Dr. Anant Madabhushi Profile

Dr. Anant Madabhushi

F. Alex Nason Professor II at Emory Univ School of Medicine

SPIE Involvement:

Conference Program Committee | Author | Editor

Publications (112)

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 | 7 April 2023 Presentation + Paper

Transformer as a spatially-aware multi-instance learning framework to predict the risk of death for early-stage non-small cell lung cancer

Yufei Zhou, Can Koyuncu, Cristian ‪Barrera, Germán Corredor, Xiangxue Wang, Cheng Lu, Anant Madabhushi

Proceedings Volume 12471, 124710V (2023) https://doi.org/10.1117/12.2654498

KEYWORDS: Transformers, Spatial learning, Lung cancer, Tumors, Medical research, Cancer, Tissues, Feature extraction

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In computational pathology, training and inference of conventional deep convolutional neural networks (CNN) are usually limited to patches of small sizes (e.g., 256 × 256) sampled from whole slide images. In practice, however, diagnostic and prognostic information could lie within the context of tumor microenvironment across multiple regions, far beyond the scope of individual patches. For instance, the spatial relationship of tumor-infiltrating lymphocytes (TIL) across regions of interest might be prognostic for non-small cell lung cancer (NSCLC). This poses a multi-instance learning (MIL) problem, and a single-patch-driven CNN typically fails to learn spatial information and context between multiple patches, especially their spatial relationship. In this work, we present a cell graph-based MIL framework to predict the risk of death for early-stage NSCLC by aggregating feature representation of TIL-enclosing patches according to their spatial relationship. Inspired by PATCHY-SAN, a graph-embedding framework for CNNs, we use graph kernel-based approaches to embed a bag of patches into a sequence with their spatial information encoded into the sequence order. A transformer model was then trained to aggregate patch-level features based on spatial information. We demonstrate the capability of this framework to predict the likelihood of the patient with NSCLC in two cohorts (n=240) to survive for more than 5 years. The training cohort (n=195) comprised hematoxylin and eosin (H&E)-stained whole slide images (WSI), while the testing cohort (n=45) comprised H&E-stained tumor microarrays (TMA). We show that, with the spatial context of multiple patches encoded as an ordered patch sequence, the performance in the testing cohort of our approach achieves an area under the receiver operating characteristic curve (AUC) of 0.836 (p=0.009; HR=5.62), as opposed to a baseline conventional CNN with an AUC of 0.542 (p=0.105; HR=1.66). The results suggest that the Transformer is a generic spatial information aware MIL framework that can learn the spatial relationship of multiple TIL-enclosing patches from the graph representation of immune cells.

Proceedings Article | 7 April 2023 Presentation + Paper

A pathomic study for risk stratification and unraveling molecular associations of different histologic subtypes of papillary thyroid cancer

Shayan Monabbati, Sirvan Khalighi, Pingfu Fu, Sylvia Asa, Anant Madabhushi

Proceedings Volume 12471, 1247114 (2023) https://doi.org/10.1117/12.2655929

KEYWORDS: Tumors, Thyroid, Cancer, Decision support systems, Tumor growth modeling, Tissues, Statistical analysis, Medical research, Biological samples

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Papillary thyroid carcinoma (PTC) has the highest incidence rate of all thyroid cancers for the last several decades. Although this particular disease tends to be fairly indolent overall, classical and tall cell variants exhibit more aggressive behavior due to a higher progression and mortality rate. However among classical PTCs, there is a need for improvement of clinical management of patients who are at higher risk of progression/death and who will potentially benefit from more aggressive management, and similarly for lower risk patients who are unnecessarily overtreated. In this study, we aimed to evaluate the prognostic role of nuclear features for disease-specific and disease-free survival within classical and follicular histological subtypes of PTC. A set of features describing the nuclear shape, architecture, and texture of both tumor and lymphocyte cells were used to train a Lasso-Cox regression model with 199 patients. Coefficients of the model were then used to assign a quantitative risk score (QuRiS) per patient. Patients were further subdivided into high and low risk of recurrence to compare survival probabilities within a 15 year study period using Kaplan-Meier estimates (C-index of 0.786 (p = 0.009 on log-rank test). Survival probabilities of both risk groups were computed with a hazard ratio 1.54 and compared using the log-rank test (p = 0.004). The trained model was then validated on the remaining 149 patients, consisting of 3 independent sets of classical (N = 107), follicular (N = 74), and tall cell (N = 16) variants of PTC, with HR=8.83, 4.21, and 0.583, respectively. We then identified specific genes that were differentially expressed between the risk groups identified by the pathomic model. Using gene set enrichment and mutation analysis, we discovered that the signaling pathways TCA cycle and amino acid metabolism are associated with poorer outcome, while mutation in the BRAF oncogene is significantly associated with better survival in cPTC patients. We also discovered that the DTX4 gene was prognostic for disease-specific survival (DSS) and further stratified the risk of disease-related death of patients with high and low expression of DTX4 using the image-based nuclear morphology features.

Proceedings Article | 7 April 2023 Presentation + Paper

Biopsy and surgical specimen specific deep learning models for prostate cancer detection on digitized pathology images

Brennan Flannery, Priti Lal, Michael Feldman, María Natalizio, Juan Santa-Rosario, Anant Madabhushi

Proceedings Volume 12471, 124710H (2023) https://doi.org/10.1117/12.2654212

KEYWORDS: Cancer detection, Biopsy, Performance modeling, Cancer, Biological samples, Tissues

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The detection of prostate cancer within H&E-stained tissue slides helps identify the presence, location, and extent of the disease. Machine learning approaches have been developed to accomplish this task for biopsies and radical prostatectomies. Deep learning approaches, primarily using convolutional neural networks (CNN), have demonstrated substantial ability to identify cancer in each of these sample types. Some models trained on biopsies have even been approved for clinical application. Biopsies are small tissue samples acquired through a syringe to establish cancer diagnosis while radical prostatectomies are large planar sections of prostate tissue acquired post-surgery. This leads to differing morphology and heterogeneity between sample types, making it unclear whether algorithms trained on biopsies are robust enough to perform well on radical prostatectomies and vice versa. Our goal was to investigate whether morphological differences between sample types affected the performance of radical prostatectomy trained CNN models when applied to biopsies and vice versa. Radical prostatectomies (N=100) and biopsies (N=50) were acquired from The University of Pennsylvania to train (80%) and validate (20%) a CNN using the Densenet architecture for biopsies (M^B), radical prostatectomies (M^R), and a combined dataset (M^B+R). Model performance was compared using sensitivity, specificity, and F1 score. To isolate the effect of morphological differences on performance, we acquired all data from the same institution, ensured no batch effects were present via UMAP, applied data augmentation during training, and applied stain normalization. Additionally, the radical prostatecomy training set was optimized for transfer to biopsies by reducing heterogeneity (M^R*). This reduction was based on distance from the centroid of a texture feature distribution. Models performed well when applied to their own sample type (F1 > 0.88) but performed poorly when applied across sample types (F1 < 0.65). Reducing heterogeneity to optimize the radical prostatectomy training set resulted in M^R* (F1=0.72) noticeably outperforming M^R (F1=0.53) on biopsies. This indicates that differences in morphology and heterogeneity drive performance differences between cancer detection models trained on different sample types. Our results suggest that these morphological differences can be overcome with sample type specific models or training set optimization methods.

Proceedings Article | 3 April 2023 Poster + Paper

Resolving impact of technical and biological variability on the convolutional neural networks: evaluating chest x-ray scans

Dmitrii Cherezov, Vidya Sankar Viswanathan, Amit Gupta, Anant Madabhushi

Proceedings Volume 12464, 124643H (2023) https://doi.org/10.1117/12.2655271

KEYWORDS: Chest imaging, Scanners, Performance modeling, Image classification, X-ray imaging, X-rays, Portability, Image analysis

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SPIE Journal Paper | 23 June 2022 Open Access

Fifty years of SPIE Medical Imaging proceedings papers

Robert Nishikawa, Christoph Hoeschen, Anant Madabhushi, Kyle Myers, Thomas Deserno, Elizabeth Krupinski, Ronald Summers, Claudia Mello-Thoms, Matthew Kupinski, Jeffrey Siewerdsen

JMI, Vol. 9, Issue S1, 012207, (June 2022) https://doi.org/10.1117/12.10.1117/1.JMI.9.S1.012207

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Proceedings Article | 4 April 2022 Presentation + Paper

Identifying the origination of liver metastasis using a hand-crafted computational pathology approach

Chuheng Chen, Cheng Lu, Joseph Willis, Anant Madabhushi

Proceedings Volume 12039, 1203904 (2022) https://doi.org/10.1117/12.2613387

KEYWORDS: Tumors, Pathology

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The liver is a common site for metastases for multiple cancer types – with adenocarcinoma being the most common subtype. Standard pathology assessments fail to identify a site of origin for three to five percent of these patients, who are then treated in an empirical manner.¹ Computational pathology is an ideal technology to improve diagnostic accuracy for metastatic cancers with a significant reduction in costs and increase in tissue preservation for future testing. Recently, Deep Learning (DL)-based algorithms have been developed to automatically identify the origination of metastases using only H&E-stained whole slide images as inputs.² However, immunohistochemical based analysis is time- and resource-intensive and tissue destructive, while the “black box” nature of the DL-based approach makes it difficult if not impossible to explain the biology behind the classifier’s decision. This pilot study demonstrates that an analysis of computer extracted quantitative cellular features from tumor epithelial nuclei, including a tumor nuclei morphological feature and graph feature as well as cytoplasm texture from H&E stained histology slides, can be used to identify the origination of liver metastasis. Since the primary source of liver metastasis is typically the colon, breast, pancreas, or esophagus,³ a data set consisting of 120 patients with primary adenocarcinoma and matched liver metastases from the breast, colon, esophagus, and pancreas was constructed. A combination of supervised classification and unsupervised clustering was applied in order to identify the tumors’ origination using the above mentioned histomorphometric features from the data set. We evaluated the utility of histomorphometric features to identify the origination of the metastatic tumors in the liver using both supervised machine classifiers and unsupervised clustering. A Random Forest classifier achieved AUCs of 0.83, 0.63, 0.82, and 0.64 in classifying the primary or metastatic tumor from colon, esophagus, breast, and pancreas. The top performing features included local cellular diversity as well as cytoplasmic texture feature families. We further verified selected features using unsupervised methods such as UMAP, hierarchical clustering, and content-based image retrieving. Based off similarity measures calculated between image tiles in the primary and metastatic tissue, a heatmap corresponding to the WSIs for the primary tumor was constructed to highlight the sites representing potential points of origination of the metastases. Our preliminary results suggest that the site of origination for metastases in the context of primary breast tumors appears to be within the stroma.

Proceedings Article | 4 April 2022 Presentation + Paper

Computer extracted features of tumor-infiltrating lymphocytes (TILs) architecture are prognostic of progression-free survival in stage III colon cancer

Aya Aqeel, Germán Corredor, Vidya Sankar Viswanathan, Chuheng Chen, Mogjan Mokhtari, Pingfu Fu, Joseph Willis, Anant Madabhushi

Proceedings Volume 12039, 120390V (2022) https://doi.org/10.1117/12.2613161

KEYWORDS: Colorectal cancer, Tumors, Feature extraction, Cancer, Image segmentation, Data modeling, Medical research

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Stage III Colorectal cancer (CRC) is treated with surgery followed by chemotherapy. Yet >20% of clinically low-risk patients develop recurrence. It is critical to identify high-risk stage III patients who can benefit from closer monitoring and escalation of therapy. Previous studies showed promising results in predicting risk from H&E slides in CRC using deep learning based algorithms. One biomarker which was heavily studied and showed good results in predicting risk is Tumor Infiltrating Lymphocytes (TILs). In CRC, TIL density has been shown to be significantly and independently associated with overall patient survival¹. Furthermore, additional studies have demonstrated that analyzing spatial organization of TILs could be more informative than density alone². Hence, our study aimed to stratify stage III CRC patients into distinct risk groups based on features derived from TILs and to determine if this classification could have independent prognostic significance. The training set (D₁) included 50 patients and validation set (D₂) consisted of 70 patients from an independent site. A survival model was trained to predict the risk of recurrence in stage III CRC patients. First, a deep learning (DL) model was used to segment TILs on WSIs. Next, 1036 features related to spatial architecture (SpaTIL) and density of TILs (DenTIL) were extracted. A Cox proportional hazards regression model in conjunction with the least absolute shrinkage and selection operator (Lasso) was used to find top 5 features and the feature coefficients associated with progression free survival (PFS) and provide risk scores to each patient. The risk scores for the training dataset were computed using the selected features with their respective coefficients. A cut-off value was determined according to these risk scores, above which patients were labelled high-risk and below was low risk. In the validation set, the median PFS for the high-risk group was 15.1mos and in the low-risk group was 27mos. The model was able to accurately predict higher incidence of progression in patients in the high-risk group (HR = 3.76, 95% CI 1.3-10.9, p-value=0.0053, c-index=0.687) in the validation set. Future work will entail additional multi-site, multi-institutional validation of our biomarker to further understand its strengths and applications.

Proceedings Article | 4 April 2022 Poster

Quantitative histomorphometric features of tumor nuclei are prognostic of disease-free survival in papillary thyroid carcinoma

Shayan Monabbati, Paula Toro, Kaustav Bera, Pingfu Fu, Sylvia Lou, Anant Madabhushi

Proceedings Volume 12039, 120391B (2022) https://doi.org/10.1117/12.2613789

KEYWORDS: Tissues, Shape analysis, Image analysis, Hazard analysis, Cancer

Proceedings Article | 4 April 2022 Presentation + Paper

Evaluating the sensitivity of deep learning to inter-reader variations in lesion delineations on bi-parametric MRI in identifying clinically significant prostate cancer

Ansh Roge, Amogh Hiremath, Michael Sobota, Sree Harsha Tirumani, Leonardo Kayat Bittencourt, Justin Ream, Ryan Ward, Halimat Olaniyan, Sadhna Verma, Andrei Purysko, Anant Madabhushi, Rakesh Shiradkar

Proceedings Volume 12033, 120330Z (2022) https://doi.org/10.1117/12.2613245

KEYWORDS: Principal component analysis, Magnetic resonance imaging, Prostate cancer, Biopsy, Medical research, Pathology, Prostate, Performance modeling, Diffusion, Convolutional neural networks

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Deep learning based convolutional neural networks (CNNs) for prostate cancer (PCa) risk stratification employ radiologist delineated regions of interest (ROIs) on MRI. These ROIs contain the reader’s interpretation of the region of PCa. Variations in reader annotations change the features that are extracted from the ROIs, which may in turn affect classification performance of CNNs. In this study, we sought to analyze the effect of variations in inter-reader delineations of PCa ROIs on training of CNNs with regards to distinguishing clinically significant (csPCa) and insignificant PCa (ciPCa). We employed 180 patient studies (n=274 lesions) from 3 cohorts who underwent 3T multi-parametric MRI followed by MRI-targeted biopsy and/or radical prostatectomy. ISUP Gleason grade groups (GGG) obtained from pathology were used to determine csPCa (GGG≥2) and ciPCa (GGG=1). 5 experienced radiologists, with over 5 years of experience in prostate imaging, delineated PCa ROIs on bi-parametric MRI (bpMRI including T2 weighted (T2W) and diffusion weighted (DWI) sequences) within the training set (n₁=160 lesions) using targeted biopsy locations. Patches were extracted using the ROIs which were then used to train individual CNNs (N₁-N₅) using the SqueezeNet architecture. The average volume for readerdelineated ROIs used for training varied greatly, ranging between 1106 and 2107 mm across all readers. The resulting networks showed no significant difference in classification performance (AUC= 0.82 ± 0.02) indicating that they were relatively robust to inter-reader variations in ROI. These models were evaluated on independent test sets (n₂=85 lesions, n₃=29 lesions) where ROIs were obtained by co-registration of MRI with post-surgical pathology, unaffected by inter-reader variations in ROIs. Network performance across D₂ and D₃ was 0.80±0.02 and 0.62 ± 0.03, respectively. The CNN predictions were moderately consistent, with ICC(2,1) scores across D₂ and D₃ being 0.74 and 0.54, respectively. Higher agreement in ROI overlap produced higher correlation in predictions on external test sets (R = 0.89, p < 0.05). Furthermore, higher average ROI volume produced greater AUC scores on D₃, indicating that comprehensive ROIs may provide more features for DL networks to use in classification. Inter-reader variations in ROIs on MRI may influence the reliability and generalizability of CNNs trained for PCa risk stratification.

SPIE Journal Paper | 18 February 2022 Open Access

History of the SPIE Medical Imaging Digital Pathology Conference

Anant Madabhushi, Metin Gurcan

JMI, Vol. 9, Issue S1, 012203, (February 2022) https://doi.org/10.1117/12.10.1117/1.JMI.9.S1.012203

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SPIE Journal Paper | 13 July 2021 Open Access

Computational pathology reveals unique spatial patterns of immune response in H&E images from COVID-19 autopsies: preliminary findings

Paula Toro, Kaustav Bera, Pingfu Fu, Lisa Barton, Hannah Gilmore, Sanjay Mukhopadhyay, Anant Madabhushi, Germán Corredor, Dylan Rasmussen, Vidya Sankar Viswanathan, Christina Buzzy, Edana Stroberg, Eric Duval

JMI, Vol. 8, Issue S1, 017501, (July 2021) https://doi.org/10.1117/12.10.1117/1.JMI.8.S1.017501

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Proceedings Article | 5 March 2021 Presentation

Annotation-free 3D segmentation of prostate glands enabled with deep-learning image translation

Weisi Xie, Adam Glaser, Nicholas Reder, Nadia Postupna, Chenyi Mao, Can Koyuncu, Patrick Leo, Robert Serafin, Hongyi Huang, Anant Madabhushi, Lawrence True, Jonathan T. Liu

Proceedings Volume 11631, 116310M (2021) https://doi.org/10.1117/12.2576965

KEYWORDS: Image segmentation, Prostate, 3D image processing, 3D modeling, Tumor growth modeling, Tissues, Prostate cancer, Visualization, Microscopy, Image processing

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Proceedings Article | 16 March 2020 Presentation + Paper

Multi-site evaluation of stable radiomic features for more accurate evaluation of pathologic downstaging on MRI after chemoradiation for rectal cancers

Amrish Selvam, Jacob Antunes, Kaustav Bera, Asya Ofshteyn, Justin Brady, Katherine Bingmer, Kenneth Friedman, Sharon Stein, Rajmohan Paspulati, Andrei Purysko, Matthew Kalady, Anant Madabhushi, Satish Viswanath

Proceedings Volume 11314, 113140V (2020) https://doi.org/10.1117/12.2549085

KEYWORDS: Cancer, Tumors, Magnetic resonance imaging, Rectum, Feature selection, Feature extraction, Visualization, Oncology, CRTs, Tissues

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Tumor downstaging after neoadjuvant chemoradiation (CRT) in rectal cancer patients is typically assessed via Magnetic Resonance Imaging (MRI) in order to determine follow-up surgical interventions, but is associated with marked inter-reader variability and limited performance. While radiomic features have shown promise for evaluating chemoradiation response and tumor stage in rectal cancers, there is a need to determine how reproducible these features are across different MRI scanners and acquisitions. In this study, we evaluated radiomic feature reproducibility in terms of feature instability within a uniquely curated true healthy" rectum cohort in order to construct a stability-informed radiomic classifier for differentiating poorly from markedly down-staged rectal tumors after chemoradiation in a multi-site setting. We utilized a cohort of 156 patients, with (a) 74 MRIs visualizing the healthy rectum, (b) 52 post-CRT MRI scans in the discovery cohort, and (c) 30 post-CRT MRI scans in a second-site validation cohort; the latter 2 being from rectal cancer patients. 764 radiomic features were extracted from within the entire rectal wall on each MRI scan. Feature instability was used to quantify how reproducible each radiomic feature was between the discovery cohort and the healthy rectum cohort, using locations along the rectum that were spatially distinct from the treated tumor region. From the resulting stability-informed" feature set, the most relevant features were identified to distinguish pathologic tumor stage groups in the discovery cohort via a QDA classifier with cross-validation to ensure robustness. The top 4 radiomic features were then evaluated in hold-out fashion on scans from the validation cohort. We found that utilizing a stability-informed radiomic model (which comprised features that were reproducible in 100% of all comparisons) was significantly more accurate in identifying pathological tumor stage regression in both discovery (AUC=0:66 ± 0:09) and validation (AUC=0.73) cohorts, compared to a basic radiomic model that used all extracted features (AUC=0:60 ± 0:07 in discovery, AUC=0.62 in validation). Evaluating feature instability with respect to healthy rectal tissue may thus enhance the performance of radiomic models in characterizing pathologic downstaging in rectal cancers, via MRI.

