Dr. Andrew Janowczyk Profile

Dr. Andrew Janowczyk

SPIE Involvement:

Author

SPIE Journal Paper | 10 October 2024 Open Access

Characterization of arteriosclerosis based on computer-aided measurements of intra-arterial thickness

Jin Zhou, Xiang Li, Dawit Demeke, Timothy A. Dinh, Yingbao Yang, Andrew Janowczyk, Jarcy Zee, Lawrence Holzman, Laura Mariani, Krishnendu Chakrabarty, Laura Barisoni, Jeffrey Hodgin, Kyle J. Lafata

JMI, Vol. 11, Issue 05, 057501, (October 2024) https://doi.org/10.1117/12.10.1117/1.JMI.11.5.057501

KEYWORDS: Arteries, Image segmentation, Tissues, Pathology, Kidney, Feature extraction, Deformation, Biopsy, Tunable filters, Distortion

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PurposeOur purpose is to develop a computer vision approach to quantify intra-arterial thickness on digital pathology images of kidney biopsies as a computational biomarker of arteriosclerosis.ApproachThe severity of the arteriosclerosis was scored (0 to 3) in 753 arteries from 33 trichrome-stained whole slide images (WSIs) of kidney biopsies, and the outer contours of the media, intima, and lumen were manually delineated by a renal pathologist. We then developed a multi-class deep learning (DL) framework for segmenting the different intra-arterial compartments (training dataset: 648 arteries from 24 WSIs; testing dataset: 105 arteries from 9 WSIs). Subsequently, we employed radial sampling and made measurements of media and intima thickness as a function of spatially encoded polar coordinates throughout the artery. Pathomic features were extracted from the measurements to collectively describe the arterial wall characteristics. The technique was first validated through numerical analysis of simulated arteries, with systematic deformations applied to study their effect on arterial thickness measurements. We then compared these computationally derived measurements with the pathologists’ grading of arteriosclerosis.ResultsNumerical validation shows that our measurement technique adeptly captured the decreasing smoothness in the intima and media thickness as the deformation increases in the simulated arteries. Intra-arterial DL segmentations of media, intima, and lumen achieved Dice scores of 0.84, 0.78, and 0.86, respectively. Several significant associations were identified between arteriosclerosis grade and pathomic features using our technique (e.g., intima-media ratio average [τ=0.52, p<0.0001]) through Kendall’s tau analysis.ConclusionsWe developed a computer vision approach to computationally characterize intra-arterial morphology on digital pathology images and demonstrate its feasibility as a potential computational biomarker of arteriosclerosis.

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Proceedings Article | 7 April 2023 Presentation + Paper

Spatial connectivity of tumor and associated cells (SpaCell): a novel computational pathology biomarker

Germán Corredor, Can Koyuncu, Andrew Janowczyk, Paula Toro, Sepideh Azarianpour, James Lewis, Anant Madabhushi

Proceedings Volume 12471, 124710U (2023) https://doi.org/10.1117/12.2653950

KEYWORDS: Tumors, Cancer, Lung cancer, Image segmentation, Deep learning, Lung, Education and training, Pulmonary disorders, Medical research, Tumor growth modeling

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Proceedings Article | 16 March 2020 Presentation + Paper

Three-dimensional histo-morphometric features from light sheet microscopy images result in improved discrimination of benign from malignant glands in prostate cancer

Can Koyuncu, Andrew Janowczyk, Cheng Lu, Patrick Leo, Mehdi Alilou, Adam Glaser, Nicholas Reder, Jonathan T. Liu, Anant Madabhushi

Proceedings Volume 11320, 113200G (2020) https://doi.org/10.1117/12.2549726

KEYWORDS: Image segmentation, 3D image processing, Prostate cancer, Biopsy, Cancer, Microscopy, Pathology, Feature extraction, Tissues, Natural surfaces

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Proceedings Article | 16 March 2020 Presentation + Paper

Computationally derived cytological image markers for predicting risk of relapse in acute myeloid leukemia patients following bone marrow transplantation

Sara ArabYarmohammadi, Zelin Zhang, Patrick Leo, Marjan Firouznia, Andrew Janowczyk, Haojia Li, Nathaniel Braman, Kaustav Bera, Behtash Nezami, Howard Meyerson, Jun Xu, Leland Metheny, Anant Madabhushi

Proceedings Volume 11320, 1132004 (2020) https://doi.org/10.1117/12.2549730

KEYWORDS: Fractal analysis, Image segmentation, Feature extraction, Bone, Leukemia, Blood, Shape analysis, Visualization, Transplantation, Visual process modeling

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Proceedings Article | 6 March 2018 Presentation + Paper

