A counting method for complex overlapping erythrocytes-based microscopic imaging

Wei, Xudong; Cao, Yiping; Fu, Guangkai; Wang, Yapin

doi:10.1142/s1793545815500339

Cited by 8 publications

(4 citation statements)

References 17 publications

(16 reference statements)

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“…Using a non-optimised computer programme code on a Dual Core Intel Pentium E5300 central processing unit at 2.6 GHz with 2 GB random access memory, and 64 bits Windows 7 Home Premium operating system, the average running time of our method was 20.29 s/image. This is less than a half of the excellent time taken with Wei et al [28] using a comparable processor, which took 49.86 s/image to identify the markers of individual cells using the watershed transform and K-means for detecting and splitting clustered cells.…”

Section: Runtime Analysismentioning

confidence: 96%

Automated marker identification using the Radon transform for watershed segmentation

González-Betancourt

Rodríguez-Ribalta

Meneses‐Marcel

et al. 2017

IET Image Processing

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Section: Runtime Analysismentioning

confidence: 96%

Automated marker identification using the Radon transform for watershed segmentation

González-Betancourt

Rodríguez-Ribalta

Meneses‐Marcel

et al. 2017

IET Image Processing

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“…Blood cells were easily identified by this method using a unique color of every component. Wei et al [ 157 ] proposed a method to detect and count overlapped RBCs in microscopic blood smear images. The H and S components were used to differentiate between WBCs and segmented RBCs.…”

Section: Approachesmentioning

confidence: 99%

“…of images(Stain) Accuracy(%) Remarks Ref. K-means clustering, WT 60 (Giemsa )100 (Wright–Giemsa) 93–98.9 Robustness is not explained [ 11 , 140 , 157 ] Iterative structured circle detection, circlet transform 100 95.3 Incorrect hole filling leads to errors To improve initial RBCs mask for accurate segmentation [ 28 , 143 ] Graph algorithm 98 99 Considered only non-overlapped cells [ 133 ] Parametric template matching, PCNN 900 cells 90–95.7 Require prior knowledge about the appearance of the cell [ 16 , 46 , 98 ] YOLO algorithm 364 96.1 Satisfactory performance [ 20 ] HSV conversion, morphological operations 200 (Giemsa) 96 Used uniform staining and illumination [ 125 ] Pixel relationship 10 (MGG) 83 Occluded objects are rejected before the later stages [ 80 ] Canny, LOG, Sobel 20–30 85–93 Normal RBCs Less samples [ …”

Section: Approachesmentioning

confidence: 99%

Analysis of red blood cells from peripheral blood smear images for anemia detection: a methodological review

Navya

Prasad

Singh

2022

Med Biol Eng Comput

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Anemia is a blood disorder which is caused due to inadequate red blood cells and hemoglobin concentration. It occurs in all phases of life cycle but is more dominant in pregnant women and infants. According to the survey conducted by the World Health Organization (WHO) (McLean et al., Public Health Nutr 12(4):444–454, 2009), anemia affects 1.62 billion people constituting 24.8% of the population and is considered the world’s second leading cause of illness. The Peripheral Blood Smear (PBS) examination plays an important role in evaluating hematological disorders. Anemia is diagnosed using PBS. Being the most powerful analytical tool, manual analysis approach is still in use even though it is tedious, prone to errors, time-consuming and requires qualified laboratorians. It is evident that there is a need for an inexpensive, automatic and robust technique to detect RBC disorders from PBS. Automation of PBS analysis is very active field of research that motivated many research groups to develop methods using image processing. In this paper, we present a review of the methods used to analyze the characteristics of RBC from PBS images using image processing techniques. We have categorized these methods into three groups based on approaches such as RBC segmentation, RBC classification and detection of anemia, and classification of anemia. The outcome of this review has been presented as a list of observations. Graphical abstract

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“…Therefore overlapping cells were separated out from the database. In the literature various measures have been used to identify single and overlapping cells (area / convexity / eccentricity (Wei et al, 2015;Abu-Qasmieh, 2018)) but as there were more class types and very different cell shapes in this dataset, this was not sufficient for adequate identification.…”

Section: Separating Single and Overlapped Cellsmentioning

confidence: 99%

Analysis of Vision-based Abnormal Red Blood Cell Classification

Wong,

Anantrasirichai,

Chalidabhongse

et al. 2021

Preprint

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Identification of abnormalities in red blood cells (RBC) is key to diagnosing a range of medical conditions from anaemia to liver disease. Currently this is done manually, a time-consuming and subjective process. This paper presents an automated process utilising the advantages of machine learning to increase capacity and standardisation of cell abnormality detection, and its performance is analysed. Three different machine learning technologies were used: a Support Vector Machine (SVM), a classical machine learning technology; TabNet, a deep learning architecture for tabular data; U-Net, a semantic segmentation network designed for medical image segmentation. A critical issue was the highly imbalanced nature of the dataset which impacts the efficacy of machine learning. To address this, synthesising minority class samples in feature space was investigated via Synthetic Minority Over-sampling Technique (SMOTE) and cost-sensitive learning. A combination of these two methods is investigated to improve the overall performance. These strategies were found to increase sensitivity to minority classes. The impact of unknown cells on semantic segmentation is demonstrated, with some evidence of the model applying learning of labelled cells to these anonymous cells. These findings indicate both classical models and new deep learning networks as promising methods in automating RBC abnormality detection.

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A counting method for complex overlapping erythrocytes-based microscopic imaging

Cited by 8 publications

References 17 publications

Automated marker identification using the Radon transform for watershed segmentation

Automated marker identification using the Radon transform for watershed segmentation

Analysis of red blood cells from peripheral blood smear images for anemia detection: a methodological review

Analysis of Vision-based Abnormal Red Blood Cell Classification

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