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 Paper

Radiomic features derived from periprostatic fat on pre-surgical T2w MRI predict extraprostatic extension of prostate cancer identified on post-surgical pathology: preliminary results

Rakesh Shiradkar, Ruyuan Zuo, Amr Mahran, Lee Ponsky, Sree Harsha Tirumani, Anant Madabhushi

Proceedings Volume 11314, 113143G (2020) https://doi.org/10.1117/12.2551248

KEYWORDS: Magnetic resonance imaging, Prostate cancer, Prostate, Machine learning, Feature extraction, Principal component analysis, Imaging systems, Statistical analysis, Cancer, Pathology

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Proceedings Article | 16 March 2020 Presentation + Paper

Texture features distinguish benign cell clusters from adenocarcinomas on bile duct brushing cytology images

Shayan Monabbati, Patrick Leo, Kaustav Bera, Behtash Nezami, Claire Michael, Aparna Harbhajanka, Anant Madabhushi

Proceedings Volume 11320, 113200I (2020) https://doi.org/10.1117/12.2550870

KEYWORDS: Feature extraction, Cell biology, Pathology, Cancer, Diagnostics, Biopsy, Machine learning, Feature selection, Data analysis, Image resolution

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Bile duct cancer, or cholangiocarcinoma, is a rare and aggressive form of cancer, with approximately 2,500 new diagnoses each year in the United States. Biliary adenocarcinoma comprise of 90% of reported cholangiocarcinoma cases and often presents symptoms in later stages and is therefore associated with poor patient outcomes. Survival rates of cholangiocarcinoma when diagnosed at late stage are 6%, but can be improved to 15% when diagnosed early. Many previous studies have investigated the role of quantitative histomorphometric (QH) features on routinely acquired hematoxylin and eosin (H&E) slides of pancreatobiliary biopsies to help identify malignancies in the lining of the biliary tract. The biopsy procedure carries a high risk of strictures and peritonitis. An alternative to biopsy is a bile duct brushing (BDB), which exclusively contain epithelial cells fixed in cytology slides and have lower complication rates. The goal of this proof of concept study was to evaluate the role of image texture features to differentiate benign clusters and adenocarcinoma on digitized BDB specimens. Textural descriptors are able to characterize local regions of interest within malignant lesions by computing spatial arrangements and statistics of color intensities. Typical features often used in characterizing image texture include Gabor, Law, Haralick, and Co-occurrence of Local Anisotropic Gradient Orientations (CoLlAGe) features. These features are able to capture subtle differences in malignant and benign phenotypes caused by a multitude of phenotypic changes, including nuclear overcrowding, disorientation, and disorderly chromatin distribution. Pixel-wise texture features from each family were computed on whole slide images (WSIs) of BDBs corresponding to 59 unique patients of which 31 were from patients pathologically confirmed as having biliary adenocarcinoma through next generation sequencing, and the remaining 28 were confirmed as benign. Each WSI was magnified at 11X, 5.5X, and 2.25X before features were extracted. A total of 445 clusters were annotated across all slide images, of which 275 were identified as malignant by an expert cytopathologist, and used as the ground truth for our machine learning models. The pixel-wise feature distributions were summarized using mean, median, standard deviation, skewness, and kurtosis. The top five statistical texture features were selected using Wilcoxon ranksum, two-sided t-test, and maximum relevance minimum redundancy tests in 3-fold patient-wise cross validation and used to train three different machine learning classifiers. A linear discriminant classifier was trained with the mean Haralick information measure 2, standard deviation and median of CoLlAGe correlation, and mean of 2D Gabor response with {0,4}Hz frequencies and orientations f2 ; 58 g radian orientations, all selected by the mRMR test. We obtained an AUC of 0:83 ±0:01 using 3-fold cross-validation on 39 patients in the training set and 20 patients in the testing set.

Proceedings Article | 16 March 2020 Presentation + Paper

Computer extracted features related to the spatial arrangement of tumor-infiltrating lymphocytes predict overall survival in epithelial ovarian cancer receiving adjuvant chemotherapy

Sepideh Azarianpour, Germán Corredor, Kaustav Bera, Patrick Leo, Nathaniel Braman, Pingfu Fu, Haider Mahdi, Anant Madabhushi

Proceedings Volume 11320, 113200Q (2020) https://doi.org/10.1117/12.2550188

KEYWORDS: Tumors, Ovarian cancer, Cancer, Feature extraction, Lung cancer, Statistical analysis, Tumor growth modeling, Tissues, Data modeling, Medical research

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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 | 16 March 2020 Presentation + Paper

A combination of intra- and peri-tumoral deep features from prostate bi-parametric MRI can distinguish clinically significant and insignificant prostate cancer

Amogh Hiremath, Rakesh Shiradkar, Nathaniel Braman, Prateek Prasanna, Art Rastinehad, Andrei Purysko, Anant Madabhushi

Proceedings Volume 11314, 113140M (2020) https://doi.org/10.1117/12.2550963

KEYWORDS: Magnetic resonance imaging, Prostate cancer, Feature extraction, Convolutional neural networks, Prostate, Diffusion weighted imaging

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Proceedings Article | 16 March 2020 Presentation + Paper

Compactness measures of tumor infiltrating lymphocytes in lung adenocarcinoma are associated with overall patient survival and immune scores

Ruiwen Ding, Prateek Prasanna, Germán Corredor, Cheng Lu, Priya Velu, Khoi Le, Patrick Leo, Niha Beig, Vamsidhar Velcheti, David Rimm, Kurt Schalper, Anant Madabhushi

Proceedings Volume 11320, 1132003 (2020) https://doi.org/10.1117/12.2549588

KEYWORDS: Tumors, Tissues, Feature extraction, Lung, Lung cancer, Biological research, Cancer, Data modeling, Principal component analysis, Statistical analysis

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SPIE Journal Paper | 14 June 2019 Open Access

Multisite evaluation of radiomic feature reproducibility and discriminability for identifying peripheral zone prostate tumors on MRI

Prathyush Chirra, Patrick Leo, Michael Yim, B. Nicolas Bloch, Ardeshir R. Rastinehad, Andrei Purysko, Mark Rosen, Anant Madabhushi, Satish Viswanath

JMI, Vol. 6, Issue 02, 024502, (June 2019) https://doi.org/10.1117/12.10.1117/1.JMI.6.2.024502

KEYWORDS: Magnetic resonance imaging, Tumors, Prostate, Feature extraction, Scanners, Tissues, Prostate cancer, Computed tomography, Visualization, Magnetism

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Recent advances in the field of radiomics have enabled the development of a number of prognostic and predictive imaging-based tools for a variety of diseases. However, wider clinical adoption of these tools is contingent on their generalizability across multiple sites and scanners. This may be particularly relevant in the context of radiomic features derived from T1- or T2-weighted magnetic resonance images (MRIs), where signal intensity values are known to lack tissue-specific meaning and vary based on differing acquisition protocols between institutions. We present the first empirical study of benchmarking five different radiomic feature families in terms of both reproducibility and discriminability in a multisite setting, specifically, for identifying prostate tumors in the peripheral zone on MRI. Our cohort comprised 147 patient T2-weighted MRI datasets from four different sites, all of which are first preprocessed to correct for acquisition-related artifacts such as bias field, differing voxel resolutions, and intensity drift (nonstandardness). About 406 three-dimensional voxel-wise radiomic features from five different families (gray, Haralick, gradient, Laws, and Gabor) were evaluated in a cross-site setting to determine (a) how reproducible they are within a relatively homogeneous nontumor tissue region and (b) how well they could discriminate tumor regions from nontumor regions. Our results demonstrate that a majority of the popular Haralick features are reproducible in over 99% of all cross-site comparisons, as well as achieve excellent cross-site discriminability (classification accuracy of ≈0.8). By contrast, a majority of Laws features are highly variable across sites (reproducible in <75 % of all cross-site comparisons) as well as resulting in low cross-site classifier accuracies (<0.6), likely due to a large number of noisy filter responses that can be extracted. These trends suggest that only a subset of radiomic features and associated parameters may be both reproducible and discriminable enough for use within machine learning classifier schemes.

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Proceedings Article | 15 May 2019 Presentation + Paper

Phenotyping tumor infiltrating lymphocytes (PhenoTIL) on H&E tissue images: predicting recurrence in lung cancer

Cristian Barrera, Germán Corredor, Xiangxue Wang, Kurt Schalper, David Rimm, Vamsidhar Velcheti, Anant Madabhushi, Eduardo Romero Castro

Proceedings Volume 10956, 1095607 (2019) https://doi.org/10.1117/12.2513048

KEYWORDS: Tumors, Tissues, Lung cancer, Data modeling, Statistical analysis, Image segmentation, Cancer, Process modeling, Oncology, Image analysis

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SPIE Journal Paper | 7 May 2019

Radiomics-based convolutional neural network for brain tumor segmentation on multiparametric magnetic resonance imaging

Prateek Prasanna, Ayush Karnawat, Marwa Ismail, Anant Madabhushi, Pallavi Tiwari

JMI, Vol. 6, Issue 02, 024005, (May 2019) https://doi.org/10.1117/12.10.1117/1.JMI.6.2.024005

KEYWORDS: Image segmentation, Tumors, Brain, Magnetic resonance imaging, Convolutional neural networks, 3D modeling, Neuroimaging, Feature extraction, Magnetorheological finishing, Distance measurement

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Accurate segmentation of gliomas on routine magnetic resonance image (MRI) scans plays an important role in disease diagnosis, prognosis, and patient treatment planning. We present a fully automated approach, radiomics-based convolutional neural network (RadCNN), for segmenting both high- and low-grade gliomas using multimodal MRI volumes (T1c, T2w, and FLAIR). RadCNN incorporates radiomic texture features (i.e., Haralick, Gabor, and Laws) within DeepMedic [a deep 3-D convolutional neural network (CNN) segmentation framework that uses image intensities; a top performing method in the BraTS 2016 challenge] to further augment the performance of brain tumor subcompartment segmentation. We first identify textural radiomic representations that best separate the different subcompartments [enhancing tumor (ET), whole tumor (WT), and tumor core (TC)] on the training set, and then feed these representations as inputs to the CNN classifier for prediction of different subcompartments. We hypothesize that textural radiomic representations of lesion subcompartments will enhance the separation of subcompartment boundaries, and hence providing these features as inputs to the deep CNN, over and above raw intensity values alone, will improve the subcompartment segmentation. Using a training set of N = 241 patients, validation set of N = 44, and test set of N = 46 patients, RadCNN method achieved Dice similarity coefficient (DSC) scores of 0.71, 0.89, and 0.73 for ET, WT, and TC, respectively. Compared to the DeepMedic model, RadCNN showed improvement in DSC scores for both ET and WT and demonstrated comparable results in segmenting the TC. Similarly, smaller Hausdorff distance measures were obtained with RadCNN as compared to the DeepMedic model across all the subcompartments. Following the segmentation of the different subcompartments, we extracted a set of subcompartment specific radiomic descriptors that capture lesion disorder and assessed their ability in separating patients into different survival cohorts (short-, mid- and long-term survival) based on their overall survival from the date of baseline diagnosis. Using a multilinear regression approach, we achieved accuracies of 0.57, 0.63, and 0.45 for the training, validation, and test cases, respectively.

Proceedings Article | 15 March 2019 Paper

Morphology of vascular network in eyes with diabetic macular edema varies based on tolerance of aflibercept treatment interval length: preliminary findings

Prateek Prasanna, Justis Ehlers, Nathaniel Braman, Natalia Figueredo, Vishal Bobba, Sumit Sharma, Sunil Srivastava, Anant Madabhushi

Proceedings Volume 10953, 1095312 (2019) https://doi.org/10.1117/12.2513419

KEYWORDS: Angiography, Visualization, Tolerancing, Ischemia, Eye, Hough transforms, Medical research, Lung cancer, Blood, Capillaries

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Diabetic macular edema is a leading cause of vision loss in diabetic patients. The underlying cause for the onset of DME is 1) the long term presence of hyperglycemia and the eventual degradation of the blood-retinal barrier (BRB) via an uptick in vascular endothelial growth factor (VEGF); VEGF increases the permeability of the blood retinal barrier and alters the length of capillaries, thereby inhibiting the ability of these vessels in performing their primary function of filtration. The lack of a proper filtration system in combination with the ongoing change in intra-retinal vasculature that stems from it, results in the eventual loss of visual acuity in DME patients. Due to the large role in which VEGF plays in acting as a catalyst for the onset of DME, current treatments now focus on utilizing anti-VEGF therapy as a first line treatment for DME. Anti-VEGF therapy improves clinical outcomes in the form of improved visual acuity and reduction in macular edema. Anti-VEGF treatments also have a peripheral effect of modifying the disease burden and allowing for extended time in between treatments. However, there is still a void in understanding how anti-VEGF affects the underlying pathophysiology. This study focuses on using quantification of the geometric properties of vasculature on Fluorescein Angiography(FA) to understand the impact anti-VEGF treatment has on retinal vascular dynamics. We hypothesize that vasculature disorder, due to VEGF action, differs across patients and can be modeled mathematically to identify candidates for anti-VEGF treatment. We use VaNgOGH, a Hough transform-based descriptor to model the disorder of the retinal vascular network on baseline FA of patients subsequently treated with intravitreal anti-VEGF therapy (aibercept). VaNgOGH computes local measures of vessel-curvature and identifies dominant peaks in the accumulator space. We explored the differences in such features on baseline FA between eyes tolerating extended dosing interval (N=15) and those eyes requiring more frequent dosing (N=12), based on initial response following treatment interval extension. The cross-validated AUC was found to be 0.73±0.1 using VaNgOGH. The variance of local orientations showed a statistically significant difference (p=0.008) between the two categories, unlike clinical parameters on baseline OCT. Our results suggest there may be fundamental differences in localized vessel orientations between eyes that will exhibit favorable response to extended interval aibercept dosing and eyes that require more frequent dosing.

Proceedings Article | 15 March 2019 Paper

Spatial arrangement of leakage patterns in diabetic macular edema is associated with tolerance of aflibercept treatment interval length: preliminary findings

Prateek Prasanna, Justis Ehlers, Vishal Bobba, Natalia Figueredo, Cheng Lu, Sumit Sharma, Sunil Srivastava, Anant Madabhushi

Proceedings Volume 10953, 1095311 (2019) https://doi.org/10.1117/12.2513654

KEYWORDS: Visualization, Angiography, Tolerancing, Eye, Macula, Pathophysiology, Statistical analysis, Image segmentation, Medical research, Lung cancer

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Diabetic macular edema (DME) is a leading cause of vision loss in diabetic patients. The underlying cause for the onset of DME is the degradation of the blood-retinal barrier, whose primary function is maintaining the extracellular fluid at an optimal range. Vascular endothelial growth factor (VEGF) has proven to be a catalyst in altering the permeability of the blood-retinal barrier, thereby initiating a cascade of events that ultimately results in a loss of visual acuity.1 The primary imaging techniques to recognize and diagnose DME are fluorescein angiography (FA) and spectral-domain optical coherence tomography (SD-OCT). Taking a multimodal approach of FA in combination with SD-OCT provides images of vasculature and other eye structures to help better identify key features such as level, location, and amount of leakage.2 First-line treatments for DME have now evolved to using anti-VEGF to inhibit the effects VEGF has on increasing the permeability of the blood-retinal barrier.3 Because VEGF also increases the chance of leakage, we can also expect anti-VEGF treatments to decrease the amount of leakage DME patients suffer from. Anti-VEGF treatments also have a peripheral effect of modifying the disease burden and allowing for extended time in between treatments.4 Although current conventional treatment parameters exist to determine the efficacy of such VEGF treatments, many of these markers rely on clinicians to make a judgment call based on a minor qualitative difference of retinal scans or involve clinicians taking a fluid assessment, an option deemed too invasive to demand from all patients. In this work, we seek to find new imaging features that derive from a sub-visual feature analysis, and ideally provide a prognostic metric for clinicians to help streamline the diagnostic process. The rationale for these new biomarkers derives from leakage properties and their activity in the retina once edema develops. A decrease in leakage within certain structures in the eye would also lead to a change in the densities of leakage patterns, correlating with better clinical outcomes. In this work, we use morphological and graph-based attributes to model the global properties and spatial distribution of leakage areas on baseline FA scans of patients subsequently treated with intravitreal anti-VEGF therapy (i.e. aibercept). The features were then used in conjunction with a classifier to distinguish between eyes tolerating extended dosing intervals (N=15) and those eyes requiring more frequent dosing (N=12), based on initial response following treatment interval extension. The cross-validated area under the receiver operating characteristic curve (AUC) was found to be 0.74±0.11% using the computed imaging attributes. Edge length disorder of minimum spanning tree showed a statistically significant difference (p=0.007) between the two groups. Clinical parameters such as central subfield thickness and macular volume were not statistically significantly different. Our results indicate that there may be differences in spatial distribution of leakage areas between eyes that will exhibit favorable response to extended interval aibercept dosing and eyes that require more frequent dosing.

Proceedings Article | 13 March 2019 Paper

Radiomic features derived from pre-operative multi-parametric MRI of prostate cancer are associated with Decipher risk score

Lin Li, Rakesh Shiradkar, Ahmad Algohary, Patrick Leo, Cristina Magi-Galluzzi, Eric Klein, Andrei Purysko, Anant Madabhushi

Proceedings Volume 10950, 109503Y (2019) https://doi.org/10.1117/12.2512606

KEYWORDS: Feature extraction, Prostate cancer, Cancer, Magnetic resonance imaging, Pathology, Prostate, Tissues, Diffusion, Image registration

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Decipher, a genomic test, is used to predict the likelihood of metastasis and prostate cancer (PCa) specific mortality based on expression patterns of 22 RNA markers from radical prostatectomy (RP) specimens. It has been shown to be strongly correlated with metastasis-free prognosis and has been integrated with the National Comprehensive Cancer Network (NCCN) guidelines. However, Decipher is expensive and tissue destructive. Radiomic features refer to the high-throughput computational texture or shape features extracted from radiographic scans. Radiomic features derived from multi-parametric magnetic resonance imaging (mpMRI) of prostate cancer have been shown to be associated with clinically significant PCa. In this study, we sought to evaluate whether radiomic features derived from T2-weighted MRI (T2WI) and apparent diffusion coefficient (ADC) maps of the prostate could distinguish different Decipher risk groups (low, intermediate and high). We also explored correlations between Decipher risk associated radiomic features and features relating to gland morphology on corresponding digitized surgical specimens. A retrospectively acquired, de-identified cohort of 70 PCa patients (N = 74 lesions) who underwent 3T mpMRI prior to RP and Decipher tests after RP were used in this study. The Decipher risk score, ranging from 0 to 1, was used to categorize patients into low/intermediate (D₁) and high (D₂) risk groups. A multivariate logistic regression model was trained (N = 37 lesions) using radiomic features selected via elastic-net regularization to predict the Decipher risk groups. The model was evaluated on a hold-out test set (N = 37 lesions) and resulted in an area under the receiver operating characteristic curve (AUC) = 0:80. Our model outperformed the prediction using PIRADS v2 (AUC = 0:67), but showed comparable performance with Gleason Grade Group (GGG) (AUC = 0:80). We observed that the best discriminating radiomic features were correlated with gland morphology and gland packing on corresponding histopathology (R = 0.43, p < 0.05).