Combination of nuclear NF-kB/p65 localization and gland morphological features from surgical specimens is predictive of early biochemical recurrence in prostate cancer patients

Patrick Leo, Eswar Shankar, Robin Elliott, Andrew Janowczyk, Anant Madabhushi, Sanjay Gupta

Proceedings Volume 10581, 105810D (2018) https://doi.org/10.1117/12.2292652

KEYWORDS: Prostate cancer, Feature extraction, Tissues, Cancer, Proteins, Prostate, Image classification, Pathology

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Proceedings Article | 27 February 2018 Presentation + Paper

A deep learning classifier for prediction of pathological complete response to neoadjuvant chemotherapy from baseline breast DCE-MRI

Kavya Ravichandran, Nathaniel Braman, Andrew Janowczyk, Anant Madabhushi

Proceedings Volume 10575, 105750C (2018) https://doi.org/10.1117/12.2294056

KEYWORDS: Tumors, Breast, Receptors, Magnetic resonance imaging, Breast cancer, Network architectures, Surgery, Cancer, Lymphatic system, Visualization

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Proceedings Article | 23 March 2016 Paper

Automated tubule nuclei quantification and correlation with oncotype DX risk categories in ER+ breast cancer whole slide images

David Romo-Bucheli, Andrew Janowczyk, Eduardo Romero, Hannah Gilmore, Anant Madabhushi

Proceedings Volume 9791, 979106 (2016) https://doi.org/10.1117/12.2211368

KEYWORDS: Binary data, Breast cancer, Cancer, Tissues, Neural networks, Oncology, Tumors, Receptors, Precision measurement, Detection and tracking algorithms

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Early stage estrogen receptor positive (ER+) breast cancer (BCa) treatment is based on the presumed aggressiveness and likelihood of cancer recurrence. The primary conundrum in treatment and management of early stage ER+ BCa is identifying which of these cancers are candidates for adjuvant chemotherapy and which patients will respond to hormonal therapy alone. This decision could spare some patients the inherent toxicity associated with adjuvant chemotherapy. Oncotype DX (ODX) and other gene expression tests have allowed for distinguishing the more aggressive ER+ BCa requiring adjuvant chemotherapy from the less aggressive cancers benefiting from hormonal therapy alone. However these gene expression tests tend to be expensive, tissue destructive and require physical shipping of tissue blocks for the test to be done. Interestingly breast cancer grade in these tumors has been shown to be highly correlated with the ODX risk score. Unfortunately studies have shown that Bloom-Richardson (BR) grade determined by pathologists can be highly variable. One of the constituent categories in BR grading is the quantification of tubules. The goal of this study was to develop a deep learning neural network classifier to automatically identify tubule nuclei from whole slide images (WSI) of ER+ BCa, the hypothesis being that the ratio of tubule nuclei to overall number of nuclei would correlate with the corresponding ODX risk categories. The performance of the tubule nuclei deep learning strategy was evaluated with a set of 61 high power fields. Under a 5-fold cross-validation, the average precision and recall measures were 0:72 and 0:56 respectively. In addition, the correlation with the ODX risk score was assessed in a set of 7513 high power fields extracted from 174 WSI, each from a different patient (At most 50 high power fields per patient study were used). The ratio between the number of tubule and non-tubule nuclei was computed for each WSI. The results suggests that for BCa cases with both low ODX score and low BR grade, the mean tubule nuclei ratio was significantly higher than that obtained for the BCa cases with both high ODX score and high BR grade (p < 0:01). The low ODX and low BR grade cases also presented a significantly higher average tubule nuclei ratio when compared with the rest of the BCa cases (p < 0:05). Finally, the BCa cases that presented both a high ODX and high BR grade show a mean tubule nuclei to total number of nuclei ratio which was significantly smaller than that obtained for the rest of BCa cases (p < 0:01).

Proceedings Article | 14 March 2011 Paper

Local morphologic scale: application to segmenting tumor infiltrating lymphocytes in ovarian cancer TMAs

Andrew Janowczyk, Sharat Chandran, Michael Feldman, Anant Madabhushi

Proceedings Volume 7962, 79622N (2011) https://doi.org/10.1117/12.878415

KEYWORDS: Particles, Tumors, Ovarian cancer, Biopsy, RGB color model, Image segmentation, Image processing, Image classification, Tissues, Principal component analysis

