemia and WBCs, the Support Vector Machine (SVM) classifier in traditional machine learning models and Convolutional Neural Network (CNN) classifier in deep learning models have widely employed. The performance metrics of the models that use these classifiers compared to the others model are higher.

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