Proceedings Article | 13 March 2019 Paper

Radiogenomic characterization of response to chemo-radiation therapy in glioblastoma is associated with PI3K/AKT/mTOR and apoptosis signaling pathways

Niha Beig, Prateek Prasanna, Virginia Hill, Ruchika Verma, Vinay Varadan, Anant Madabhushi, Pallavi Tiwari

Proceedings Volume 10950, 109501B (2019) https://doi.org/10.1117/12.2512258

KEYWORDS: Machine learning, Magnetic resonance imaging, Tumors, Cell death, Cancer, Resistance, Oncology, Feature extraction, Medical research, Brain, Radiotherapy

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Over 40% of Glioblastoma (GBM) patients do not respond to conventional chemo-radiation therapy (chemo-RT) and relapse within 6-9 months, suggesting that they may have been better suited for other targeted therapies. Currently, there are no biomarkers that can reliably predict patients' response to chemo-RT in GBM. We seek to evaluate the role of radiomic markers on pre-treatment MRI to predict GBM patients' response to chemo-RT. Further, to establish a biological underpinning of the radiomic markers, we identified radiogenomic correlates of the radiomic markers with signaling pathways that are known to impact chemo-RT response. A total of 49 studies with Gd-T1w, T2w, FLAIR MRI protocols and corresponding gene expression were obtained from Ivy GAP (n=29) and TCIA (n=20) databases. Responders (n=22) were patients with progression-free survival (PFS) of at least ≥ 6 months, while non-responders (n=27) had PFS < 6 months. 13 molecular pathways were curated from the MSigDB Hallmark gene set. For each study, enhancing tumor on MRI was manually segmented by an expert reader. 1390 3D-radiomic features (Gabor, Haralick, and Laws energy) were extracted from this region across all MRI protocols. Joint mutual information identified the 3 most predictive radiomic features in the training set (n=29). This was followed by correlating these features with the gene set enrichment analysis (GSEA) score computed for every pathway. A support vector machine (SVM) classifier was trained using these 3 features and validated on a test set (n=20) that resulted in an Area Under Curve (AUC) of 0.71 to distinguish chemo-RT responders from non-responders. Laws energy descriptor (characterizing appearance of edges, spots, and ripples) from the enhancing region on Gd-T1w MR images were found to best predict chemo-RT response. Radiogenomic correlation with GSEA scores revealed that these radiomic features were significantly associated with PI3K/AKT/mTOR (promotes cell proliferation, survival) and apoptosis (programmed cell death) signaling pathways (p < 0.03, False Discovery Rate = 5%).

Proceedings Article | 13 March 2019 Presentation + Paper

A combination of intra- and peritumoral features on baseline CT scans is associated with overall survival in non-small cell lung cancer patients treated with immune checkpoint inhibitors: a multi-agent multi-site study

Mohammadhadi Khorrami, Mehdi Alilou, Prateek Prasanna, Pradnya Patil, Pirya Velu, Kaustav Bera, Pingfu Fu, Vamsidhar Velcheti, Anant Madabhushi

Proceedings Volume 10950, 109500R (2019) https://doi.org/10.1117/12.2513001

KEYWORDS: Tumors, Computed tomography, Lung cancer, Feature extraction, Cancer, Lung, Tissues, Medical research, Feature selection, Proteins

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Immune checkpoint inhibitors targeting the programmed cell death (PD)1/ L1 axis have been approved for treatment of chemotherapy refractory advanced non-small cell lung cancer (NSCLC) for a few years. While higher PD-L1 expression is associated with better outcomes after monotherapy with immune checkpoint inhibitors, it is not a perfect predictive biomarker for clinical benefit from immunotherapy, because some patients with low PD-L1 expression have sustained responses. In clinical practice, using radiological tools like Response Evaluation Criteria in Solid Tumors (RECIST), tends to underestimate the benefit of therapy. For instance, some patients treated with immunotherapy suffer from pseudoprogression while actually having a favorable response, RECIST in this setting is inadequate to capture the response. In this study we sought to explore whether radiomic texture features extracted from both inside and outside of the tumor from baseline CT scans were associated with overall patient survival (OS) in 139 NSCLC patients being treated with IO from two separate sites. Patients were divided into a discovery (D₁ = 50; nivolumab from Cleveland Clinic) and two validation sets (D₂ = 62 from Cleveland Clinic, D₃ = 27 from University of Pennsylvania Health System. Patients in the validation sets had been treated with different types of checkpoint inhibitor drugs including nivolumab, pembrolizumab, and atezolizumab. 454 radiomic texture features from within (intra-tumoral) and outside the tumor (peri-tumoral) were extracted from baseline contrast CT images. Following feature selection on the discovery set, a radiomic risk-score signature was generated by using least absolute shrinkage and selection operator. Using a Cox regression model, the association of the radiomic signature with overall survival (OS) was evaluated in the discovery and two validation sets. In addition, 95% confidence intervals (CI) and relative hazard ratios (HR) were calculated. Our results revealed that the radiomics signature was significantly associated with OS, both in the discovery set (HR = 5.06, 95%CI = 3, 8.55; p-value < 0.0001) and the two validation data sets (D₂: HR = 5.88, 95% CI = 2.19, 21.63, p-value = 0.0009; D₃: HR = 5.37, 95% CI = 1.74, 16.57, p-value = 0.0034). Our initial results appear to suggest that our radiomic signature could serve as a non-invasive way of predicting and monitoring response to checkpoint inhibitors for patients with non-small cell lung cancer.

Proceedings Article | 13 March 2019 Presentation + Paper

Quantitative vessel tortuosity radiomics on baseline non-contrast lung CT predict response to immunotherapy and are prognostic of overall survival

Mehdi Alilou, Pranjal Vaidya, Mohammadhadi Khorrami, Alexia Zagouras, Pradnya Patil, Kaustav Bera, Pingfu Fu, Vamsidhar Velcheti, Anant Madabhushi

Proceedings Volume 10950, 109501F (2019) https://doi.org/10.1117/12.2513648

KEYWORDS: Computed tomography, Tumors, Image segmentation, Lung cancer, Cancer, Lung, Feature extraction, Medical research

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Proceedings Article | 13 March 2019 Paper

Deformation heterogeneity radiomics to predict molecular subtypes of pediatric Medulloblastoma on routine MRI

Sukanya Iyer, Marwa Ismail, Benita Tamrazi, Ashley Margol, Ruchika Verma, Ramon Correa, Prateek Prasanna, Niha Beig, Kaustav Bera, Volodymyr Statsevych, Alexander Judkins, Anant Madabhushi, Pallavi Tiwari

Proceedings Volume 10950, 109501E (2019) https://doi.org/10.1117/12.2513567

KEYWORDS: Tumors, Magnetic resonance imaging, Brain, Tissues, Gadolinium, Cancer, Medical research, Lung cancer, Radiotherapy, Genomics

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Medulloblastoma (MB) is the most common malignant brain tumor in children. Currently, "one-size-fits-all" radiation and chemotherapy treatment regimen is employed for treating MB patient, causing at least some children to undergo highly aggressive and in some cases, inadequate radiation therapy. Consequently, there is a need for prognostic and predictive tools for identifying disease aggressiveness and ultimately which patients with MB may be able to benefit from de-escalation of therapy. Genomic characterization of MB has recently identified 4 distinct molecular subgroups: Sonic Hedgehog (SHH) , Wingless (WNT) , Group 3, Group 4 each exhibiting different clinical behavior. The molecular sub-types have unique risk-profiles and outcomes, and patients could potentially benefit from sub-group specific treatments. However, the transition of these molecular MB subtypes into clinical practice has been limited due to challenges in availability of molecular profiling in most hospitals, as well as variability in clinical assessment. In this work, we present a radiomic feature that captures subtle tissue deformations caused due to the impact of tumor growth on the normal-appearing brain around tumor (BAT), to distinguish molecular sub-types of MB. First, we obtain voxel-wise deformation magnitude from the deformation orientations, after registering Gadolinium (Gd)-enhanced T1-w MRI scan for every study to a normal age-specific T1w MRI template. Deformation statistics are then computed within every 5mm annular BAT region, 0 < d < 60mm, where d is the distance from the tumor infiltrating edge, to capture subtle localized deformation changes around the tumor. Our results using multi-class comparison via one-way ANOVA and post-hoc comparison showed significant differences across deformation magnitudes obtained for Group 3, Group 4, and SHH molecular sub-types, observed up to 15-mm outside the infiltrating edge. Our feasibility results suggest that the subtle deformation features in BAT observed on routine Gd-T1w MRI may potentially serve as surrogate markers to non-invasively characterize molecular sub-types of pediatric MB.

Proceedings Article | 13 March 2019 Presentation + Paper

Radiomics of the lesion habitat on pre-treatment MRI predicts response to chemo-radiation therapy in Glioblastoma

Ruchika Verma, Ramon Correa, Virginia Hill, Niha Beig, Abdelkader Mahammedi, Anant Madabhushi, Pallavi Tiwari

Proceedings Volume 10950, 109500B (2019) https://doi.org/10.1117/12.2512907

KEYWORDS: Tumors, Magnetic resonance imaging, CRTs, Feature extraction, Brain, Cancer, Receivers, Animal model studies, Medical research, Lung cancer

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Glioblastoma (GBM) is a highly aggressive brain tumor with a median survival of 15 months. Unfortunately, chemo-radiation therapy (CRT), the standard-of-care treatment for GBM, fails in over 40% of the patients within 6 months of treatment, likely on account of the highly infiltrative and heterogeneous nature of the disease. Consequently, there is a need to differentiate patients who might be at high-risk of poor outcome due to treatment failure from those who may respond favorably to CRT treatment. In this work, we analyzed the lesion heterogeneity on clinical multi-parametric MRI (MP-MRI) by interrogating radiomic features from the lesion habitat" (comprising enhancing tumor, necrotic core, T2/FLAIR hyperintensities), to determine if we could non-invasively stratify patients into low-risk and high-risk categories based on their progression-free-survival (PFS). We employed a total of 124 pre-treatment MP-MRI scans (Gadolinium (Gd)-enhanced T1w, T2w, FLAIR) and dichotomized high-risk from low-risk patients using the median PFS information. Of the 124 scans, 90 studies were used for training and 34 studies were used for independent validation. For each MRI scan, necrotic core, enhancing tumor, and edematous sub-compartments were annotated by an expert. Thereafter, a total of 1008 radiomic descriptors (e.g. Haralick, Laws energy, CoLlAGe) were extracted from every sub-compartment across all three MRI protocols (Gd-T1w, T2w, FLAIR). The top 5 most discriminatory radiomic features (p _ 0.05) were selected from the training cohort using a one way analysis of variance (ANOVA) test after removing multi-collinearity for each sub-compartment across all three MRI protocols. A linear discriminant analysis (LDA) classifier was employed individually for each sub-compartment, using the top 5 features selected from the training cohort. These features were then used to differentiate between high-risk and low-risk groups in the independent validation set. We further concatenated the top 5 radiomic features from each sub-compartment to evaluate the combined impact of the tumor habitat in predicting patient outcome. The best accuracy of 72.2% on the training cohort, and 73.3% on the independent validation cohort was obtained from the enhancing tumor sub-compartment, in distinguishing the low-risk from the high-risk group. Interestingly, when top features from the 3 sub-compartments were combined together for risk-stratification, an accuracy of 82.3% was obtained on the independent validation cohort (N=34). Our preliminary results seem to suggest that radiomic features from the tumor habitat might be reflective of tumor heterogeneity and could potentially differentiate high-risk from low-risk groups in predicting patient's response to treatment.

Proceedings Article | 8 March 2019 Paper

Radiomic characterization of perirectal fat on MRI enables accurate assessment of tumor regression and lymph node metastasis in rectal cancers after chemoradiation

Michael Yim, Zhouping Wei, Jacob Antunes, Neil K. Sehgal, Kaustav Bera, Justin Brady, Kenneth Friedman, Joseph Willis, Andrei Purysko, Raj Paspulati, Anant Madabhushi, Satish Viswanath

Proceedings Volume 10951, 109512A (2019) https://doi.org/10.1117/12.2512612

KEYWORDS: Tumors, Magnetic resonance imaging, Cancer, Lymphatic system, Medical research, Feature extraction, Feature selection, Data analysis, Oncology

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Proceedings Article | 8 March 2019 Paper

Integrating radiomic features from T2-weighted and contrast-enhanced MRI to evaluate pathologic rectal tumor regression after chemoradiation

Siddhartha Nanda, Jacob Antunes, Amrish Selvam, Kaustav Bera, Justin Brady, Jayakrishna Gollamudi, Kenneth Friedman, Joseph Willis, Conor Delaney, Raj Paspulati, Anant Madabhushi, Satish Viswanath

Proceedings Volume 10951, 109512R (2019) https://doi.org/10.1117/12.2513945

KEYWORDS: Magnetic resonance imaging, Tumors, Cancer, CRTs, Feature extraction, In vivo imaging, Medical research, Feature selection, Tissues, Lung cancer

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SPIE Journal Paper | 8 February 2019

Convolutional neural network initialized active contour model with adaptive ellipse fitting for nuclear segmentation on breast histopathological images

Jun Xu, Lei Gong, Guanhao Wang, Cheng Lu, Hannah Gilmore, Shaoting Zhang, Anant Madabhushi

JMI, Vol. 6, Issue 01, 017501, (February 2019) https://doi.org/10.1117/12.10.1117/1.JMI.6.1.017501

KEYWORDS: Image segmentation, Convolutional neural networks, Performance modeling, Data modeling, Breast, Breast cancer, Sensors, Cancer, Tissues, Computing systems

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Automated detection and segmentation of nuclei from high-resolution histopathological images is a challenging problem owing to the size and complexity of digitized histopathologic images. In the context of breast cancer, the modified Bloom–Richardson Grading system is highly correlated with the morphological and topological nuclear features are highly correlated with Modified Bloom–Richardson grading. Therefore, to develop a computer-aided prognosis system, automated detection and segmentation of nuclei are critical prerequisite steps. We present a method for automated detection and segmentation of breast cancer nuclei named a convolutional neural network initialized active contour model with adaptive ellipse fitting (CoNNACaeF). The CoNNACaeF model is able to detect and segment nuclei simultaneously, which consist of three different modules: convolutional neural network (CNN) for accurate nuclei detection, (2) region-based active contour (RAC) model for subsequent nuclear segmentation based on the initial CNN-based detection of nuclear patches, and (3) adaptive ellipse fitting for overlapping solution of clumped nuclear regions. The performance of the CoNNACaeF model is evaluated on three different breast histological data sets, comprising a total of 257 H&E-stained images. The model is shown to have improved detection accuracy of F-measure 80.18%, 85.71%, and 80.36% and average area under precision-recall curves (AveP) 77%, 82%, and 74% on a total of 3 million nuclei from 204 whole slide images from three different datasets. Additionally, CoNNACaeF yielded an F-measure at 74.01% and 85.36%, respectively, for two different breast cancer datasets. The CoNNACaeF model also outperformed the three other state-of-the-art nuclear detection and segmentation approaches, which are blue ratio initialized local region active contour, iterative radial voting initialized local region active contour, and maximally stable extremal region initialized local region active contour models.

Proceedings Article | 21 December 2018 Paper

A comparative analysis of sensitivity of convolutional neural networks for histopathology image classification in breast cancer

Fabian Cano, Anant Madabhushi, Angel Cruz-Roa

Proceedings Volume 10975, 109750W (2018) https://doi.org/10.1117/12.2511647

KEYWORDS: Breast cancer, Neurons, Data modeling, Tumor growth modeling, Pathology, Cancer, Digital imaging, Convolutional neural networks, Visual process modeling, Image classification

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SPIE Journal Paper | 18 April 2018 Open Access

Combination of computer extracted shape and texture features enables discrimination of granulomas from adenocarcinoma on chest computed tomography

Mahdi Orooji, Mehdi Alilou, Sagar Rakshit, Niha Beig, Mohammadhadi Khorrami, Prabhakar Rajiah, Rajat Thawani, Jennifer Ginsberg, Christopher Donatelli, Michael Yang, Frank Jacono, Robert Gilkeson, Vamsidhar Velcheti, Philip Linden, Anant Madabhushi

JMI, Vol. 5, Issue 02, 024501, (April 2018) https://doi.org/10.1117/12.10.1117/1.JMI.5.2.024501

KEYWORDS: Computed tomography, Feature extraction, Data analysis, Chest, Feature selection, Lung cancer, Receivers, Tumors, Digital filtering, Image filtering

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Proceedings Article | 6 March 2018 Presentation + Paper

RaPtomics: integrating radiomic and pathomic features for predicting recurrence in early stage lung cancer

Pranjal Vaidya, Xiangxue Wang, Kaustav Bera, Arjun Khunger, Humberto Choi, Pradnya Patil, Vamsidhar Velcheti, Anant Madabhushi

Proceedings Volume 10581, 105810M (2018) https://doi.org/10.1117/12.2296646

KEYWORDS: Tumors, Tissues, Lung cancer, Feature extraction, Computed tomography, Cancer, Statistical analysis, Image segmentation, Feature selection, Lung

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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 | 6 March 2018 Paper

A watershed and feature-based approach for automated detection of lymphocytes on lung cancer images

Germán Corredor, Xiangxue Wang, Cheng Lu, Vamsidhar Velcheti, Eduardo Romero, Anant Madabhushi

Proceedings Volume 10581, 105810R (2018) https://doi.org/10.1117/12.2293147

KEYWORDS: Lung cancer, Image segmentation, Visualization, Data modeling, Feature extraction, Tumors, Image processing, Cancer, Visual process modeling, 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 | 27 February 2018 Presentation + Paper

Empirical evaluation of cross-site reproducibility in radiomic features for characterizing prostate MRI

Prathyush Chirra, Patrick Leo, Michael Yim, B. Nicolas Bloch, Ardeshir Rastinehad, Andrei Purysko, Mark Rosen, Anant Madabhushi, Satish Viswanath

Proceedings Volume 10575, 105750B (2018) https://doi.org/10.1117/12.2293992

KEYWORDS: Magnetic resonance imaging, Prostate, Feature extraction, Computed tomography, Scanners, Tissues, Image resolution, Data acquisition, Magnetism, Machine learning

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Proceedings Article | 17 November 2017 Paper

Quantifying expert diagnosis variability when grading tumor-infiltrating lymphocytes

Paula Toro, Germán Corredor, Xiangxue Wang, Viviana Arias, Vamsidhar Velcheti, Anant Madabhushi, Eduardo Romero

Proceedings Volume 10572, 1057202 (2017) https://doi.org/10.1117/12.2286717

KEYWORDS: Tumors, Pathology, Lung cancer, Oncology, Solids, Cancer, Human-machine interfaces, Software, Image quality, Statistical analysis

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Proceedings Article | 17 November 2017 Paper

A lymphocyte spatial distribution graph-based method for automated classification of recurrence risk on lung cancer images

Juan Garciá-Arteaga, Germán Corredor, Xiangxue Wang, Vamsidhar Velcheti, Anant Madabhushi, Eduardo Romero

Proceedings Volume 10572, 1057203 (2017) https://doi.org/10.1117/12.2285653

KEYWORDS: Lung cancer, Pathology, Blood, Tumors, Image classification, Machine learning, Feature extraction, Biomedical optics

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SPIE Journal Paper | 28 June 2017 Open Access

Special Section Guest Editorial: Digital Pathology

Metin Gurcan, John Tomaszewski, Anant Madabhushi

JMI, Vol. 4, Issue 02, 021101, (June 2017) https://doi.org/10.1117/12.10.1117/1.JMI.4.2.021101

KEYWORDS: Pathology, Digital imaging, Image analysis, Diagnostics, Medical imaging, Machine learning, Image classification, Prostate cancer, Visualization, Image quality

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SPIE Journal Paper | 28 March 2017

Connecting Markov random fields and active contour models: application to gland segmentation and classification

Jun Xu, James Monaco, Rachel Sparks, Anant Madabhushi

JMI, Vol. 4, Issue 02, 021107, (March 2017) https://doi.org/10.1117/12.10.1117/1.JMI.4.2.021107