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In this paper we present the concept and associated methodological framework for a novel locally adaptive scale notion called local morphological scale (LMS). Broadly speaking, the LMS at every spatial location is defined as the set of spatial locations, with associated morphological descriptors, which characterize the local structure or heterogeneity for the location under consideration. More specifically, the LMS is obtained as the union of all pixels in the polygon obtained by linking the final location of trajectories of particles emanating from the location under consideration, where the path traveled by originating particles is a function of the local gradients and heterogeneity that they encounter along the way. As these particles proceed on their trajectory away from the location under consideration, the velocity of each particle (i.e. do the particles stop, slow down, or simply continue around the object) is modeled using a physics based system. At some time point the particle velocity goes to zero (potentially on account of encountering (a) repeated obstructions, (b) an insurmountable image gradient, or (c) timing out) and comes to a halt. By using a Monte-Carlo sampling technique, LMS is efficiently determined through parallelized computations. LMS is different from previous local scale related formulations in that it is (a) not a locally connected sets of pixels satisfying some pre-defined intensity homogeneity criterion (generalized-scale), nor is it (b) constrained by any prior shape criterion (ball-scale, tensor-scale). Shape descriptors quantifying the morphology of the particle paths are used to define a tensor LMS signature associated with every spatial image location. These features include the number of object collisions per particle, average velocity of a particle, and the length of the individual particle paths. These features can be used in conjunction with a supervised classifier to correctly differentiate between two different object classes based on local structural properties. In this paper, we apply LMS to the specific problem of classifying regions of interest in Ovarian Cancer (OCa) histology images as either tumor or stroma. This approach is used to classify lymphocytes as either tumor infiltrating lymphocytes (TILs) or non-TILs; the presence of TILs having been identified as an important prognostic indicator for disease outcome in patients with OCa. We present preliminary results on the tumor/stroma classification of 11,000 randomly selected locations of interest, across 11 images obtained from 6 patient studies. Using a Probabilistic Boosting Tree (PBT), our supervised classifier yielded an area under the receiver operation characteristic curve (AUC) of 0.8341 ±0.0059 over 5 runs of randomized cross validation. The average LMS computation time at every spatial location for an image patch comprising 2000 pixels with 24 particles at every location was only 18s.

Proceedings Article | 13 March 2010 Paper

A weighted mean shift, normalized cuts initialized color gradient based geodesic active contour model: applications to histopathology image segmentation

Jun Xu, Andrew Janowczyk, Sharat Chandran, Anant Madabhushi

Proceedings Volume 7623, 76230Y (2010) https://doi.org/10.1117/12.845602

KEYWORDS: Image segmentation, Data modeling, Prostate, Tumor growth modeling, Biopsy, RGB color model, Sensors, Breast, Cancer, Expectation maximization algorithms

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While geodesic active contours (GAC) have become very popular tools for image segmentation, they are sensitive to model initialization. In order to get an accurate segmentation, the model typically needs to be initialized very close to the true object boundary. Apart from accuracy, automated initialization of the objects of interest is an important pre-requisite to being able to run the active contour model on very large images (such as those found in digitized histopathology). A second limitation of GAC model is that the edge detector function is based on gray scale gradients; color images typically being converted to gray scale prior to computing the gradient. For color images, however, the gray scale gradient results in broken edges and weak boundaries, since the other channels are not exploited for the gradient determination. In this paper we present a new geodesic active contour model that is driven by an accurate and rapid object initialization scheme-weighted mean shift normalized cuts (WNCut). WNCut draws its strength from the integration of two powerful segmentation strategies-mean shift clustering and normalized cuts. WNCut involves first defining a color swatch (typically a few pixels) from the object of interest. A multi-scale mean shift coupled normalized cuts algorithm then rapidly yields an initial accurate detection of all objects in the scene corresponding to the colors in the swatch. This detection result provides the initial boundary for GAC model. The edge-detector function of the GAC model employs a local structure tensor based color gradient, obtained by calculating the local min/max variations contributed from each color channel (e.g. R,G,B or H,S,V). Our color gradient based edge-detector function results in more prominent boundaries compared to classical gray scale gradient based function. We evaluate segmentation results of our new WNCut initialized color gradient based GAC (WNCut-CGAC) model against a popular region-based model (Chan & Vese) on a total of 60 digitized histopathology images. Across a total of 60 images, the WNCut-CGAC model yielded an average overlap, sensitivity, specificity, and positive predictive value of 73%, 83%, 97%, 84%, compared to the Chan & Vese model which had corresponding values of 64%, 75%, 95%, 72%. The rapid and accurate object initialization scheme (WNCut) and the color gradient make the WNCut-CGAC scheme, an ideal segmentation tool for very large, color imagery.

Showing 5 of 9 publications

Conference Committee Involvement (1)

Tenth International Symposium on Medical Information Processing and Analysis

14 October 2014 | Cartagena de Indias, Colombia

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