A novel automated image analysis system using deep convolutional neural networks can assist to differentiate MDS and AA

Kimura, Konobu; Tabe, Yoko; Ai, Tomohiko; Takehara, Ikki; Fukuda, Hiroshi; Takahashi, Hiromizu; Naito, Toshio; Komatsu, Norio; Uchihashi, Kinya; Ohsaka, Akimichi

doi:10.1038/s41598-019-49942-z

Cited by 67 publications

(53 citation statements)

References 26 publications

(30 reference statements)

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“…This compliments other novel AI strategies aimed at utilizing mutational and peripheral blood data for more accurate MPN diagnosis, 30 along with improved interpretation of peripheral blood/bone marrow smear preparations. [31][32][33][34] Secondly, a comprehensive and easily interpreted summary of the megakaryocytic population will enable the pathologist to concentrate on the "higher-level" process of integrating the broader pathological features with the clinical and laboratory findings. Thirdly, this approach is ideally suited for more accurate assessment of sequential specimens from patients undergoing treatment and/or repeated investigation, in whom quantitative morphological correlates of disease response are currently unavailable.…”

Section: Discussionmentioning

confidence: 99%

Artificial intelligence–based morphological fingerprinting of megakaryocytes: a new tool for assessing disease in MPN patients

Sirinukunwattana

Aberdeen²,

Theissen

et al. 2020

Blood Advances

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Accurate diagnosis and classification of myeloproliferative neoplasms (MPNs) requires integration of clinical, morphological, and genetic findings. Despite major advances in our understanding of the molecular and genetic basis of MPNs, the morphological assessment of bone marrow trephines (BMT) is critical in differentiating MPN subtypes and their reactive mimics. However, morphological assessment is heavily constrained by a reliance on subjective, qualitative, and poorly reproducible criteria. To improve the morphological assessment of MPNs, we have developed a machine learning approach for the automated identification, quantitative analysis, and abstract representation of megakaryocyte features using reactive/nonneoplastic BMT samples (n = 43) and those from patients with established diagnoses of essential thrombocythemia (n = 45), polycythemia vera (n = 18), or myelofibrosis (n = 25). We describe the application of an automated workflow for the identification and delineation of relevant histological features from routinely prepared BMTs. Subsequent analysis enabled the tissue diagnosis of MPN with a high predictive accuracy (area under the curve = 0.95) and revealed clear evidence of the potential to discriminate between important MPN subtypes. Our method of visually representing abstracted megakaryocyte features in the context of analyzed patient cohorts facilitates the interpretation and monitoring of samples in a manner that is beyond conventional approaches. The automated BMT phenotyping approach described here has significant potential as an adjunct to standard genetic and molecular testing in established or suspected MPN patients, either as part of the routine diagnostic pathway or in the assessment of disease progression/response to treatment.

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Section: Discussionmentioning

confidence: 99%

Artificial intelligence–based morphological fingerprinting of megakaryocytes: a new tool for assessing disease in MPN patients

Sirinukunwattana

Aberdeen²,

Theissen

et al. 2020

Blood Advances

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“…Image analyses. To perform analyses of the cell images, we employed the CNN-based automatic imagerecognition system that we recently developed 10 . Briefly, the deep learning system (DLS) was trained using a .…”

Section: Methodsmentioning

confidence: 99%

“…SHAP values close to 1 denote high likelihood, whereas those close to -1 denote less likelihood. https://doi.org/10.1038/s41598-021-82826-9www.nature.com/scientificreports/ total of 695,030 normal and abnormal cell images, and we could accurately classify 17 cell subtypes and detect 97 abnormal morphological features10 . The neural network was composed of two modules: the first module consisting of series of neural networks layers such as 2 dimensional Separative convolutional neural-network (CNN) based "image extractor" module, and the second module consisting of the layers connected to the output module.…”

mentioning

confidence: 99%

“…In order to reduce the workload and inter-and intra-personal inconsistency, we previously developed an automated image analysis system using deep convolutional neural networks (CNNs) based-image analysis algorithms using a total of 695,030 normal and abnormal blood cells. Using the system, we could differentiate myelodysplastic syndrome (MDS) and aplastic anemia with high accuracy compared to human diagnoses 8 .…”