KEYWORDS: Tissues, Image segmentation, Performance modeling, Magnetorheological finishing, Prostate, Data modeling, Actinium, Tumor growth modeling, Visual process modeling, Statistical modeling

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SPIE Journal Paper | 11 March 2017

Training a cell-level classifier for detecting basal-cell carcinoma by combining human visual attention maps with low-level handcrafted features

Germán Corredor, Jon Whitney, Viviana Arias Pedroza, Anant Madabhushi, Eduardo Romero Castro

JMI, Vol. 4, Issue 02, 021105, (March 2017) https://doi.org/10.1117/12.10.1117/1.JMI.4.2.021105

KEYWORDS: Visualization, Cancer, Tumor growth modeling, Diagnostics, Visual process modeling, Information visualization, Pathology, Image segmentation, Feature extraction, Medical imaging

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Proceedings Article | 3 March 2017 Presentation + Paper

Radiogenomic analysis of hypoxia pathway reveals computerized MRI descriptors predictive of overall survival in glioblastoma

Niha Beig, Jay Patel, Prateek Prasanna, Sasan Partovi, Vinay Varadan, Anant Madabhushi, Pallavi Tiwari

Proceedings Volume 10134, 101341U (2017) https://doi.org/10.1117/12.2255694

KEYWORDS: Hypoxia, Magnetic resonance imaging, Brain, Cancer, Tumors, Statistical analysis, Feature extraction, Oxygen, Positron emission tomography

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Glioblastoma Multiforme (GBM) is a highly aggressive brain tumor with a median survival of 14 months. Hypoxia is a hallmark trait in GBM that is known to be associated with angiogenesis, tumor growth, and resistance to conventional therapy, thereby limiting treatment options for GBM patients. There is thus an urgent clinical need for non-invasively capturing tumor hypoxia in GBM towards identifying a subset of patients who would likely benefit from anti-angiogenic therapies (bevacizumab) in the adjuvant setting. In this study, we employed radiomic descriptors to (a) capture molecular variations of tumor hypoxia on routine MRI that are otherwise not appreciable; and (b) employ the radiomic correlates of hypoxia to discriminate patients with short-term survival (STS, overall survival (OS) < 7 months), mid-term survival (MTS) (7 months<OS<16 months), and long-term survival (LTS, OS>16 months). A total of 97 studies (25 STS, 36 MTS, 36 LTS) with Gadolinium T1-contrast (Gd-T1c), T2w, and FLAIR protocols with their corresponding gene expression profiles were obtained from the cancer genome atlas (TCGA) database. For each MRI study, necrotic, enhancing tumor, and edematous regions were segmented by an expert. A total of 30 radiomic descriptors (i.e. Haralick, Laws energy, Gabor) were extracted from every region across all three MRI protocols. By performing unsupervised clustering of the expression profile of hypoxia associated genes, a "low", "medium", or "high" index was defined for every study. Spearman correlation was then used to identify the most significantly correlated MRI features with the hypoxia index for every study. These features were further used to categorize each study as STS, MTS, and LTS using Kaplan-Meier (KM) analysis. Our results revealed that the most significant features (p < 0.05) were identified as Laws energy and Haralick features that capture image heterogeneity on FLAIR and Gd-T1w sequences. We also found these radiomic features to be significantly associated with survival, distinguishing MTS from LTS (p=.005) and STS from LTS (p=.0008).

SPIE Journal Paper | 24 October 2016

Evaluating stability of histomorphometric features across scanner and staining variations: prostate cancer diagnosis from whole slide images

Patrick Leo, George Lee, Natalie N. Shih, Robin Elliott, Michael Feldman, Anant Madabhushi

JMI, Vol. 3, Issue 04, 047502, (October 2016) https://doi.org/10.1117/12.10.1117/1.JMI.3.4.047502

KEYWORDS: Scanners, Image segmentation, Lithium, Feature extraction, Prostate cancer, Pathology, Cancer, Tumors, RGB color model, Tissues

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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 | 23 March 2016 Paper

Evaluating stability of histomorphometric features across scanner and staining variations: predicting biochemical recurrence from prostate cancer whole slide images

Patrick Leo, George Lee, Anant Madabhushi

Proceedings Volume 9791, 97910I (2016) https://doi.org/10.1117/12.2217053

KEYWORDS: Pathology, Prostate cancer, Scanners, Image processing, Digital image processing, Feature extraction, Machine learning, Feature selection, Image segmentation, Tissues, RGB color model

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Quantitative histomorphometry (QH) is the process of computerized extraction of features from digitized tissue slide images. Typically these features are used in machine learning classifiers to predict disease presence, behavior and outcome. Successful robust classifiers require features that both discriminate between classes of interest and are stable across data from multiple sites. Feature stability may be compromised by variation in slide staining and scanning procedures. These laboratory specific variables include dye batch, slice thickness and the whole slide scanner used to digitize the slide. The key therefore is to be able to identify features that are not only discriminating between the classes of interest (e.g. cancer and non-cancer or biochemical recurrence and non- recurrence) but also features that will not wildly fluctuate on slides representing the same tissue class but from across multiple different labs and sites. While there has been some recent efforts at understanding feature stability in the context of radiomics applications (i.e. feature analysis of radiographic images), relatively few attempts have been made at studying the trade-off between feature stability and discriminability for histomorphometric and digital pathology applications. In this paper we present two new measures, preparation-induced instability score (PI) and latent instability score (LI), to quantify feature instability across and within datasets. Dividing PI by LI yields a ratio for how often a feature for a specific tissue class (e.g. low grade prostate cancer) is different between datasets from different sites versus what would be expected from random chance alone. Using this ratio we seek to quantify feature vulnerability to variations in slide preparation and digitization. Since our goal is to identify stable QH features we evaluate these features for their stability and thus inclusion in machine learning based classifiers in a use case involving prostate cancer. Specifically we examine QH features which may predict 5 year biochemical recurrence for prostate cancer patients who have undergone radical prostatectomy from digital slide images of surgically excised tissue specimens, 5 year biochemical recurrence being a strong predictor of disease recurrence. In this study we evaluated the ability of our feature robustness indices to identify the most stable and predictive features of 5 year biochemical recurrence using digitized slide images of surgically excised prostate cancer specimens from 80 different patients across 4 different sites. A total of 242 features from 5 different feature families were investigated to identify the most stable QH features from our set. Our feature robustness indices (PI and LI) suggested that five feature families (graph, shape, co-occurring gland tensors, gland sub-graphs, texture) were susceptible to variations in slide preparation and digitization across various sites. The family least affected was shape features in which 19.3% of features varied across laboratories while the most vulnerable family, at 55.6%, was the gland disorder features. However the disorder features were the most stable within datasets being different between random halves of a dataset in an average of just 4.1% of comparisons while texture features were the most unstable being different at a rate of 4.7%. We also compared feature stability across two datasets before and after color normalization. Color normalization decreased feature stability with 8% and 34% of features different between the two datasets in two outcome groups prior to normalization and 49% and 51% different afterwards. Our results appear to suggest that evaluation of QH features across multiple sites needs to be undertaken to assess robustness and class discriminability alone should not represent the benchmark for selection of QH features to build diagnostic and prognostic digital pathology classifiers.

Proceedings Article | 21 March 2016 Paper

Multi-modality registration via multi-scale textural and spectral embedding representations

Lin Li, Mirabela Rusu, Satish Viswanath, Gregory Penzias, Shivani Pahwa, Jay Gollamudi, Anant Madabhushi

Proceedings Volume 9784, 978446 (2016) https://doi.org/10.1117/12.2217639

KEYWORDS: Image registration, Magnetic resonance imaging, Independent component analysis, Cancer, Feature extraction, Chromium, Prostate, Image segmentation, In vivo imaging, Pathology

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Intensity-based similarity measures assume that the original signal intensity of different modality images can provide statistically consistent information regarding the two modalities to be co-registered. In multi-modal registration problems, however, intensity-based similarity measures are often inadequate to identify an optimal transformation. Texture features can improve the performance of the multi-modal co-registration by providing more similar appearance representations of the two images to be co-registered, compared to the signal intensity representations. Furthermore, texture features extracted at different length scales (neighborhood sizes) can reveal similar underlying structural attributes between the images to be co-registered similarities that may not be discernible on the signal intensity representation alone. However one limitation of using texture features is that a number of them may be redundant and dependent and hence there is a need to identify non-redundant representations. Additionally it is not clear which features at which specific scales reveal similar attributes across the images to be co-registered. To address this problem, we introduced a novel approach for multimodal co-registration that employs new multi-scale image representations. Our approach comprises 4 distinct steps: (1) texure feature extraction at each length scale within both the target and template images, (2) independent component analysis (ICA) at each texture feature length scale, and (3) spectrally embedding (SE) the ICA components (ICs) obtained for the texture features at each length scale, and finally (4) identifying and combining the optimal length scales at which to perform the co-registration. To combine and co-register across different length scales, -mutual information (-MI) was applied in the high dimensional space of spectral embedding vectors to facilitate co-registration. To validate our multi-scale co-registration approach, we aligned 45 pairs of prostate MRI and histology images corresponding to the prostate with the objective of mapping extent of prostate cancer annotated by a pathologist on the pathology onto the pre-operative MRI. The registration results showed higher correlation between template and target images with average correlation ratio of 0.927 compared to 0.914 for intensity-based registration. Additionally an improvement in the dice similarity coefficient (DSC) of 13.6% was observed for the multi-scale registration compared to intensity-based registration and an 1.26% DSC improvement compared to registration involving the best individual scale.

Proceedings Article | 22 December 2015 Paper

A method for medulloblastoma tumor differentiation based on convolutional neural networks and transfer learning

Angel Cruz-Roa, John Arévalo, Alexander Judkins, Anant Madabhushi, Fabio González

Proceedings Volume 9681, 968103 (2015) https://doi.org/10.1117/12.2208825

KEYWORDS: Convolutional neural networks, Visualization, Tumors, Visual process modeling, Data modeling, Feature extraction, RGB color model, Tissues, Tumor growth modeling, Machine vision

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SPIE Journal Paper | 1 October 2015

Association of computerized texture features on MRI with early treatment response following laser ablation for neuropathic cancer pain: preliminary findings

Pallavi Tiwari, Shabbar Danish, Benjamin Jiang, Anant Madabhushi

JMI, Vol. 2, Issue 04, 041008, (October 2015) https://doi.org/10.1117/12.10.1117/1.JMI.2.4.041008

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Laser interstitial thermal therapy (LITT) has recently emerged as a new treatment modality for cancer pain management that targets the cingulum (pain center in the brain) and has shown promise over radio frequency (RF)-based ablation, due to magnetic resonance image (MRI) guidance that allows for precise ablation. Since laser ablation for pain management is currently exploratory and is only performed at a few centers worldwide, its short- and long-term effects on the cingulum are currently unknown. Traditionally, treatment effects for neurological conditions are evaluated by monitoring changes in intensities and/or volume of the ablation zone on post-treatment Gadolinium-contrast T1-w (Gd-T1) MRI. However, LITT introduces subtle localized changes corresponding to tissues response to treatment, which may not be appreciable on visual inspection of volumetric or intensity changes. Additionally, different MRI protocols [Gd-T1, T2w, gradient echo sequence (GRE), fluidattenuated inversion recovery (FLAIR)] are known to capture complementary diagnostic information regarding the patient’s response to treatment; the utility of these MRI protocols has so far not been investigated to evaluate early and localized response to LITT treatment in the context of neuropathic cancer pain. In this work, we present the first attempt at (a) examining early treatment-related changes on a per-voxel basis via quantitative comparison of computer-extracted texture descriptors across pre- and post-LITT multiparametric (MP-MRI) (Gd-T1, T2w, GRE, FLAIR), subtle microarchitectural texture changes that may not be appreciable on original MR intensities or volumetric differences, and (b) investigating the efficacy of different MRI protocols in accurately capturing immediate post-treatment changes reflected (1) within and (2) outside the ablation zone. A retrospective cohort of four patient studies comprising pre- and immediate (24 h) post-LITT 3 Tesla Gd-T1, T2w, GRE, and FLAIR acquisitions was considered. Our quantitative approach first involved intensity standardization to allow for grayscale MR intensities acquired pre- and post-LITT to have a fixed tissue-specific meaning within the same imaging protocol, the same body region, and within the same patient. An affine registration was then performed on individual post-LITT MRI protocols to a reference MRI protocol pre-LITT. A total of 78 computerized texture features (co-occurrence matrix homogeneity, neighboring gray-level dependence matrix, Gabor) are then extracted from pre- and post-LITT MP-MRI on a per-voxel basis. Quantitative, voxelwise comparison of the changes in MRI texture features between pre- and post-LITT MRI indicate that (a) Gabor texture features at specific orientations were highly sensitive as well as specific in predicting subtle microarchitectural changes within and around the ablation zone pre- and post-LITT, (b) FLAIR was identified as the most sensitive MRI protocol in identifying early treatment changes yielding a normalized percentage change of 360% within the ablation zone relative to its pre-LITT value, and (c) GRE was identified as the most sensitive MRI protocol in quantifying changes outside the ablation zone post-LITT. Our preliminary results thus indicate potential for noninvasive computerized MP-MRI features over volumetric features in determining localized microarchitectural early focal treatment changes post-LITT for neuropathic cancer pain treatment.

Proceedings Article | 28 January 2015 Paper

A note on the stability and discriminability of graph-based features for classification problems in digital pathology

Angel Cruz-Roa, Jun Xu, Anant Madabhushi

Proceedings Volume 9287, 928703 (2015) https://doi.org/10.1117/12.2085141

KEYWORDS: Image segmentation, Cancer, Pathology, Tumors, Tissues, Feature extraction, Breast cancer, Image processing algorithms and systems, Detection and tracking algorithms, Prostate

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Nuclear architecture or the spatial arrangement of individual cancer nuclei on histopathology images has been shown to be associated with different grades and differential risk for a number of solid tumors such as breast, prostate, and oropharyngeal. Graph-based representations of individual nuclei (nuclei representing the graph nodes) allows for mining of quantitative metrics to describe tumor morphology. These graph features can be broadly categorized into global and local depending on the type of graph construction method. While a number of local graph (e.g. Cell Cluster Graphs) and global graph (e.g. Voronoi, Delaunay Triangulation, Minimum Spanning Tree) features have been shown to associated with cancer grade, risk, and outcome for different cancer types, the sensitivity of the preceding segmentation algorithms in identifying individual nuclei can have a significant bearing on the discriminability of the resultant features. This therefore begs the question as to which features while being discriminative of cancer grade and aggressiveness are also the most resilient to the segmentation errors. These properties are particularly desirable in the context of digital pathology images, where the method of slide preparation, staining, and type of nuclear segmentation algorithm employed can all dramatically affect the quality of the nuclear graphs and corresponding features. In this paper we evaluated the trade off between discriminability and stability of both global and local graph-based features in conjunction with a few different segmentation algorithms and in the context of two different histopathology image datasets of breast cancer from whole-slide images (WSI) and tissue microarrays (TMA). Specifically in this paper we investigate a few different performance measures including stability, discriminability and stability vs discriminability trade off, all of which are based on p-values from the Kruskal-Wallis one-way analysis of variance for local and global graph features. Apart from identifying the set of local and global features that satisfied the trade off between stability and discriminability, our most interesting finding was that a simple segmentation method was sufficient to identify the most discriminant features for invasive tumour detection in TMAs, whereas for tumour grading in WSI, the graph based features were more sensitive to the accuracy of the segmentation algorithm employed.

Proceedings Article | 28 January 2015 Paper

A comparative evaluation of supervised and unsupervised representation learning approaches for anaplastic medulloblastoma differentiation

Angel Cruz-Roa, John Arevalo, Ajay Basavanhally, Anant Madabhushi, Fabio González

Proceedings Volume 9287, 92870G (2015) https://doi.org/10.1117/12.2073849

KEYWORDS: Tumors, Machine learning, Neurons, Tumor growth modeling, Independent component analysis, Pathology, Sensors, Pattern recognition, Feature extraction, Convolutional neural networks

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SPIE Journal Paper | 27 October 2014

Quantitative identification of magnetic resonance imaging features of prostate cancer response following laser ablation and radical prostatectomy

Geert J. S. Litjens, Henkjan J. Huisman, Robin M. Elliott, Natalie Nc. Shih, Michael D. Feldman, Satish Viswanath, Jurgen Fütterer, Joyce G. R. Bomers, Anant Madabhushi

JMI, Vol. 1, Issue 03, 035001, (October 2014) https://doi.org/10.1117/12.10.1117/1.JMI.1.3.035001

KEYWORDS: Magnetic resonance imaging, Prostate cancer, Tissues, Prostate, Laser therapeutics, Feature extraction, Laser ablation, Image registration, Scanners, Pathology

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SPIE Journal Paper | 10 October 2014

Mitosis detection in breast cancer pathology images by combining handcrafted and convolutional neural network features

Haibo Wang, Angel Cruz Roa, Ajay Basavanhally, Hannah Gilmore, Natalie Shih, Mike Feldman, John Tomaszewski, Fabio Gonzalez, Anant Madabhushi

JMI, Vol. 1, Issue 03, 034003, (October 2014) https://doi.org/10.1117/12.10.1117/1.JMI.1.3.034003

KEYWORDS: Breast cancer, Pathology, Feature extraction, Image segmentation, Computing systems, Neurons, RGB color model, Scanners, Convolutional neural networks, Microscopes

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Breast cancer (BCa) grading plays an important role in predicting disease aggressiveness and patient outcome. A key component of BCa grade is the mitotic count, which involves quantifying the number of cells in the process of dividing (i.e., undergoing mitosis) at a specific point in time. Currently, mitosis counting is done manually by a pathologist looking at multiple high power fields (HPFs) on a glass slide under a microscope, an extremely laborious and time consuming process. The development of computerized systems for automated detection of mitotic nuclei, while highly desirable, is confounded by the highly variable shape and appearance of mitoses. Existing methods use either handcrafted features that capture certain morphological, statistical, or textural attributes of mitoses or features learned with convolutional neural networks (CNN). Although handcrafted features are inspired by the domain and the particular application, the data-driven CNN models tend to be domain agnostic and attempt to learn additional feature bases that cannot be represented through any of the handcrafted features. On the other hand, CNN is computationally more complex and needs a large number of labeled training instances. Since handcrafted features attempt to model domain pertinent attributes and CNN approaches are largely supervised feature generation methods, there is an appeal in attempting to combine these two distinct classes of feature generation strategies to create an integrated set of attributes that can potentially outperform either class of feature extraction strategies individually. We present a cascaded approach for mitosis detection that intelligently combines a CNN model and handcrafted features (morphology, color, and texture features). By employing a light CNN model, the proposed approach is far less demanding computationally, and the cascaded strategy of combining handcrafted features and CNN-derived features enables the possibility of maximizing the performance by leveraging the disconnected feature sets. Evaluation on the public ICPR12 mitosis dataset that has 226 mitoses annotated on 35 HPFs (400× magnification) by several pathologists and 15 testing HPFs yielded an F-measure of 0.7345. Our approach is accurate, fast, and requires fewer computing resources compared to existent methods, making this feasible for clinical use.

