Algorithmic framework for HEp-2 fluorescence pattern classification to aid auto-immune diseases diagnosis

Elbischger, Pierre; Geerts, Stig; Sander, Kåre; Ziervogel-Lukas, G.; Sinah, P.

doi:10.1109/isbi.2009.5193109

Cited by 20 publications

(23 citation statements)

References 7 publications

(8 reference statements)

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“…The cause of all auto-immune diseases is an unwanted immune response against human cell structures being wrongly interpreted and fought as foreign bodies. Often the course of the disease is chronic and leads to seriously damaging tissue and organs [4]. Examples of such autoimmune diseases are Rheumatoid Arthritis, Multiple Sclerosis and Diabetes mellitus type 1.…”

Section: Introductionmentioning

confidence: 99%

HEp-2 cell pattern segmentation for the support of autoimmune disease diagnosis

Creemers

Guerti

Geerts

et al. 2011

Proceedings of the 4th International Symposium on Applied Sciences in Biomedical and Communication Technologies

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The Indirect Immune Fluorescence Test (iIFT) is the most commonly used screening method for the diagnosis of autoimmune diseases. The presence of certain autoimmune diseases is proven by immunologically detecting their corresponding auto-antibodies using the HEp-2 cancer cell line. For this purpose HEp-2 cells are added to the patients' blood serum containing certain auto-antibodies which will bond with the HEp-2 cells leading to a wide variety of patterns that can be observed under a fluorescence microscope. Due to the disadvantages of manual testing, automation and standardization are necessary. This paper proposes an unsupervised segmentation algorithm as part of an ongoing research to develop a CAD system to digitally support iIFT testing.

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Section: Introductionmentioning

confidence: 99%

HEp-2 cell pattern segmentation for the support of autoimmune disease diagnosis

Creemers

Guerti

Geerts

et al. 2011

Proceedings of the 4th International Symposium on Applied Sciences in Biomedical and Communication Technologies

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“…It was shown that the segmentation performance of the proposed method achieved 89 % when evaluated based on percent volume overlap (PVO) rate [13,14]. The classification performance using a support vector machine (SVM) [15,16] classifier designed based on the features calculated from the segmented cells achieved an average accuracy of 96.90 %, outperforming the methods proposed in other previous studies [1,[5][6][7][8][9][10].…”

Section: Introductionmentioning

confidence: 83%

“…Generally, these systems include a module for image segmentation designed based on Otsu thresholding [1][2][3] and watershed segmentation [4], and another module for image recognition built based on various pattern recognition methods [1,[5][6][7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Design of a Computer-Assisted System to Automatically Detect Cell Types Using ANA IIF Images for the Diagnosis of Autoimmune Diseases

Cheng

Hsieh

et al. 2015

J Med Syst

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Indirect immunofluorescence technique applied on HEp-2 cell substrates provides the major screening method to detect ANA patterns in the diagnosis of autoimmune diseases. Currently, the ANA patterns are mostly inspected by experienced physicians to identify abnormal cell patterns. The objective of this study is to design a computer-assisted system to automatically detect cell patterns of IIF images for the diagnosis of autoimmune diseases in the clinical setting. The system simulates the functions of modern flow cytometer and provides the diagnostic reports generated by the system to the technicians and physicians through the radar graphs, box-plots, and tables. The experimental results show that, among the IIF images collected from 17 patients, 6 were classified as coarse-speckled, 3 as diffused, 2 as discrete-speckled, 1 as fine-speckled, 2 as nucleolar, and 3 as peripheral patterns, which were consistent with the patterns determined by the physicians. In addition to recognition of cell patterns, the system also provides the function to automatically generate the report for each patient. The time needed for the whole procedure is less than 30 min, which is more efficient than the manual operation of the physician after inspecting the ANA IIF images. Besides, the system can be easily deployed on many desktop and laptop computers. In conclusion, the designed system, containing functions for automatic detection of ANA cell pattern and generation of diagnostic report, is effective and efficient to assist physicians to diagnose patients with autoimmune diseases. The limitations of the current developed system include (1) only a unique cell pattern was considered for the IIF images collected from a patient, and (2) the cells during the process of mitosis were not adopted for cell classification.

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“…Perner et al [23] Textural Decision Tree Hiemann et al [15] Structural; textural LogisticModel Tree Elbischger et al [8] Image statistics; cell shape; textural Nearest Neighbour (NN) Hsieh et al [16] Image statistics; textural Learning Vector Quantisation (LVQ) Soda et al [34] Specific set of features (e.g. textural) for each class Multi Expert System Cordelli et al [7] Image statistics; textural; morphological AdaBoost Strandmark et al [35] Morphological; image statistics; textural Random Forest Ali et al [2] Biological-Inspired Descriptor Boosted k-NN Classifier Theodorakopoulos et al [36] Morphological and texture features Kernel SVM (KSVM) Thibault et al [37] Morphological and texture features Linear Regression, Random Forest Ghosh et al [13] Histograms of Oriented Gradients, SVM image statistics and textural Li et al [19] Textural and image statistics SVM Di Cataldo et al [5] GLCM and DCT features SVM Snell et al [33] Texture and shape Multistage classifier Ersoy et al [9] Local shape measures, gradient and textural ShareBoost Wiliem et al [41] Bag of visual words with dual-region structure Nearest Convex Hull Classifier (NCH) and apply an automated feature selection process [15].…”

Section: Approach Descriptors Classifiermentioning

confidence: 99%

Automatic Classification of Human Epithelial Type 2 Cell Indirect Immunofluorescence Images using Cell Pyramid Matching

Wiliem

Sanderson²,

Wong³

et al. 2014

Preprint

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This paper describes a novel system for automatic classification of images obtained from Anti-Nuclear Antibody (ANA) pathology tests on Human Epithelial type 2 (HEp-2) cells using the Indirect Immunofluorescence (IIF) protocol. The IIF protocol on HEp-2 cells has been the hallmark method to identify the presence of ANAs, due to its high sensitivity and the large range of antigens that can be detected. However, it suffers from numerous shortcomings, such as being subjective as well as time and labour intensive. Computer Aided Diagnostic (CAD) systems have been developed to address these problems, which automatically classify a HEp-2 cell image into one of its known patterns (eg. speckled, homogeneous). Most of the existing CAD systems use handpicked features to represent a HEp-2 cell image, which may only work in limited scenarios. We propose a novel automatic cell image classification method termed Cell Pyramid Matching (CPM), which is comprised of regional histograms of visual words coupled with the Multiple Kernel Learning framework. We present a study of several variations of generating histograms and show the efficacy of the system on two publicly available datasets: the ICPR HEp-2 cell classification contest dataset and the SNPHEp-2 dataset.

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Algorithmic framework for HEp-2 fluorescence pattern classification to aid auto-immune diseases diagnosis

Cited by 20 publications

References 7 publications

HEp-2 cell pattern segmentation for the support of autoimmune disease diagnosis

HEp-2 cell pattern segmentation for the support of autoimmune disease diagnosis

Design of a Computer-Assisted System to Automatically Detect Cell Types Using ANA IIF Images for the Diagnosis of Autoimmune Diseases

Automatic Classification of Human Epithelial Type 2 Cell Indirect Immunofluorescence Images using Cell Pyramid Matching

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