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confidence: 99%

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Automated diagnostic support system with deep learning algorithms for distinction of Philadelphia chromosome-negative myeloproliferative neoplasms using peripheral blood specimen

Kimura

Horiuchi

et al. 2021

Sci Rep

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Philadelphia chromosome-negative myeloproliferative neoplasms (Ph-negative MPNs) such as polycythemia vera (PV), essential thrombocythemia (ET), and primary myelofibrosis are characterized by abnormal proliferation of mature bone marrow cell lineages. Since various non-hematologic disorders can also cause leukocytosis, thrombocytosis and polycythemia, the detection of abnormal peripheral blood cells is essential for the diagnostic screening of Ph-negative MPNs. We sought to develop an automated diagnostic support system of Ph-negative MPNs. Our strategy was to combine the complete blood cell count and research parameters obtained by an automated hematology analyzer (Sysmex XN-9000) with morphological parameters that were extracted using a convolutional neural network deep learning system equipped with an Extreme Gradient Boosting (XGBoost)-based decision-making algorithm. The developed system showed promising performance in the differentiation of PV, ET, and MF with high accuracy when compared with those of the human diagnoses, namely: > 90% sensitivity and > 90% specificity. The calculated area under the curve of the ROC curves were 0.990, 0.967, and 0.974 for PV, ET, MF, respectively. This study is a step toward establishing a universal automated diagnostic system for all types of hematology disorders.

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“…Machine learning methods like convolutional neural networks (CNNs) have proven to be quite successful in detecting image features and could potentially be utilized to automate (aspects of) PB analyses. Indeed, CNNs have been used to differentiate between leukocytes, 3 and to detect myelodysplastic syndromes in PBSs 4 . In this study, we present an automated pipeline based on CNNs that enabled us to successfully detect and quantify lymphocyte vacuolization as observed in PBSs of CLN3 disease patients.…”

Section: Introductionmentioning

confidence: 99%

Automatic quantification of lymphocyte vacuolization in peripheral blood smears of patients with Batten's disease (CLN3 disease)

et al. 2021

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Quantifying lymphocyte vacuolization in peripheral blood smears (PBSs) serves as a measure for disease severity in CLN3 disease—a lysosomal storage disorder of childhood‐onset. However, thus far quantification methods are based on labor‐intensive manual assessment of PBSs. As machine learning techniques like convolutional neural networks (CNNs) have been deployed quite successfully in detecting pathological features in PBSs, we explored whether these techniques could be utilized to automate quantification of lymphocyte vacuolization. Here, we present and validate a deep learning pipeline that automates quantification of lymphocyte vacuolization. By using two CNNs in succession, trained for cytoplasm‐segmentation and vacuolization‐detection, respectively, we obtained an excellent correlation with manual quantification of lymphocyte vacuolization (r = 0.98, n = 40). These results show that CNNs can be utilized to automate the otherwise cumbersome task of manually quantifying lymphocyte vacuolization, thereby aiding prompt clinical decisions in relation to CLN3 disease, and potentially beyond.

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A novel automated image analysis system using deep convolutional neural networks can assist to differentiate MDS and AA

Cited by 67 publications

References 26 publications

Artificial intelligence–based morphological fingerprinting of megakaryocytes: a new tool for assessing disease in MPN patients

Artificial intelligence–based morphological fingerprinting of megakaryocytes: a new tool for assessing disease in MPN patients

Automated diagnostic support system with deep learning algorithms for distinction of Philadelphia chromosome-negative myeloproliferative neoplasms using peripheral blood specimen

Automatic quantification of lymphocyte vacuolization in peripheral blood smears of patients with Batten's disease (CLN3 disease)

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