Proceedings Article | 24 March 2014 Paper

Computer extracted texture features on T2w MRI to predict biochemical recurrence following radiation therapy for prostate cancer

Shoshana Ginsburg, Mirabela Rusu, John Kurhanewicz, Anant Madabhushi

Proceedings Volume 9035, 903509 (2014) https://doi.org/10.1117/12.2043937

KEYWORDS: Magnetic resonance imaging, Feature extraction, Prostate cancer, Radiotherapy, Tumors, Feature selection, Wavelets, Cancer, Prostate, Spectroscopy

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In this study we explore the ability of a novel machine learning approach, in conjunction with computer-extracted features describing prostate cancer morphology on pre-treatment MRI, to predict whether a patient will develop biochemical recurrence within ten years of radiation therapy. Biochemical recurrence, which is characterized by a rise in serum prostate-specific antigen (PSA) of at least 2 ng/mL above the nadir PSA, is associated with increased risk of metastasis and prostate cancer-related mortality. Currently, risk of biochemical recurrence is predicted by the Kattan nomogram, which incorporates several clinical factors to predict the probability of recurrence-free survival following radiation therapy (but has limited prediction accuracy). Semantic attributes on T2w MRI, such as the presence of extracapsular extension and seminal vesicle invasion and surrogate measure- ments of tumor size, have also been shown to be predictive of biochemical recurrence risk. While the correlation between biochemical recurrence and factors like tumor stage, Gleason grade, and extracapsular spread are well- documented, it is less clear how to predict biochemical recurrence in the absence of extracapsular spread and for small tumors fully contained in the capsule. Computer{extracted texture features, which quantitatively de- scribe tumor micro-architecture and morphology on MRI, have been shown to provide clues about a tumor's aggressiveness. However, while computer{extracted features have been employed for predicting cancer presence and grade, they have not been evaluated in the context of predicting risk of biochemical recurrence. This work seeks to evaluate the role of computer-extracted texture features in predicting risk of biochemical recurrence on a cohort of sixteen patients who underwent pre{treatment 1.5 Tesla (T) T2w MRI. We extract a combination of first-order statistical, gradient, co-occurrence, and Gabor wavelet features from T2w MRI. To identify which of these T2w MRI texture features are potential independent prognostic markers of PSA failure, we implement a partial least squares (PLS) method to embed the data in a low{dimensional space and then use the variable importance in projections (VIP) method to quantify the contributions of individual features to classification on the PLS embedding. In spite of the poor resolution of the 1.5 T MRI data, we are able to identify three Gabor wavelet features that, in conjunction with a logistic regression classifier, yield an area under the receiver operating characteristic curve of 0.83 for predicting the probability of biochemical recurrence following radiation therapy. In comparison to both the Kattan nomogram and semantic MRI attributes, the ability of these three computer-extracted features to predict biochemical recurrence risk is demonstrated.

Proceedings Article | 21 March 2014 Paper

Spatially aware expectation maximization (SpAEM): application to prostate TRUS segmentation

Mahdi Orooji, Rachel Sparks, B. Nicolas Bloch, Ernest Feleppa, Dean Barratt, Anant Madabhushi

Proceedings Volume 9034, 90343Y (2014) https://doi.org/10.1117/12.2043981

KEYWORDS: Prostate, Image segmentation, Ultrasonography, Expectation maximization algorithms, Feature extraction, Image processing, Image filtering, Statistical analysis, Medical imaging, Cancer

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Proceedings Article | 21 March 2014 Paper

Spectral embedding-based registration (SERg) for multimodal fusion of prostate histology and MRI

Eileen Hwuang, Mirabela Rusu, Sudha Karthigeyan, Shannon Agner, Rachel Sparks, Natalie Shih, John Tomaszewski, Mark Rosen, Michael Feldman, Anant Madabhushi

Proceedings Volume 9034, 90343P (2014) https://doi.org/10.1117/12.2044317

KEYWORDS: Image registration, Magnetic resonance imaging, Prostate, Independent component analysis, Chromium, Feature extraction, Image restoration, Image segmentation, Brain, Neuroimaging

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Multi-modal image registration is needed to align medical images collected from different protocols or imaging sources, thereby allowing the mapping of complementary information between images. One challenge of multimodal image registration is that typical similarity measures rely on statistical correlations between image intensities to determine anatomical alignment. The use of alternate image representations could allow for mapping of intensities into a space or representation such that the multimodal images appear more similar, thus facilitating their co-registration. In this work, we present a spectral embedding based registration (SERg) method that uses non-linearly embedded representations obtained from independent components of statistical texture maps of the original images to facilitate multimodal image registration. Our methodology comprises the following main steps: 1) image-derived textural representation of the original images, 2) dimensionality reduction using independent component analysis (ICA), 3) spectral embedding to generate the alternate representations, and 4) image registration. The rationale behind our approach is that SERg yields embedded representations that can allow for very different looking images to appear more similar, thereby facilitating improved co-registration. Statistical texture features are derived from the image intensities and then reduced to a smaller set by using independent component analysis to remove redundant information. Spectral embedding generates a new representation by eigendecomposition from which only the most important eigenvectors are selected. This helps to accentuate areas of salience based on modality-invariant structural information and therefore better identifies corresponding regions in both the template and target images. The spirit behind SERg is that image registration driven by these areas of salience and correspondence should improve alignment accuracy. In this work, SERg is implemented using Demons to allow the algorithm to more effectively register multimodal images. SERg is also tested within the free-form deformation framework driven by mutual information. Nine pairs of synthetic T1-weighted to T2-weighted brain MRI were registered under the following conditions: five levels of noise (0%, 1%, 3%, 5%, and 7%) and two levels of bias field (20% and 40%) each with and without noise. We demonstrate that across all of these conditions, SERg yields a mean squared error that is 81.51% lower than that of Demons driven by MRI intensity alone. We also spatially align twenty-six ex vivo histology sections and in vivo prostate MRI in order to map the spatial extent of prostate cancer onto corresponding radiologic imaging. SERg performs better than intensity registration by decreasing the root mean squared distance of annotated landmarks in the prostate gland via both Demons algorithm and mutual information-driven free-form deformation. In both synthetic and clinical experiments, the observed improvement in alignment of the template and target images suggest the utility of parametric eigenvector representations and hence SERg for multimodal image registration.

Proceedings Article | 20 March 2014 Paper

Cascaded ensemble of convolutional neural networks and handcrafted features for mitosis detection

Haibo Wang, Angel Cruz-Roa, Ajay Basavanhally, Hannah Gilmore, Natalie Shih, Mike Feldman, John Tomaszewski, Fabio Gonzalez, Anant Madabhushi

Proceedings Volume 9041, 90410B (2014) https://doi.org/10.1117/12.2043902

KEYWORDS: Feature extraction, RGB color model, Computing systems, Scanners, Breast cancer, Data modeling, Microscopes, Image segmentation, Convolutional neural networks, Glasses

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Breast cancer (BCa) grading plays an important role in predicting disease aggressiveness and patient outcome. A key component of BCa grade is mitotic count, which involves quantifying the number of cells in the process of dividing (i.e. undergoing mitosis) at a specific point in time. Currently mitosis counting is done manually by a pathologist looking at multiple high power fields on a glass slide under a microscope, an extremely laborious and time consuming process. The development of computerized systems for automated detection of mitotic nuclei, while highly desirable, is confounded by the highly variable shape and appearance of mitoses. Existing methods use either handcrafted features that capture certain morphological, statistical or textural attributes of mitoses or features learned with convolutional neural networks (CNN). While handcrafted features are inspired by the domain and the particular application, the data-driven CNN models tend to be domain agnostic and attempt to learn additional feature bases that cannot be represented through any of the handcrafted features. On the other hand, CNN is computationally more complex and needs a large number of labeled training instances. Since handcrafted features attempt to model domain pertinent attributes and CNN approaches are largely unsupervised feature generation methods, there is an appeal to attempting to combine these two distinct classes of feature generation strategies to create an integrated set of attributes that can potentially outperform either class of feature extraction strategies individually. In this paper, we present a cascaded approach for mitosis detection that intelligently combines a CNN model and handcrafted features (morphology, color and texture features). By employing a light CNN model, the proposed approach is far less demanding computationally, and the cascaded strategy of combining handcrafted features and CNN-derived features enables the possibility of maximizing performance by leveraging the disconnected feature sets. Evaluation on the public ICPR12 mitosis dataset that has 226 mitoses annotated on 35 High Power Fields (HPF, x400 magnification) by several pathologists and 15 testing HPFs yielded an F-measure of 0.7345. Apart from this being the second best performance ever recorded for this MITOS dataset, our approach is faster and requires fewer computing resources compared to extant methods, making this feasible for clinical use.

Proceedings Article | 20 March 2014 Paper

Automatic detection of invasive ductal carcinoma in whole slide images with convolutional neural networks

Angel Cruz-Roa, Ajay Basavanhally, Fabio González, Hannah Gilmore, Michael Feldman, Shridar Ganesan, Natalie Shih, John Tomaszewski, Anant Madabhushi

Proceedings Volume 9041, 904103 (2014) https://doi.org/10.1117/12.2043872

KEYWORDS: Tissues, Visualization, Tumors, Image segmentation, Convolution, Breast cancer, RGB color model, Pathology, Convolutional neural networks, Tumor growth modeling

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This paper presents a deep learning approach for automatic detection and visual analysis of invasive ductal carcinoma (IDC) tissue regions in whole slide images (WSI) of breast cancer (BCa). Deep learning approaches are learn-from-data methods involving computational modeling of the learning process. This approach is similar to how human brain works using different interpretation levels or layers of most representative and useful features resulting into a hierarchical learned representation. These methods have been shown to outpace traditional approaches of most challenging problems in several areas such as speech recognition and object detection. Invasive breast cancer detection is a time consuming and challenging task primarily because it involves a pathologist scanning large swathes of benign regions to ultimately identify the areas of malignancy. Precise delineation of IDC in WSI is crucial to the subsequent estimation of grading tumor aggressiveness and predicting patient outcome. DL approaches are particularly adept at handling these types of problems, especially if a large number of samples are available for training, which would also ensure the generalizability of the learned features and classifier. The DL framework in this paper extends a number of convolutional neural networks (CNN) for visual semantic analysis of tumor regions for diagnosis support. The CNN is trained over a large amount of image patches (tissue regions) from WSI to learn a hierarchical part-based representation. The method was evaluated over a WSI dataset from 162 patients diagnosed with IDC. 113 slides were selected for training and 49 slides were held out for independent testing. Ground truth for quantitative evaluation was provided via expert delineation of the region of cancer by an expert pathologist on the digitized slides. The experimental evaluation was designed to measure classifier accuracy in detecting IDC tissue regions in WSI. Our method yielded the best quantitative results for automatic detection of IDC regions in WSI in terms of F-measure and balanced accuracy (71.80%, 84.23%), in comparison with an approach using handcrafted image features (color, texture and edges, nuclear textural and architecture), and a machine learning classifier for invasive tumor classification using a Random Forest. The best performing handcrafted features were fuzzy color histogram (67.53%, 78.74%) and RGB histogram (66.64%, 77.24%). Our results also suggest that at least some of the tissue classification mistakes (false positives and false negatives) were less due to any fundamental problems associated with the approach, than the inherent limitations in obtaining a very highly granular annotation of the diseased area of interest by an expert pathologist.

Proceedings Article | 18 March 2014 Paper

Distinguishing prostate cancer from benign confounders via a cascaded classifier on multi-parametric MRI

G.J.S. Litjens, R. Elliott, N. Shih, M. Feldman, J. Barentsz, C. Hulsbergen - van de Kaa, I. Kovacs, H. Huisman, A. Madabhushi

Proceedings Volume 9035, 903512 (2014) https://doi.org/10.1117/12.2043751

KEYWORDS: Magnetic resonance imaging, Prostate cancer, Cancer, Feature selection, Prostate, Feature extraction, Tissues, Pathology, Scanners, Diagnostics

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Learning how to separate benign confounders from prostate cancer is important because the imaging characteristics of these confounders are poorly understood. Furthermore, the typical representations of the MRI parameters might not be enough to allow discrimination. The diagnostic uncertainty this causes leads to a lower diagnostic accuracy. In this paper a new cascaded classifier is introduced to separate prostate cancer and benign confounders on MRI in conjunction with specific computer-extracted features to distinguish each of the benign classes (benign prostatic hyperplasia (BPH), inflammation, atrophy or prostatic intra-epithelial neoplasia (PIN). In this study we tried to (1) calculate different mathematical representations of the MRI parameters which more clearly express subtle differences between different classes, (2) learn which of the MRI image features will allow to distinguish specific benign confounders from prostate cancer, and (2) find the combination of computer-extracted MRI features to best discriminate cancer from the confounding classes using a cascaded classifier. One of the most important requirements for identifying MRI signatures for adenocarcinoma, BPH, atrophy, inflammation, and PIN is accurate mapping of the location and spatial extent of the confounder and cancer categories from ex vivo histopathology to MRI. Towards this end we employed an annotated prostatectomy data set of 31 patients, all of whom underwent a multi-parametric 3 Tesla MRI prior to radical prostatectomy. The prostatectomy slides were carefully co-registered to the corresponding MRI slices using an elastic registration technique. We extracted texture features from the T2-weighted imaging, pharmacokinetic features from the dynamic contrast enhanced imaging and diffusion features from the diffusion-weighted imaging for each of the confounder classes and prostate cancer. These features were selected because they form the mainstay of clinical diagnosis. Relevant features for each of the classes were selected using maximum relevance minimum redundancy feature selection, allowing us to perform classifier independent feature selection. The selected features were then incorporated in a cascading classifier, which can focus on easier sub-tasks at each stage, leaving the more difficult classification tasks for later stages. Results show that distinct features are relevant for each of the benign classes, for example the fraction of extra-vascular, extra-cellular space in a voxel is a clear discriminator for inflammation. Furthermore, the cascaded classifier outperforms both multi-class and one-shot classifiers in overall accuracy for discriminating confounders from cancer: 0.76 versus 0.71 and 0.62.

Proceedings Article | 18 March 2014 Paper

A prostate MRI atlas of biochemical failures following cancer treatment

Mirabela Rusu, John Kurhanewicz, Ashutosh Tewari, Anant Madabhushi

Proceedings Volume 9035, 903513 (2014) https://doi.org/10.1117/12.2043775

KEYWORDS: Magnetic resonance imaging, Prostate, Cancer, Radiotherapy, Prostate cancer, Oncology, Principal component analysis, Surgery, Therapeutics, Statistical analysis

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Radical prostatectomy (RP) and radiation therapy (RT) are the most common treatment options for prostate cancer (PCa). Despite advancements in radiation delivery and surgical procedures, RP and RT can result in failure rates as high as 40% and >25%, respectively. Treatment failure is characterized by biochemical recurrence (BcR), which is defined in terms of prostate specific antigen (PSA) concentrations and its variation following treatment. PSA is expected to decrease following treatment, thereby its presence in even small concentrations (e.g 0.2 ng/ml for surgery or 2 ng/ml over the nadir PSA for radiation therapy) is indicative of treatment failure. Early identification of treatment failure may enable the use of more aggressive or neo-adjuvant therapies. Moreover, predicting failure prior to treatment may spare the patient from a procedure that is unlikely to be successful. Our goal is to identify differences on pre-treatment MRI between patients who have BcR and those who remain disease-free at 5 years post-treatment. Specifically, we focus on (1) identifying statistically significant differences in MRI intensities, (2) establishing morphological differences in prostatic anatomic structures, and (3) comparing these differences with the natural variability of prostatic structures. In order to attain these objectives, we use an anatomically constrained registration framework to construct BcR and non-BcR statistical atlases based on the pre-treatment magnetic resonance images (MRI) of the prostate. The patients included in the atlas either underwent RP or RT and were followed up for at least 5 years. The BcR atlas was constructed from a combined population of 12 pre-RT 1.5 Tesla (T) MRI and 33 pre-RP 3T MRI from patients with BcR within 5 years of treatment. Similarly, the non-BcR atlas was built based on a combined cohort of 20 pre-RT 1.5T MRI and 41 pre-RP 3T MRI from patients who remain disease-free 5 years post treatment. We chose the atlas framework as it enables the mapping of MR images from all subjects into the same canonical space, while constructing both an imaging and a morphological statistical atlas. Such co-registration allowed us to perform voxel-by-voxel comparisons of MRI intensities and capsule and central gland morphology to identify statistically significant differences between the BcR and non-BcR patient populations. To assess whether the morphological differences are valid, we performed an additional experiment where we constructed sub-population atlases by randomly sampling RT patients to construct the BcR and non-BcR atlases. Following these experiments we observed that: (1) statistically significant MRI intensity differences exist between BcR and non-BcR patients, specifically on the border of the central gland; (2) statistically significant morphological differences are visible in the prostate and central gland, specifically in the proximity of the apex, and (3) the differences between the BcR and non-BcR cohorts in terms of shape appeared to be consistent across these sub-population atlases as observed in our RT atlases.

Proceedings Article | 18 March 2014 Paper

Texture descriptors to distinguish radiation necrosis from recurrent brain tumors on multi-parametric MRI

Pallavi Tiwari, Prateek Prasanna, Lisa Rogers, Leo Wolansky, Chaitra Badve, Andrew Sloan, Mark Cohen, Anant Madabhushi

Proceedings Volume 9035, 90352B (2014) https://doi.org/10.1117/12.2043969

KEYWORDS: Magnetic resonance imaging, Radon, Tumors, Brain, Pathology, Feature extraction, Principal component analysis, Positron emission tomography, Biopsy, Visualization

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Di erentiating radiation necrosis (a radiation induced treatment e ect) from recurrent brain tumors (rBT) is currently one of the most clinically challenging problems in care and management of brain tumor (BT) patients. Both radiation necrosis (RN), and rBT exhibit similar morphological appearance on standard MRI making non-invasive diagnosis extremely challenging for clinicians, with surgical intervention being the only course for obtaining de nitive ground truth". Recent studies have reported that the underlying biological pathways de n- ing RN and rBT are fundamentally di erent. This strongly suggests that there might be phenotypic di erences and hence cues on multi-parametric MRI, that can distinguish between the two pathologies. One challenge is that these di erences, if they exist, might be too subtle to distinguish by the human observer. In this work, we explore the utility of computer extracted texture descriptors on multi-parametric MRI (MP-MRI) to provide alternate representations of MRI that may be capable of accentuating subtle micro-architectural di erences between RN and rBT for primary and metastatic (MET) BT patients. We further explore the utility of texture descriptors in identifying the MRI protocol (from amongst T1-w, T2-w and FLAIR) that best distinguishes RN and rBT across two independent cohorts of primary and MET patients. A set of 119 texture descriptors (co-occurrence matrix homogeneity, neighboring gray-level dependence matrix, multi-scale Gaussian derivatives, Law features, and histogram of gradient orientations (HoG)) for modeling di erent macro and micro-scale morphologic changes within the treated lesion area for each MRI protocol were extracted. Principal component analysis based variable importance projection (PCA-VIP), a feature selection method previously developed in our group, was employed to identify the importance of every texture descriptor in distinguishing RN and rBT on MP-MRI. PCA-VIP employs regression analysis to provide an importance score to each feature based on their ability to distinguish the two classes (RN/rBT). The top performing features identi ed via PCA-VIP were employed within a random- forest classi er to di erentiate RN from rBT across two cohorts of 20 primary and 22 MET patients. Our results revealed that, (a) HoG features at di erent orientations were the most important image features for both cohorts, suggesting inherent orientation di erences between RN, and rBT, (b) inverse di erence moment (capturing local intensity homogeneity), and Laws features (capturing local edges and gradients) were identi ed as important for both cohorts, and (c) Gd-C T1-w MRI was identi ed, across the two cohorts, as the best MRI protocol in distinguishing RN/rBT.

