Super-Resolution Digital Pathology Image Processing of Bone Marrow Aspirate and Cytology Smears and Tissue Sections

Singh, Amol; Ohgami, Robert S.

doi:10.4103/jpi.jpi_56_18

Cited by 9 publications

(11 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The notable performance of the software stems partly from its pre-processing algorithm. While we utilize standard equalization and smoothing operations seen in other studies [41–43], we also employ an enhanced binarizations step with a Gaussian filter to better account for the dynamic intensity variations of different cilia candidates (Fig. 2).…”

Section: Discussionmentioning

confidence: 99%

New software for automated cilia detection in cells (ACDC)

Lauring

Zhu

Luo

et al. 2019

Cilia

View full text Add to dashboard Cite

Background Primary cilia frequency and length are key metrics in studies of ciliogenesis and ciliopathies. Typically, quantitative cilia analysis is done manually, which is very time-consuming. While some open-source and commercial image analysis software applications can segment input data, they still require the user to optimize many parameters, suffer from user bias, and often lack rigorous performance quality assessment (e.g., false positives and false negatives). Further, optimal parameter combinations vary in detection accuracy depending on cilia reporter, cell type, and imaging modality. A good automated solution would analyze images quickly, robustly, and adaptably—across different experimental data sets—without significantly compromising the accuracy of manual analysis. Methods To solve this problem, we developed a new software for a utomated c ilia d etection in c ells (ACDC). The software operates through four main steps: image importation, pre-processing, detection auto-optimization, and analysis. From a data set, a representative image with manually selected cilia (i.e., Ground Truth) is used for detection auto-optimization based on four parameters: signal-to-noise ratio, length, directional score, and intensity standard deviation. Millions of parameter combinations are automatically evaluated and optimized according to an accuracy ‘F1’ score, based on the amount of false positives and false negatives. Afterwards, the optimized parameter combination is used for automated detection and analysis of the entire data set. Results The ACDC software accurately and adaptably detected nuclei and primary cilia across different cell types (NIH3T3, RPE1), cilia reporters (AcTub, Smo-GFP, Arl13b), and image magnifications (60×, 40×). We found that false-positive and false-negative rates for Arl13b-stained cilia were 1–6%, yielding high F1 scores of 0.96–0.97 (max. = 1.00). The software detected significant differences in mean cilia length between control and cytochalasin D-treated cell populations and could monitor dynamic changes in cilia length from movie recordings. Automated analysis offered up to a 96-fold speed enhancement compared to manual analysis, requiring around 5 s/image, or nearly 18,000 cilia analyzed/hour. Conclusion The ACDC software is a solution for robust automated analysis of microscopic images of ciliated cells. The software is extremely adaptable, accurate, and offers immense time-savings compared to traditional manual analysis. Electronic supplementary material The online version of this article (10.1186/s13630-019-0061-z) contains supplementary material, which is available to authorized users.

show abstract

Section: Discussionmentioning

confidence: 99%

New software for automated cilia detection in cells (ACDC)

Lauring

Zhu

Luo

et al. 2019

Cilia

View full text Add to dashboard Cite

show abstract

“… 75 , 76 , 77 In contrast to common solid tumors, image analysis has seen relatively limited application to disorders of the bone marrow, with most studies describing strategies for cell identification, quantification, and the resolution of specific leukemic differential diagnoses including B-ALL and common B-cell lymphoma/leukemia subtypes. 78 , 79 , 80 , 81 , 82 , 83 These machine learning strategies have generally relied on morphology-based criteria to distinguish tumor cell subtypes rather than interrogate tumor cells with the intention of gaining novel insights into disease biology. However, recently machine learning has been used to correlate bone marrow aspirate morphologic features with somatic mutations in myelodysplastic syndrome, with specific morphologic profiles linked to unique clinical characteristics.…”

Section: Digital Pathologymentioning

confidence: 99%

Application of Single-Cell Approaches to Study Myeloproliferative Neoplasm Biology

Royston

Mead

Psaila

2021

Hematology/Oncology Clinics of North America

View full text Add to dashboard Cite

Philadelphia-negative myeloproliferative neoplasms (MPNs) are an excellent tractable disease model of a number of aspects of human cancer biology, including genetic evolution, tissue-associated fibrosis, and cancer stem cells. In this review, we discuss recent insights into MPN biology gained from the application of a number of new single-cell technologies to study human disease, with a specific focus on single-cell genomics, single-cell transcriptomics, and digital pathology.

show abstract

“…The program consists of constructing a super-resolution image from multiple images to create a three-dimensional digital picture. The algorithm allowed a significant improvement in image sharpness and resolution when applied to BM aspirate smears [33].…”

Section: Digital Pathology For the Diagnosis Of Acute And Chronic Leumentioning

confidence: 99%

“…Other groups trained supervised models for segmentation and classification of ALL, mainly the support vector machine (SVM) algorithm. The overall accuracy for the detection of lymphoblasts and differentiating them from reactive lymphoid cells ranged from 74% to 99%, with a sensitivity as high as 100% and a specificity up to 95% [33]. The best outcomes were obtained by Bhattacharjee et al, who collected 120 cases and used pattern recognition-based segmentation to train and compare the results of multiple classifiers, including artificial neural network (ANN), k-nearest neighbor (kNN), k-means, and support vector machine (SVM) [47].…”

Section: Digital Pathology For the Diagnosis Of Acute And Chronic Leumentioning

confidence: 99%

Artificial Intelligence and Digital Microscopy Applications in Diagnostic Hematopathology

Achi

Khoury

2020

Cancers

View full text Add to dashboard Cite

Digital Pathology is the process of converting histology glass slides to digital images using sophisticated computerized technology to facilitate acquisition, evaluation, storage, and portability of histologic information. By its nature, digitization of analog histology data renders it amenable to analysis using deep learning/artificial intelligence (DL/AI) techniques. The application of DL/AI to digital pathology data holds promise, even if the scope of use cases and regulatory framework for deploying such applications in the clinical environment remains in the early stages. Recent studies using whole-slide images and DL/AI to detect histologic abnormalities in general and cancer in particular have shown encouraging results. In this review, we focus on these emerging technologies intended for use in diagnostic hematology and the evaluation of lymphoproliferative diseases.

show abstract

Super-Resolution Digital Pathology Image Processing of Bone Marrow Aspirate and Cytology Smears and Tissue Sections

Cited by 9 publications

References 25 publications

New software for automated cilia detection in cells (ACDC)

New software for automated cilia detection in cells (ACDC)

Application of Single-Cell Approaches to Study Myeloproliferative Neoplasm Biology

Artificial Intelligence and Digital Microscopy Applications in Diagnostic Hematopathology

Contact Info

Product

Resources

About