Proceedings Article | 13 March 2014 Paper

Supervised multi-view canonical correlation analysis: fused multimodal prediction of disease diagnosis and prognosis

Asha Singanamalli, Haibo Wang, George Lee, Natalie Shih, Mark Rosen, Stephen Master, John Tomaszewski, Michael Feldman, Anant Madabhushi

Proceedings Volume 9038, 903805 (2014) https://doi.org/10.1117/12.2043762

KEYWORDS: Magnetic resonance imaging, Data fusion, Principal component analysis, Canonical correlation analysis, Alzheimer's disease, Simulation of CCA and DLA aggregates, Tumors, Proteins, Prostate cancer, Biomedical optics

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While the plethora of information from multiple imaging and non-imaging data streams presents an opportunity for discovery of fused multimodal, multiscale biomarkers, they also introduce multiple independent sources of noise that hinder their collective utility. The goal of this work is to create fused predictors of disease diagnosis and prognosis by combining multiple data streams, which we hypothesize will provide improved performance as compared to predictors from individual data streams. To achieve this goal, we introduce supervised multiview canonical correlation analysis (sMVCCA), a novel data fusion method that attempts to find a common representation for multiscale, multimodal data where class separation is maximized while noise is minimized. In doing so, sMVCCA assumes that the different sources of information are complementary and thereby act synergistically when combined. Although this method can be applied to any number of modalities and to any disease domain, we demonstrate its utility using three datasets. We fuse (i) 1.5 Tesla (T) magnetic resonance imaging (MRI) features with cerbrospinal fluid (CSF) proteomic measurements for early diagnosis of Alzheimer’s disease (n = 30), (ii) 3T Dynamic Contrast Enhanced (DCE) MRI and T2w MRI for in vivo prediction of prostate cancer grade on a per slice basis (n = 33) and (iii) quantitative histomorphometric features of glands and proteomic measurements from mass spectrometry for prediction of 5 year biochemical recurrence postradical prostatectomy (n = 40). Random Forest classifier applied to the sMVCCA fused subspace, as compared to that of MVCCA, PCA and LDA, yielded the highest classification AUC of 0.82 +/- 0.05, 0.76 +/- 0.01, 0.70 +/- 0.07, respectively for the aforementioned datasets. In addition, sMVCCA fused subspace provided 13.6%, 7.6% and 15.3% increase in AUC as compared with that of the best performing individual view in each of the three datasets, respectively. For the biochemical recurrence dataset, Kaplan-Meier curves generated from classifier prediction in the fused subspace reached the significance threshold (p = 0.05) for distinguishing between patients with and without 5 year biochemical recurrence, unlike those generated from classifier predictions of the individual modalities.

Proceedings Article | 12 March 2014 Paper

Distinguishing benign confounding treatment changes from residual prostate cancer on MRI following laser ablation

G. Litjens, H. Huisman, R. Elliott, N. Shih, M. Feldman, S. Viswanath, J. Fütterer, J. Bomers, A. Madabhushi

Proceedings Volume 9036, 90361D (2014) https://doi.org/10.1117/12.2043819

KEYWORDS: Magnetic resonance imaging, Tissues, Prostate cancer, Prostate, Cancer, Feature extraction, Laser ablation, Laser therapeutics, Scanners, Image registration

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Laser interstitial thermotherapy (LITT) is a relatively new focal therapy technique for the ablation of localized prostate cancer. However, very little is known about the specific effects of LITT within the ablation zone and the surrounding normal tissue regions. For instance, it is important to be able to assess the extent of residual cancer within the prostate following LITT, which may be masked by thermally induced benign necrotic changes. Fortunately LITT is MRI compatible and hence this allows for quantitatively assessing LITT induced changes via multi-parametric MRI. Of course definite validation of any LITT induced changes on MRI requires confirmation via histopathology. The aim of this study was to quantitatively assess and distinguish the imaging characteristics of prostate cancer and benign confounding treatment changes following LITTon 3 Tesla multi-parametric MRI by carefully mapping the treatment related changes from the ex vivo surgically resected histopathologic specimens onto the pre-operative in vivo imaging. A better understanding of the imaging characteristics of residual disease and successfully ablated tissue might lead to improved treatment monitoring and as such patient prognosis. A unique clinical trial at the Radboud University Medical Center, in which 3 patients underwent a prostatectomy after LITT treatment, yielded ex-vivo histopathologic specimens along with pre- and post-LITT MRI. Using this data we (1) identified the computer extracted MRI signatures associated with treatment effects including benign necrotic changes and residual disease and (2) subsequently evaluated the computer extracted MRI features previously identified in distinguishing LITT induced changes in the ablated area relative to the residual disease. Towards this end first a pathologist annotated the ablated area and the residual disease on the ex-vivo histology and then we transferred the annotations to the post-LITT MRI using semi-automatic elastic registration. The pre- and post-LITT MRI were subsequently registered and computer-derived multi-parametric MRI features extracted to determine differences in feature values between residual disease and successfully ablated tissue to assess treatment response. A scoring metric allowed us to identify those specific computer-extracted MRI features that maximally and differentially expressed between the ablated regions and the residual cancer, on a voxel- by voxel basis. Finally, we used a Fuzzy C-Means algorithm to assess the discriminatory power of these selected features. Our results show that specific computer-extracted features from multi-parametric MRI differentially express within the ablated and residual cancer regions, as evidenced by our ability to, on a voxel-by-voxel basis, classify tissue as residual disease. Additionally, we show that change of feature values between pre- and post-LITT MRI may be useful as a quantitative marker for treatment response (T2-weighted texture and DCE MRI features showed largest differences between residual disease and successfully ablated tissue). Finally, a clustering approach to separate treatment effects and residual disease incorporating both (1) and (2) yielded a maximum area under the ROC curve of 0.97 on a voxel basis across 3 studies.

Proceedings Article | 12 March 2014 Paper

Identifying MRI markers to evaluate early treatment-related changes post-laser ablation for cancer pain management

Pallavi Tiwari, Shabbar Danish, Anant Madabhushi

Proceedings Volume 9036, 90362L (2014) https://doi.org/10.1117/12.2043729

KEYWORDS: Magnetic resonance imaging, Laser ablation, Cancer, Oncology, Tissues, Laser therapeutics, Visualization, In vivo imaging, Feature extraction, Laser dentistry

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Laser interstitial thermal therapy (LITT) has recently emerged as a new treatment modality for cancer pain management that targets the cingulum (pain center in the brain), and has shown promise over radio-frequency (RF) based ablation which is reported to provide temporary relief. One of the major advantages enjoyed by LITT is its compatibility with magnetic resonance imaging (MRI), allowing for high resolution in vivo imaging to be used in LITT procedures. Since laser ablation for pain management is currently exploratory and is only performed at a few centers worldwide, its short-, and long-term effects on the cingulum are currently unknown. Traditionally treatment effects are evaluated by monitoring changes in volume of the ablation zone post-treatment. However, this is sub-optimal since it involves evaluating a single global parameter (volume) to detect changes pre-, and post-MRI. Additionally, the qualitative observations of LITT-related changes on multi-parametric MRI (MPMRI) do not specifically address differentiation between the appearance of treatment related changes (edema, necrosis) from recurrence of the disease (pain recurrence). In this work, we explore the utility of computer extracted texture descriptors on MP-MRI to capture early treatment related changes on a per-voxel basis by extracting quantitative relationships that may allow for an in-depth understanding of tissue response to LITT on MRI, subtle changes that may not be appreciable on original MR intensities. The second objective of this work is to investigate the efficacy of different MRI protocols in accurately capturing treatment related changes within and outside the ablation zone post-LITT. A retrospective cohort of studies comprising pre- and 24-hour post-LITT 3 Tesla T1-weighted (T1w), T2w, T2-GRE, and T2-FLAIR acquisitions was considered. Our scheme involved (1) inter-protocol as well as inter-acquisition affine registration of pre- and post-LITT MRI, (2) quantitation of MRI parameters by correcting for intensity drift in order to examine tissue-specific response, and (3) quantification of MRI maps via texture and intensity features to evaluate changes in MR markers pre- and post-LITT. A total of 78 texture features comprising of non-steerable and steerable gradient and second order statistical features were extracted from pre- and post-LITT MP-MRI on a per-voxel basis. Quantitative, voxel-wise comparison of the changes in MRI texture features between pre-, and post-LITT MRI indicate that (a) steerable and non-steerable gradient texture features were highly sensitive as well as specific in predicting subtle micro-architectural changes within and around the ablation zone pre- and post-LITT, (b) FLAIR was identified as the most sensitive MRI protocol in identifying early treatment changes yielding a normalized percentage change of 360% within the ablation zone relative to its pre-LITT value, and (c) GRE was identified as the most sensitive MRI protocol in quantifying changes outside the ablation zone post-LITT. Our preliminary results thus indicate great potential for non-invasive computerized MRI features in determining localized micro-architectural focal treatment related changes post-LITT.

Proceedings Article | 29 March 2013 Paper

Identifying in vivo DCE MRI parameters correlated with ex vivo quantitative microvessel architecture: A radiohistomorphometric approach

Asha Singanamalli, Rachel Sparks, Mirabela Rusu, Natalie Shih, Amy Ziober, John Tomaszewski, Mark Rosen, Michael Feldman, Anant Madabhushi

Proceedings Volume 8676, 867604 (2013) https://doi.org/10.1117/12.2008136

KEYWORDS: Tumors, Magnetic resonance imaging, Feature extraction, Tissues, Image segmentation, Targeting Task Performance metric, In vivo imaging, Prostate cancer, Prostate, Pathology

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We introduce a novel radiohistomorphometric method for quantitative correlation and subsequent discovery of imaging markers for aggressive prostate cancer (CaP). While this approach can be employed in the context any imaging modality and disease domain, we seek to identify quantitative dynamic contrast enhanced (DCE) magnetic resonance imaging (MRI) attributes that are highly correlated with density and architecture of tumor microvessels, surrogate markers of CaP aggressiveness. This retrospective study consisted of five Gleason score matched patients who underwent 3 Tesla multiparametric MRI prior to radical prostatectomy (RP). The excised gland was sectioned and quartered with a rotary knife. For each serial section, digitized images of individual quadrants were reconstructed into pseudo whole mount sections via previously developed stitching program. The individual quadrants were stained with vascular marker CD31 and annotated for CaP by an expert pathologist. The stained microvessel regions were quantitatively characterized in terms of density and architectural arrangement via graph algorithms, yielding a series of quantitative histomorphometric features. The reconstructed pseudo whole mount histologic sections were non-linearly co-registered with DCE MRI to identify tumor extent on MRI on a voxel-by-voxel basis. Pairwise correlations between kinetic and microvessel features within CaP annotated regions on the two modalities were computed to identify highly correlated attributes. Preliminary results of the radiohistomorphometric correlation identified 8 DCE MRI kinetic features that were highly and significantly (p<0.05) correlated with a number of microvessel parameters. Most of the identified imaging features were related to rate of washout (Rwo) and initial area under the curve (IAUC). Association of those attributes with Gleason patterns showed that the identified imaging features clustered most of the tumors with primary Gleason pattern of 3 together. These results suggest that Rwo and IAUC may be promising candidate imaging markers for identification of aggressive CaP in vivo.

Proceedings Article | 29 March 2013 Paper

EM-based segmentation-driven color standardization of digitized histopathology

Ajay Basavanhally, Anant Madabhushi

Proceedings Volume 8676, 86760G (2013) https://doi.org/10.1117/12.2007173

KEYWORDS: Tissues, Image segmentation, Expectation maximization algorithms, Prostate, Calcium, RGB color model, Standards development, Image processing, Scanners, Magnetic resonance imaging

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The development of tools for the processing of color images is often complicated by nonstandardness – the notion that different image regions corresponding to the same tissue will occupy different ranges in the color spectrum. In digital pathology (DP), these issues are often caused by variations in slide thickness, staining, scanning parameters, and illumination. Nonstandardness can be addressed via standardization, a pre-processing step that aims to improve color constancy by realigning color distributions of images to match that of a predefined template image. Unlike color normalization methods, which aim to scale (usually linearly or assuming that the transfer function of the system is known) the intensity of individual images, standardization is employed to align distributions in broad tissue classes (e.g. epithelium, stroma) across different DP images irrespective of institution, protocol, or scanner. Intensity standardization has previously been used for addressing the issue of intensity drift in MRI images, where similar tissue regions have different image intensities across scanners and patients. However, this approach is a global standardization (GS) method that aligns histograms of entire images at once. By contrast, histopathological imagery is complicated by the (a) additional information present in color images and (b) heterogeneity of tissue composition. In this paper, we present a novel color Expectation Maximization (EM) based standardization (EMS) scheme to decompose histological images into independent tissue classes (e.g. nuclei, epithelium, stroma, lumen) via the EM algorithm and align the color distributions for each class independently. Experiments are performed on prostate and oropharyngeal histopathology tissues from 19 and 26 patients, respectively. Evaluation methods include (a) a segmentation-based assessment of color consistency in which normalized median intensity (NMI) is calculated from segmented regions across a dataset and (b) a quantitative measure of histogram alignment via mean landmark distance. EMS produces lower NMI standard deviations (i.e. greater consistency) of 0.0054 and 0.0034 for prostate and oropharyngeal cohorts, respectively, than unstandardized (0.034 and 0.026) and GS (0.031 and 0.017) approaches. Similarly, we see decreased mean landmark distance for EMS (2.25 and 4.20) compared to both unstandardized (54.8 and 27.3) and GS (27.1 and 8.8) images. These results suggest that the separation of broad tissue classes in EMS is vital to the standardization of DP imagery and subsequent development of computerized image analysis tools.

Proceedings Article | 29 March 2013 Paper

Cell cluster graph for prediction of biochemical recurrence in prostate cancer patients from tissue microarrays

Sahirzeeshan Ali, Robert Veltri, Jonathan Epstein, Christhunesa Christudass, Anant Madabhushi

Proceedings Volume 8676, 86760H (2013) https://doi.org/10.1117/12.2008695

KEYWORDS: Tissues, Tumors, Feature extraction, Prostate cancer, Pathology, Feature selection, Cancer, Image analysis, Prostate

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Prostate cancer (CaP) is evidenced by profound changes in the spatial distribution of cells. Spatial arrangement and architectural organization of nuclei, especially clustering of the cells, within CaP histopathology is known to be predictive of disease aggressiveness and potentially patient outcome. Quantitative histomorphometry is a relatively new field which attempt to develop and apply novel advanced computerized image analysis and feature extraction methods for the quantitative characterization of tumor morphology on digitized pathology slides. Recently, graph theory has been used to characterize the spatial arrangement of these cells by constructing a graph with cell/nuclei as the node. One disadvantage of several extant graph based algorithms (Voronoi, Delaunay, Minimum Spanning Tree) is that they do not allow for extraction of local spatial attributes from complex networks such as those that emerges from large histopathology images with potentially thousands of nuclei. In this paper, we define a cluster of cells as a node and construct a novel graph called Cell Cluster Graph (CCG) to characterize local spatial architecture. CCG is constructed by first identifying the cell clusters to use as nodes for the construction of the graph. Pairwise spatial relationship between nodes is translated into edges of the CCG, each of which are assigned certain probability, i.e. each edge between any pair of a nodes has a certain probability to exist. Spatial constraints are employed to deconstruct the entire graph into subgraphs and we then extract global and local graph based features from the CCG. We evaluated the ability of the CCG to predict 5 year biochemical failures in men with CaP and who had previously undergone radical prostatectomy. Extracted features from CCG constructed using nuclei as nodal centers on tissue microarray (TMA) images obtained from the surgical specimens of 80 patients allowed us to train a support vector machine classifier via a 3 fold randomized cross validation procedure which yielded a classification accuracy of 83:1±1:2%. By contrast the Voronoi, Delaunay, and Minimum spanning tree based graph classifiers yielded corresponding classification accuracies of 67:1±1:8% and 60:7±0:9% respectively.

Proceedings Article | 29 March 2013 Paper

Multiscale multimodal fusion of histological and MRI volumes for characterization of lung inflammation

Mirabela Rusu, Haibo Wang, Thea Golden, Andrew Gow, Anant Madabhushi

Proceedings Volume 8672, 86720X (2013) https://doi.org/10.1117/12.2007148

KEYWORDS: Magnetic resonance imaging, Lung, In vivo imaging, 3D modeling, Image registration, Pathology, Rigid registration, Data modeling, Image segmentation, Image analysis

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Proceedings Article | 15 March 2013 Paper

A statistical deformation model (SDM) based regularizer for non-rigid image registration: application to registration of multimodal prostate MRI and histology

Srivathsan Babu Prabu, Robert Toth, Anant Madabhushi

Proceedings Volume 8676, 86760C (2013) https://doi.org/10.1117/12.2008707

KEYWORDS: Image registration, Magnetic resonance imaging, Prostate, In vivo imaging, Statistical modeling, Brain, Tissues, Image segmentation, Image restoration, Computed tomography

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Proceedings Article | 15 March 2013 Paper

Quantitative evaluation of treatment related changes on multi-parametric MRI after laser interstitial thermal therapy of prostate cancer

Satish Viswanath, Robert Toth, Mirabela Rusu, Dan Sperling, Herbert Lepor, Jurgen Futterer, Anant Madabhushi

Proceedings Volume 8671, 86711F (2013) https://doi.org/10.1117/12.2008037

KEYWORDS: Magnetic resonance imaging, Prostate, Visualization, Laser therapeutics, Image registration, Diffusion weighted imaging, Prostate cancer, In vivo imaging, Tissues, Image resolution

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Laser interstitial thermal therapy (LITT) has recently shown great promise as a treatment strategy for localized, focal, low-grade, organ-confined prostate cancer (CaP). Additionally, LITT is compatible with multi-parametric magnetic resonance imaging (MP-MRI) which in turn enables (1) high resolution, accurate localization of ablation zones on in vivo MP-MRI prior to LITT, and (2) real-time monitoring of temperature changes in vivo via MR thermometry during LITT. In spite of rapidly increasing interest in the use of LITT for treating low grade, focal CaP, very little is known about treatment-related changes following LITT. There is thus a clear need for studying post-LITT changes via MP-MRI and consequently to attempt to (1) quantitatively identify MP-MRI markers predictive of favorable treatment response and longer term patient outcome, and (2) identify which MP-MRI markers are most sensitive to post-LITT changes in the prostate. In this work, we present the first attempt at examining focal treatment-related changes on a per-voxel basis (high resolution) via quantitative evaluation of MR parameters pre- and post-LITT. A retrospective cohort of MP-MRI data comprising both pre- and post- LITT T2-weighted (T2w) and diffusion-weighted (DWI) acquisitions was considered, where DWI MRI yielded an Apparent Diffusion Co-efficient (ADC) map. A spatially constrained affine registration scheme was implemented to first bring T2w and ADC images into alignment within each of the pre- and post-LITT acquisitions, following which the pre- and post-LITT acquisitions were aligned. Pre- and post-LITT MR parameters (T2w intensity, ADC value) were then standardized to a uniform scale (to correct for intensity drift) and then quantified via the raw intensity values as well as via texture features derived from T2w MRI. In order to quantify imaging changes as a result of LITT, absolute differences were calculated between the normalized pre- and post-LITT MRI parameters. Quantitatively combining the ADC and T2w MRI parameters enabled construction of an integrated MP-MRI difference map that was highly indicative of changes specific to the LITT ablation zone. Preliminary quantitative comparison of the changes in different MR parameters indicated that T2w texture may be highly sensitive as well as specific in identifying changes within the ablation zone pre- and post-LITT. Visual evaluation of the differences in T2w texture features pre- and post-LITT also appeared to provide an indication of LITT-related effects such as edema. Our preliminary results thus indicate great potential for non-invasive MP-MRI imaging markers for determining focal treatment related changes, and hence long- and short-term patient outcome.

Proceedings Article | 14 March 2013 Paper

Quantitative evaluation of multi-parametric MR imaging marker changes post-laser interstitial ablation therapy (LITT) for epilepsy

Pallavi Tiwari, Shabbar Danish, Stephen Wong, Anant Madabhushi

Proceedings Volume 8671, 86711Y (2013) https://doi.org/10.1117/12.2008157

KEYWORDS: Magnetic resonance imaging, Epilepsy, Laser therapeutics, Tumors, Laser ablation, Brain, Medicine, Dentistry, Laser energy, Neuroimaging

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Laser-induced interstitial thermal therapy (LITT) has recently emerged as a new, less invasive alternative to craniotomy for treating epilepsy; which allows for focussed delivery of laser energy monitored in real time by MRI, for precise removal of the epileptogenic foci. Despite being minimally invasive, the effects of laser ablation on the epileptogenic foci (reflected by changes in MR imaging markers post-LITT) are currently unknown. In this work, we present a quantitative framework for evaluating LITT-related changes by quantifying per-voxel changes in MR imaging markers which may be more reflective of local treatment related changes (TRC) that occur post-LITT, as compared to the standard volumetric analysis which involves monitoring a more global volume change across pre-, and post-LITT MRI. Our framework focuses on three objectives: (a) development of temporal MRI signatures that characterize TRC corresponding to patients with seizure freedom by comparing differences in MR imaging markers and monitoring them over time, (b) identification of the optimal time point when early LITT induced effects (such as edema and mass effect) subside by monitoring TRC at subsequent time-points post-LITT, and (c) identification of contributions of individual MRI protocols towards characterizing LITT-TRC for epilepsy by identifying MR markers that change most dramatically over time and employ individual contributions to create a more optimal weighted MP-MRI temporal profile that can better characterize TRC compared to any individual imaging marker. A cohort of patients were monitored at different time points post-LITT via MP-MRI involving T1-w, T2-w, T2-GRE, T2-FLAIR, and apparent diffusion coefficient (ADC) protocols. Post affine registration of individual MRI protocols to a reference MRI protocol pre-LITT, differences in individual MR markers are computed on a per-voxel basis, at different time-points with respect to baseline (pre-LITT) MRI as well as across subsequent time-points. A time-dependent MRI profile corresponding to successful (seizure-free) is then created that captures changes in individual MR imaging markers over time. Our preliminary analysis on two patient studies suggests that (a) LITT related changes (attributed to swelling and edema) appear to subside within 4-weeks post-LITT, (b) ADC may be more sensitive for evaluating early TRC (up to 3-months), and T1-w may be more sensitive in evaluating early delayed TRC (1-month, 3-months), while T2-w and T2-FLAIR appeared to be more sensitive in identifying late TRC (around 6-months post-LITT) compared to the other MRI protocols under evaluation. T2-GRE was found to be only nominally sensitive in identifying TRC at any follow-up time-point post-LITT. The framework presented in this work thus serves as an important precursor to a comprehensive treatment evaluation framework that can be used to identify sensitive MR markers corresponding to patient response (seizure-freedom or seizure recurrence), with an ultimate objective of making prognostic predictions about patient outcome post-LITT.

Proceedings Article | 13 March 2013 Paper

Mouse lung volume reconstruction from efficient groupwise registration of individual histological slices with natural gradient

Haibo Wang, Mirabela Rusu, Thea Golden, Andrew Gow, Anant Madabhushi

Proceedings Volume 8669, 866914 (2013) https://doi.org/10.1117/12.2006860

KEYWORDS: Image registration, Lung, Photonic integrated circuits, Reconstruction algorithms, Magnetic resonance imaging, Pathogens, Image restoration, Data modeling, Mouse models, Animal model studies

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Mouse lung models facilitate the study of the pathogenesis of various pulmonary diseases such as infections and inflammatory diseases. The co-registration of ex vivo histological data and pre-excised magnetic resonance imaging (MRI) in preclinical mouse models would allow for determination and validation of imaging signatures for different pathobiologies within the lung. While slice-based co-registration could be used, this approach assumes that (a) slice correspondences between the two different modalities exist, and (b) finding slice correspondences often requires the intervention of an expert and is time consuming. A more practical approach is to first reconstruct the 3D histological volume from individual slices, then perform 3D registration with the MR volume. Before the histological reconstruction, image registration is required to compensate for geometric differences between slices. Pairwise algorithms work by registering pairs of successive slices. However, even if successive slices are registered reasonably well, the propagation of registration errors over slices can yield a distorted volumetric reconstruction significantly different in shape from the shape of the true specimen. Groupwise registration can reduce the error propagation by considering more than two successive images during the registration, but existing algorithms are computationally expensive. In this paper, we present an efficient groupwise registration approach, which yields consistent volumetric reconstruction and yet runs equally fast as pairwise registration. The improvements are based on 1) natural gradient which speeds up the transform warping procedure and 2) efficient optimization of the cost function of our groupwise registration. The strength of the natural gradient technique is that it could help mitigate the impact of the uncertainties of the gradient direction across multiple template slices. Experiments on two mouse lung datasets show that compared to pairwise registration, our groupwise approach runs faster in terms of registration convergence, and yields globally more consistent reconstruction.

Proceedings Article | 13 March 2013 Paper

A novel point-based nonrigid image registration scheme based on learning optimal landmark configurations

Tao Wan, B. Nicolas Bloch, Shabbar Danish, Anant Madabhushi

Proceedings Volume 8669, 866934 (2013) https://doi.org/10.1117/12.2007153

KEYWORDS: Image registration, Brain, Neuroimaging, Magnetic resonance imaging, Tumors, Medical imaging, Brain mapping, Tissues, Computer simulations, Image processing

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Image registration plays an increasingly important role in the field of medical image processing given the plurality of images often acquired from different sensors, time points, or viewpoints. Landmark-based registration schemes represent the most popular class of registration methods due to their simplicity and high accuracy. Previous studies have shown that these registration schemes are sensitive to the number and location of landmarks. Identifying important landmarks to perform an accurate registration remains a very challenging task. Current landmark selection methods, such as feature-based approaches, focus on optimization of global transformation and may have poor performance in recovering local deformation, e.g. subtle tissue changes caused by tumor resection, making them inappropriate for registering pre- and post-surgery images as a small cancerous region will be deformed after removing a tumor. In this work, a novel method is introduced to estimate optimal landmark configurations. An important landmark configuration that will be used as a training landmark set was learned for an image pair with a known deformation. This landmark configuration can be considered as a collection of discrete points. A generic transformation matrix between a pair of training landmark sets with different deformation locations was computed via an iterative close point (ICP) alignment technique. A new landmark configuration was determined by simply transforming the training landmarks to the current displacement location while preserving the topological structure of the configuration of landmarks. Two assumptions are made: 1) In a new pair of images the deformation is approximately the same size and has only been spatially relocated in the image, and that by a simple affine transformation one can identify the optimal configuration on this new pair of images; and 2) The deformation is of similar size and shape on the original pair of images. These are reasonable assumptions in many cases where one seeks to register tumor images at multiple time points following application of therapy and to evaluate changes in tumor size. The experiments were conducted on 286 pairs of synthetic MRI brain images. The training landmark configurations were obtained through 2000 iterations of registration where the points with consistently best registration performance were selected. The estimated landmarks greatly improved the quality metrics compared to a uniform grid placement scheme and a speeded-up robust features (SURF) based method as well as a generic free-form deformation (FFD) approach. The quantitative results showed that the new landmark configuration achieved 95% improvement in recovering the local deformation compared to 89% for the uniform grid placement, 79% for the SURF-based approach, and 10% for the generic FFD approach.

Proceedings Article | 13 March 2013 Paper

Statistical 3D prostate imaging atlas construction via anatomically constrained registration

Mirabela Rusu, B. Nicolas Bloch, Carl Jaffe, Neil Rofsky, Elizabeth Genega, Ernest Feleppa, Robert Lenkinski, Anant Madabhushi

Proceedings Volume 8669, 866913 (2013) https://doi.org/10.1117/12.2006941

KEYWORDS: Magnetic resonance imaging, Prostate, Cancer, Image registration, 3D image processing, Artificial intelligence, In vivo imaging, Image segmentation, Biopsy, Stereoscopy

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Statistical imaging atlases allow for integration of information from multiple patient studies collected across different image scales and modalities, such as multi-parametric (MP) MRI and histology, providing population statistics regarding a specific pathology within a single canonical representation. Such atlases are particularly valuable in the identification and validation of meaningful imaging signatures for disease characterization in vivo within a population. Despite the high incidence of prostate cancer, an imaging atlas focused on different anatomic structures of the prostate, i.e. an anatomic atlas, has yet to be constructed. In this work we introduce a novel framework for MRI atlas construction that uses an iterative, anatomically constrained registration (AnCoR) scheme to enable the proper alignment of the prostate (Pr) and central gland (CG) boundaries. Our current implementation uses endorectal, 1.5T or 3T, T2-weighted MRI from 51 patients with biopsy confirmed cancer; however, the prostate atlas is seamlessly extensible to include additional MRI parameters. In our cohort, radical prostatectomy is performed following MP-MR image acquisition; thus ground truth annotations for prostate cancer are available from the histological specimens. Once mapped onto MP-MRI through elastic registration of histological slices to corresponding T2-w MRI slices, the annotations are utilized by the AnCoR framework to characterize the 3D statistical distribution of cancer per anatomic structure. Such distributions are useful for guiding biopsies toward regions of higher cancer likelihood and understanding imaging profiles for disease extent in vivo. We evaluate our approach via the Dice similarity coefficient (DSC) for different anatomic structures (delineated by expert radiologists): Pr, CG and peripheral zone (PZ). The AnCoR-based atlas had a CG DSC of 90.36%, and Pr DSC of 89.37%. Moreover, we evaluated the deviation of anatomic landmarks, the urethra and veromontanum, and found 3.64 mm and respectively 4.31 mm. Alternative strategies that use only the T2-w MRI or the prostate surface to drive the registration were implemented as comparative approaches. The AnCoR framework outperformed the alternative strategies by providing the lowest landmark deviations.

Proceedings Article | 8 March 2013 Paper

Fully automated prostate magnetic resonance imaging and transrectal ultrasound fusion via a probabilistic registration metric

Rachel Sparks, B. Nicholas Bloch, Ernest Feleppa, Dean Barratt, Anant Madabhushi

Proceedings Volume 8671, 86710A (2013) https://doi.org/10.1117/12.2007610

KEYWORDS: Prostate, Magnetic resonance imaging, Biopsy, Signal attenuation, Image registration, Image segmentation, Fourier transforms, Curium, Ultrasonography, Tellurium

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Proceedings Article | 26 February 2013 Paper

Iterative multiple reference tissue method for estimating pharmacokinetic parameters on prostate DCE MRI

Shoshana Ginsburg, B. Nicolas Bloch, Neil Rofsky, Elizabeth Genega, Robert Lenkinski, Anant Madabhushi

Proceedings Volume 8670, 86701J (2013) https://doi.org/10.1117/12.2007715

KEYWORDS: Magnetic resonance imaging, Tissues, Prostate, Tumors, Biological research, Arteries, Blood, Image segmentation, Image registration, Plasma

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Pharmacokinetic (PK) parameters are probes of tissue status that can be assessed by analysis of dynamic contrast-enhanced (DCE) MRI and are useful for prostate cancer (CaP) detection and grading. Traditionally, PK analysis requires knowledge of the time-resolved concentration of the contrast agent in the blood plasma, the arterial input function (AIF), which is typically estimated in an artery in the field-of-view (FOV). In cases when no suitable artery is present in the FOV, the multiple reference tissue method (MRTM) enables the estimation of PK parameters without the AIF by leveraging PK parameter values from the literature for a reference tissue in the FOV. Nevertheless, PK parameters estimated in the prostate vary significantly between patients. Consequently, population-based values obtained from the literature may introduce error into PK parameter estimation via MRTM. The objectives of this paper are two-fold. First we present a novel scheme, iterative MRTM (IMRTM), to estimate PK parameter values in the absence of the AIF without making assumptions about the PK constants associated with a reference tissue. Then, using IMRTM we investigate differences in PK constants between CaP in the peripheral zone (PZ) and CaP in the central gland (CG), as CG and PZ CaP have previously been shown to differ significantly in terms of both texture and prognosis. We apply IMRTM to 15 patients with CaP in either the CG or the PZ who were scheduled for a radical prostatectomy and a pre-operative MRI. Values for the PK parameters K^trans and v_eestimated via IMRTM average 0.29 and 0.60 for normal central gland (CG), 0.29 and 0.64 for normal peripheral zone (PZ), and 0.30 and 0.53 for CaP. It is noteworthy that PK constants estimated in PZ CaP are significantly higher than those estimated in CG CaP (p < 0:05). While both MRTM and IMRTM provide PK parameter values that are biologically feasible, IMRTM has the advantage that it invokes patient-specific information rather than relying on population-based PK constants in performing PK analysis.

Proceedings Article | 23 February 2012 Paper

Gleason grading of prostate histology utilizing manifold regularization via statistical shape model of manifolds

Rachel Sparks, Anant Madabhushi

Proceedings Volume 8315, 83151J (2012) https://doi.org/10.1117/12.912887

KEYWORDS: Prostate, Statistical modeling, Tissues, Biopsy, Prostate cancer, Visualization, Image classification, Computing systems, Decision support systems, Image segmentation

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Gleason patterns of prostate cancer histopathology, characterized primarily by morphological and architectural attributes of histological structures (glands and nuclei), have been found to be highly correlated with disease aggressiveness and patient outcome. Gleason patterns 4 and 5 are highly correlated with more aggressive disease and poorer patient outcome, while Gleason patterns 1-3 tend to reflect more favorable patient outcome. Because Gleason grading is done manually by a pathologist visually examining glass (or digital) slides, subtle morphologic and architectural differences of histological attributes may result in grading errors and hence cause high inter-observer variability. Recently some researchers have proposed computerized decision support systems to automatically grade Gleason patterns by using features pertaining to nuclear architecture, gland morphology, as well as tissue texture. Automated characterization of gland morphology has been shown to distinguish between intermediate Gleason patterns 3 and 4 with high accuracy. Manifold learning (ML) schemes attempt to generate a low dimensional manifold representation of a higher dimensional feature space while simultaneously preserving nonlinear relationships between object instances. Classification can then be performed in the low dimensional space with high accuracy. However ML is sensitive to the samples contained in the dataset; changes in the dataset may alter the manifold structure. In this paper we present a manifold regularization technique to constrain the low dimensional manifold to a specific range of possible manifold shapes, the range being determined via a statistical shape model of manifolds (SSMM). In this work we demonstrate applications of the SSMM in (1) identifying samples on the manifold which contain noise, defined as those samples which deviate from the SSMM, and (2) accurate out-of-sample extrapolation (OSE) of newly acquired samples onto a manifold constrained by the SSMM. We demonstrate these applications of the SSMM in the context of distinguishing between Gleason patterns 3 and 4 using glandular morphologic features in a prostate histopathology dataset of 58 patient studies. Identifying and eliminating noisy samples from the manifold via the SSMM results in a statistically significant improvement in classification accuracy (CA), 93.0 ± 1.0% with removal of noisy samples compared to a CA of 90.9 ± 1.1% without removal of samples. The use of the SSMM for OSE of new independent test instances also shows statistically significant improvement in CA, 87.1±0.8% with the SSMM compared to 85.6±0.1% without the SSMM. Similar improvements were observed for the synthetic Swiss Roll and Helix datasets.

Proceedings Article | 23 February 2012 Paper

Incorporating the whole-mount prostate histology reconstruction program Histostitcher into the extensible imaging platform (XIP) framework

Robert Toth, Jonathan Chappelow, Christoph Vetter, Oliver Kutter, Christoph Russ, Michael Feldman, John Tomaszewski, Natalie Shih, Anant Madabhushi

Proceedings Volume 8315, 83151K (2012) https://doi.org/10.1117/12.912938

KEYWORDS: Visualization, Magnetic resonance imaging, Human-machine interfaces, In vivo imaging, MATLAB, Prostate, Reconstruction algorithms, Computer aided diagnosis and therapy, Prostate cancer, Medical imaging

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There is a need for identifying quantitative imaging (e.g. MRI) signatures for prostate cancer (CaP), so that computer-aided diagnostic methods can be trained to detect disease extent in vivo. Determining CaP extent on in vivo MRI is difficult to do; however, with the availability of ex vivo surgical whole mount histological sections (WMHS) for CaP patients undergoing radical prostatectomy, co-registration methods can be applied to align and map disease extent onto pre-operative MR imaging from the post-operative histology. Yet obtaining digitized images of WHMS for co-registration with the pre-operative MRI is cumbersome since (a) most digital slide scanners are unable to accommodate the entire section, and (b) significant technical expertise is required for whole mount slide preparation. Consequently, most centers opt to construct quartered sections of each histology slice. Prior to co-registration with MRI, however, these quartered sections need to be digitally stitched together to reconstitute a digital, pseudo WMHS. Histostitcher© is an interactive software program that uses semi-automatic registration tools to digitally stitch quartered sections into pseudo WMHS. Histostitcher© was originally developed using the GUI tools provided by the Matlab programming interface, but the clinical use was limited due to the inefficiency of the interface. The limitations of the Matlab based GUI include (a) an inability to edit the fiducials, (b) the rendering being extremely slow, and (c) lack of interactive and rapid visualization tools. In this work, Histostitcher© has been integrated into the eXtensible Imaging Platform (XIP ^TM ) framework (a set of libraries containing functionalities for analyzing and visualizing medical image data). XIP ^TM lends the stitching tool much greater flexibility and functionality by (a) allowing interactive and seamless navigation through the full resolution histology images, (b) the ability to easily add, edit, or remove fiducials and annotations in order to register the quadrants and map the disease extent. In this work, we showcase examples of digital stitching of quartered histological sections into pseudo-WHMS using Histostitcher © via the new XIP ^TM interface. This tool will be particularly useful in clinical trials and large cohort studies where a quick, interactive way of digitally reconstructing pseudo WMHS is required.

Proceedings Article | 16 March 2011 Paper

Empirical evaluation of bias field correction algorithms for computer-aided detection of prostate cancer on T2w MRI

Satish Viswanath, Daniel Palumbo, Jonathan Chappelow, Pratik Patel, B. Nicholas Bloch, Neil Rofsky, Robert Lenkinski, Elizabeth Genega, Anant Madabhushi

Proceedings Volume 7963, 79630V (2011) https://doi.org/10.1117/12.878813

KEYWORDS: Magnetic resonance imaging, Prostate, Computer aided diagnosis and therapy, Prostate cancer, Detection and tracking algorithms, Image segmentation, In vivo imaging, Tissues, Linear filtering

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In magnetic resonance imaging (MRI), intensity inhomogeneity refers to an acquisition artifact which introduces a non-linear variation in the signal intensities within the image. Intensity inhomogeneity is known to significantly affect computerized analysis of MRI data (such as automated segmentation or classification procedures), hence requiring the application of bias field correction (BFC) algorithms to account for this artifact. Quantitative evaluation of BFC schemes is typically performed using generalized intensity-based measures (percent coefficient of variation, %CV ) or information-theoretic measures (entropy). While some investigators have previously empirically compared BFC schemes in the context of different domains (using changes in %CV and entropy to quantify improvements), no consensus has emerged as to the best BFC scheme for any given application. The motivation for this work is that the choice of a BFC scheme for a given application should be dictated by application-specific measures rather than ad hoc measures such as entropy and %CV. In this paper, we have attempted to address the problem of determining an optimal BFC algorithm in the context of a computer-aided diagnosis (CAD) scheme for prostate cancer (CaP) detection from T2-weighted (T2w) MRI. One goal of this work is to identify a BFC algorithm that will maximize the CaP classification accuracy (measured in terms of the area under the ROC curve or AUC). A secondary aim of our work is to determine whether measures such as %CV and entropy are correlated with a classifier-based objective measure (AUC). Determining the presence or absence of these correlations is important to understand whether domain independent BFC performance measures such as %CV , entropy should be used to identify the optimal BFC scheme for any given application. In order to answer these questions, we quantitatively compared 3 different popular BFC algorithms on a cohort of 10 clinical 3 Tesla prostate T2w MRI datasets (comprising 39 2D MRI slices): N3 , PABIC, and the method of Cohen et al. Results of BFC via each of the algorithms was evaluated in terms of %CV , entropy, as well as classifier AUC for CaP detection from T2w MRI. The CaP classifier was trained and evaluated on a per-pixel basis using annotations of CaP obtained via registration of T2w MRI and ex vivo whole-mount histology sections. Our results revealed that different BFC schemes resulted in a maximization of different performance measures, that is, the BFC scheme identified by minimization of %CV and entropy was not the one that maximized AUC as well. Moreover, existing BFC evaluation measures (%CV , entropy) did not correlate with AUC (application-based evaluation), but did correlate with each other, suggesting that domain-specific performance measures should be considered in making a decision regarding choice of appropriate BFC scheme. Our results also revealed that N3 provided the best correction of bias field artifacts in prostate MRI data, when the goal was to identify prostate cancer.

Proceedings Article | 16 March 2011 Paper

Linked statistical shape models for multi-modal segmentation of the prostate on MRI-CT for radiotherapy planning

Najeeb Chowdhury, Jonathan Chappelow, Robert Toth, Sung Kim, Stephen Hahn, Neha Vapiwala, Haibo Lin, Stefan Both, Anant Madabhushi

Proceedings Volume 7963, 796314 (2011) https://doi.org/10.1117/12.878416

KEYWORDS: Prostate, Magnetic resonance imaging, Computed tomography, Image segmentation, Image registration, Diagnostics, Radiotherapy, Printed circuit board testing, Statistical modeling, Principal component analysis

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We present a novel framework for building a linked statistical shape model (LSSM), a statistical shape model (SSM) that links the shape variation of a structure of interest (SOI) across multiple imaging modalities. This framework is particularly relevant in scenarios where accurate delineations of a SOI's boundary on one of the modalities may not be readily available, or difficult to obtain, for training a SSM. We apply the LSSM in the context of multi-modal prostate segmentation for radiotherapy planning, where we segment the prostate on MRI and CT simultaneously. Prostate capsule segmentation is a critical step in prostate radiotherapy planning, where dose plans have to be formulated on CT. Since accurate delineations of the prostate boundary are very difficult to obtain on CT, pre-treatment MRI is now beginning to be acquired at several medical centers. Delineation of the prostate on MRI is acknowledged as being significantly simpler to do compared to CT. Hence, our framework incorporates multi-modal registration of MRI and CT to map 2D boundary delineations of prostate (obtained from an expert radiation oncologist) on MR training images onto corresponding CT images. The delineations of the prostate capsule on MRI and CT allows for 3D reconstruction of the prostate shape which facilitates the building of the LSSM. We acquired 7 MRI-CT patient studies and used the leave-one-out strategy to train and evaluate our LSSM (fLSSM), built using expert ground truth delineations on MRI and MRI-CT fusion derived capsule delineations on CT. A unique attribute of our fLSSM is that it does not require expert delineations of the capsule on CT. In order to perform prostate MRI segmentation using the fLSSM, we employed a regionbased approach where we deformed the evolving prostate boundary to optimize a mutual information based cost criterion, which took into account region-based intensity statistics of the image being segmented. The final prostate segmentation was then transferred onto the CT image using the LSSM. We compared our fLSSM against another LSSM (xLSSM), where, unlike the fLSSM, expert delineations of the capsule on both MRI and CT were employed in the model building; xLSSM representing the idealized LSSM. We also compared our fLSSM against an exclusive CT-based SSM (ctSSM), built from expert delineations of capsule on CT only. Due to the intensity-driven nature of the segmentation algorithm, the ctSSM was not able segment the prostate. On MRI, the xLSSM and fLSSM yielded almost identical results. On CT, our results suggest that the fLSSM, while not dependent on highly accurate delineations of the capsule on CT, yields comparable results to an idealized LSSM scheme (xLSSM). Hence, the fLSSM provides an accurate alternative to SSMs that require careful SOI delineations that may be difficult or laborious to obtain, while providing concurrent segmentations of the capsule on multiple modalities.

Proceedings Article | 16 March 2011 Paper

Spectral embedding based active contour (SEAC): application to breast lesion segmentation on DCE-MRI

Shannon Agner, Jun Xu, Mark Rosen, Sudha Karthigeyan, Sarah Englander, Anant Madabhushi

Proceedings Volume 7963, 796305 (2011) https://doi.org/10.1117/12.878218

KEYWORDS: Image segmentation, Breast, Magnetic resonance imaging, Feature extraction, Medical imaging, Image filtering, Data modeling, Yield improvement, Tumor growth modeling, Fuzzy logic

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Proceedings Article | 14 March 2011 Paper

Segmenting multiple overlapping objects via a hybrid active contour model incorporating shape priors: applications to digital pathology

Sahirzeeshan Ali, Anant Madabhushi

Proceedings Volume 7962, 79622W (2011) https://doi.org/10.1117/12.878425

KEYWORDS: Image segmentation, Performance modeling, Tumor growth modeling, Statistical modeling, Prostate, Data modeling, Visual process modeling, Principal component analysis, Breast, Breast cancer

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Proceedings Article | 14 March 2011 Paper

Integrating an adaptive region-based appearance model with a landmark-free statistical shape model: application to prostate MRI segmentation

Robert Toth, Julie Bulman, Amish Patel, B. Nicholas Bloch, Elizabeth Genega, Neil Rofsky, Robert Lenkinski, Anant Madabhushi

Proceedings Volume 7962, 79622V (2011) https://doi.org/10.1117/12.878346

KEYWORDS: Prostate, Image segmentation, Statistical modeling, Magnetic resonance imaging, 3D modeling, 3D image processing, Systems modeling, Principal component analysis, Medical imaging, Statistical analysis

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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 | 11 March 2011 Paper

Content-based image retrieval utilizing explicit shape descriptors: applications to breast MRI and prostate histopathology

Rachel Sparks, Anant Madabhushi

Proceedings Volume 7962, 79621I (2011) https://doi.org/10.1117/12.878428

KEYWORDS: Image retrieval, Breast, Prostate, Medical imaging, Model-based design, Chemical species, Shape analysis, Databases, Image registration, Diagnostics

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Content-based image retrieval (CBIR) systems, in the context of medical image analysis, allow for a user to compare a query image to previously archived database images in terms of diagnostic and/or prognostic similarity. CBIR systems can therefore serve as a powerful computerized decision support tool for clinical diagnostics and also serve as a useful learning tool for medical students, residents, and fellows. An accurate CBIR system relies on two components, (1) image descriptors which are related to a previously defined notion of image similarity and (2) quantification of image descriptors in order to accurately characterize and capture the a priori defined image similarity measure. In many medical applications, the morphology of an object of interest (e.g. breast lesions on DCE-MRI or glands on prostate histopathology) may provide important diagnostic and prognostic information regarding the disease being investigated. Morphological attributes can be broadly categorized as being (a) model-based (MBD) or (b) non-model based (NMBD). Most computerized decision support tools leverage morphological descriptors (e.g. area, contour variation, and compactness) which belong to the latter category in that they do not explicitly model morphology for the object of interest. Conversely, descriptors such as Fourier descriptors (FDs) explicitly model the object of interest. In this paper, we present a CBIR system that leverages a novel set of MBD called Explicit Shape Descriptors (ESDs) which accurately describe the similarity between the morphology of objects of interest. ESDs are computed by: (a) fitting shape models to objects of interest, (b) pairwise comparison between shape models, and (c) a nonlinear dimensionality reduction scheme to extract a concise set of morphological descriptors in a reduced dimensional embedding space. We utilized our ESDs in the context of CBIR in three datasets: (1) the synthetic MPEG-7 Set B containing 1400 silhouette images, (2) DCE-MRI of 91 breast lesions, (3) and digitized prostate histopathology dataset comprised of 888 glands. For each dataset, each image was sequentially selected as a query image and the remaining images in the database were ranked according to how similar they were to the query image based on the ESDs. From this ranking, area under the precision-recall curve (AUPRC) was calculated and averaged over all possible query images, for each of the three datasets. For the MPEG-7 dataset bull's eye accuracy for our CBIR system is 78.65%, comparable to several state of the art shape modeling approaches. For the breast DCE-MRI dataset, ESDs outperforms a set of NMBDs with an AUPRC of 0.55 ± 0.02. For the prostate histopathology dataset, ESDs and FDs perform equivalently with an AUPRC of 0.40 ± .01, but outperform NMBDs.

Proceedings Article | 4 March 2011 Paper

Incorporating domain knowledge for tubule detection in breast histopathology using O'Callaghan neighborhoods

Ajay Basavanhally, Elaine Yu, Jun Xu, Shridar Ganesan, Michael Feldman, John Tomaszewski, Anant Madabhushi

Proceedings Volume 7963, 796310 (2011) https://doi.org/10.1117/12.878092

KEYWORDS: Cancer, Spatial analysis, Image segmentation, RGB color model, Feature extraction, Deconvolution, Breast cancer, Tissues, Breast, Data modeling

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An important criterion for identifying complicated objects with multiple attributes is the use of domain knowledge which reflects the precise spatial linking of the constituent attributes. Hence, simply detecting the presence of the low-level attributes that constitute the object, even in cases where these attributes might be detected in spatial proximity to each other is usually not a robust strategy. The O'Callaghan neighborhood is an ideal vehicle for characterizing objects comprised of multiple attributes spatially connected to each other in a precise fashion because it allows for modeling and imposing spatial distance and directional constraints on the object attributes. In this work we apply the O'Callaghan neighborhood to the problem of tubule identification on hematoxylin and eosin (H & E) stained breast cancer (BCa) histopathology, where a tubule is characterized by a central lumen surrounded by cytoplasm and a ring of nuclei around the cytoplasm. The detection of tubules is important because tubular density is an important predictor in cancer grade determination. In the context of ER+ BCa, grade has been shown to be strongly linked to disease aggressiveness and patient outcome. The more standard pattern recognition approaches to detection of complex objects typically involve training classifiers for low-level attributes individually. For tubule detection, the spatial proximity of lumen, cytoplasm, and nuclei might suggest the presence of a tubule. However such an approach could also suffer from false positive errors due to the presence of fat, stroma, and other lumen-like areas that could be mistaken for tubules. In this work, tubules are identified by imposing spatial and distance constraints using O'Callaghan neighborhoods between the ring of nuclei around each lumen. In this work, cancer nuclei in each image are found via a color deconvolution scheme, which isolates the hematoxylin stain, thereby enabling automated detection of individual cell nuclei. The potential lumen areas are segmented using a Hierarchical Normalized Cut (HNCut) initialized Color Gradient based Active Contour model (CGAC). The HNCut algorithm detects lumen-like areas within the image via pixel clustering across multiple image resolutions. The pixel clustering provides initial contours for the CGAC. From the initial contours, the CGAC evolves to segment the boundaries of the potential lumen areas. A set of 22 graph-based image features characterizing the spatial linking between the tubular attributes is extracted from the O'Callaghan neighborhood in order to distinguish true from false lumens. Evaluation on 1226 potential lumen areas from 14 patient studies produces an area under the receiver operating characteristic curve (AUC) of 0.91 along with the ability to classify true lumen with 86% accuracy. In comparison to manual grading of tubular density over 105 images, our method is able to distinguish histopathology images with low and high tubular density at 89% accuracy (AUC = 0.94).

Proceedings Article | 4 March 2011 Paper

Enhanced multi-protocol analysis via intelligent supervised embedding (EMPrAvISE): detecting prostate cancer on multi-parametric MRI

Satish Viswanath, B. Nicholas Bloch, Jonathan Chappelow, Pratik Patel, Neil Rofsky, Robert Lenkinski, Elizabeth Genega, Anant Madabhushi

Proceedings Volume 7963, 79630U (2011) https://doi.org/10.1117/12.878312

KEYWORDS: Radon, Magnetic resonance imaging, Diffusion weighted imaging, Data fusion, Magnetorheological finishing, Prostate cancer, Image registration, In vivo imaging, Feature extraction, Fermium

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Currently, there is significant interest in developing methods for quantitative integration of multi-parametric (structural, functional) imaging data with the objective of building automated meta-classifiers to improve disease detection, diagnosis, and prognosis. Such techniques are required to address the differences in dimensionalities and scales of individual protocols, while deriving an integrated multi-parametric data representation which best captures all disease-pertinent information available. In this paper, we present a scheme called Enhanced Multi-Protocol Analysis via Intelligent Supervised Embedding (EMPrAvISE); a powerful, generalizable framework applicable to a variety of domains for multi-parametric data representation and fusion. Our scheme utilizes an ensemble of embeddings (via dimensionality reduction, DR); thereby exploiting the variance amongst multiple uncorrelated embeddings in a manner similar to ensemble classifier schemes (e.g. Bagging, Boosting). We apply this framework to the problem of prostate cancer (CaP) detection on 12 3 Tesla pre-operative in vivo multi-parametric (T2-weighted, Dynamic Contrast Enhanced, and Diffusion-weighted) magnetic resonance imaging (MRI) studies, in turn comprising a total of 39 2D planar MR images. We first align the different imaging protocols via automated image registration, followed by quantification of image attributes from individual protocols. Multiple embeddings are generated from the resultant high-dimensional feature space which are then combined intelligently to yield a single stable solution. Our scheme is employed in conjunction with graph embedding (for DR) and probabilistic boosting trees (PBTs) to detect CaP on multi-parametric MRI. Finally, a probabilistic pairwise Markov Random Field algorithm is used to apply spatial constraints to the result of the PBT classifier, yielding a per-voxel classification of CaP presence. Per-voxel evaluation of detection results against ground truth for CaP extent on MRI (obtained by spatially registering pre-operative MRI with available whole-mount histological specimens) reveals that EMPrAvISE yields a statistically significant improvement (AUC=0.77) over classifiers constructed from individual protocols (AUC=0.62, 0.62, 0.65, for T2w, DCE, DWI respectively) as well as one trained using multi-parametric feature concatenation (AUC=0.67).

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.

Proceedings Article | 13 March 2010 Paper

A structural-functional MRI-based disease atlas: application to computer-aided-diagnosis of prostate cancer

G. Xiao, B. Bloch, J. Chappelow, E. Genega, N. Rofsky, R. Lenkinski, A. Madabhushi

Proceedings Volume 7623, 762303 (2010) https://doi.org/10.1117/12.845554

KEYWORDS: Magnetic resonance imaging, Image registration, Cancer, Prostate cancer, Prostate, Feature extraction, Computer aided diagnosis and therapy, Medical imaging, Biopsy, In vivo imaging

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Different imaging modalities or protocols of a single patient may convey different types of information regarding a disease for the same anatomical organ/tissue. On the other hand, multi-modal/multi-protocol medical images from several different patients can also provide spatial statistics of the disease occurrence, which in turn can greatly aid in disease diagnosis and aid in improved, accurate biopsy and targeted treatment. It is therefore important to not only integrate medical images from multiple patients into a common coordinate frame (in the form of a population-based atlas), but also find the correlation between these multi-modal/multi-protocol data features and the disease spatial distribution in order to identify different quantitative structural and functional disease signatures. Most previous work on construction of anatomical atlases has focused on deriving a population-based atlas for the purpose of deriving the spatial statistics. Moreover, these models are typically derived from normal or healthy subjects, either explicitly or implicitly, where it is assumed that the inter-patient pathological variation is not large. These methods are not suitable for constructing a disease atlas, where significant differences between patients on account of disease related variations can be expected. In this paper, we present a novel framework for the construction of a multi-parametric MRI-based data-driven disease atlas consisting of multi-modal and multi-protocol data from across multiple patient studies. Our disease atlas contains 3 Tesla structural (T2) and functional (dynamic contrast enhanced (DCE)) prostate in vivo MRI with corresponding whole mount histology specimens obtained via radical prostatectomy. Our atlas construction framework comprises 3 distinct modules: (a) determination of disease spatial extent on the multi-protocol MR imagery for each patient, (b) construction of a multi-protocol MR imaging spatial atlas which captures the geographical proclivity of the disease, and (c) feature extraction and the construction of the data-driven multi-protocol MRI based prostate cancer atlas. The marriage of data driven and spatial atlases could serve as a useful tool for clinicians to identifying structural and functional imaging disease signatures so as to make better, more informed diagnoses. Each spatial location in this atlas can be associated with a high dimensional multi-attribute quantitative feature vector. Additionally, since the feature vectors are extracted from across multiple patient studies, each spatial location in the data-driven atlas can be characterized by a feature distribution (in turn characterized by a mean and standard deviation). Preliminary investigation in quantitatively correlating the disease signatures from across the spatial and data driven atlases suggests that our quantitative atlas framework could emerge as a powerful tool for discovering prostate cancer imaging signatures.

Proceedings Article | 27 February 2010 Paper

Computer-assisted targeted therapy (CATT) for prostate radiotherapy planning by fusion of CT and MRI

Jonathan Chappelow, Stefan Both, Satish Viswanath, Stephen Hahn, Michael Feldman, Mark Rosen, John Tomaszewski, Neha Vapiwala, Pratik Patel, Anant Madabhushi

Proceedings Volume 7625, 76252C (2010) https://doi.org/10.1117/12.844653

KEYWORDS: Magnetic resonance imaging, Prostate, Diagnostics, Computed tomography, Cancer, Image registration, Tumors, Radiotherapy, Printed circuit board testing, Computer aided diagnosis and therapy

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Proceedings Article | 27 March 2009 Paper

WERITAS: weighted ensemble of regional image textures for ASM segmentation

Robert Toth, Scott Doyle, Mark Rosen, Arjun Kalyanpur, Sona Pungavkar, B. Nicolas Bloch, Elizabeth Genega, Neil Rofsky, Robert Lenkinski, Anant Madabhushi

Proceedings Volume 7259, 725905 (2009) https://doi.org/10.1117/12.812473

KEYWORDS: Image segmentation, Mahalanobis distance, Prostate, Magnetic resonance imaging, Systems modeling, Breast, Image resolution, In vivo imaging, Feature extraction, Feature selection

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Proceedings Article | 27 March 2009 Paper

Probabilistic pairwise Markov models: application to prostate cancer detection

James Monaco, John Tomaszewski, Michael Feldman, Mehdi Moradi, Parvin Mousavi, Alexander Boag, Chris Davidson, Purang Abolmaesumi, Anant Madabhushi

Proceedings Volume 7259, 725903 (2009) https://doi.org/10.1117/12.812462

KEYWORDS: Image segmentation, Solid modeling, Tumor growth modeling, CAD systems, Computer aided design, Magnetorheological finishing, Prostate, Prostate cancer, Computer aided diagnosis and therapy, Chromium

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Proceedings Article | 27 March 2009 Paper

COLLINARUS: collection of image-derived non-linear attributes for registration using splines

Jonathan Chappelow, B. Nicolas Bloch, Neil Rofsky, Elizabeth Genega, Robert Lenkinski, William DeWolf, Satish Viswanath, Anant Madabhushi

Proceedings Volume 7259, 72592N (2009) https://doi.org/10.1117/12.812352

KEYWORDS: Image registration, Magnetic resonance imaging, Cancer, Prostate, In vivo imaging, Brain, Rigid registration, Neuroimaging, Image processing, Image fusion

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We present a new method for fully automatic non-rigid registration of multimodal imagery, including structural and functional data, that utilizes multiple texutral feature images to drive an automated spline based non-linear image registration procedure. Multimodal image registration is significantly more complicated than registration of images from the same modality or protocol on account of difficulty in quantifying similarity between different structural and functional information, and also due to possible physical deformations resulting from the data acquisition process. The COFEMI technique for feature ensemble selection and combination has been previously demonstrated to improve rigid registration performance over intensity-based MI for images of dissimilar modalities with visible intensity artifacts. Hence, we present here the natural extension of feature ensembles for driving automated non-rigid image registration in our new technique termed Collection of Image-derived Non-linear Attributes for Registration Using Splines (COLLINARUS). Qualitative and quantitative evaluation of the COLLINARUS scheme is performed on several sets of real multimodal prostate images and synthetic multiprotocol brain images. Multimodal (histology and MRI) prostate image registration is performed for 6 clinical data sets comprising a total of 21 groups of in vivo structural (T2-w) MRI, functional dynamic contrast enhanced (DCE) MRI, and ex vivo WMH images with cancer present. Our method determines a non-linear transformation to align WMH with the high resolution in vivo T2-w MRI, followed by mapping of the histopathologic cancer extent onto the T2-w MRI. The cancer extent is then mapped from T2-w MRI onto DCE-MRI using the combined non-rigid and affine transformations determined by the registration. Evaluation of prostate registration is performed by comparison with the 3 time point (3TP) representation of functional DCE data, which provides an independent estimate of cancer extent. The set of synthetic multiprotocol images, acquired from the BrainWeb Simulated Brain Database, comprises 11 pairs of T1-w and proton density (PD) MRI of the brain. Following the application of a known warping to misalign the images, non-rigid registration was then performed to recover the original, correct alignment of each image pair. Quantitative evaluation of brain registration was performed by direct comparison of (1) the recovered deformation field to the applied field and (2) the original undeformed and recovered PD MRI. For each of the data sets, COLLINARUS is compared with the MI-driven counterpart of the B-spline technique. In each of the quantitative experiments, registration accuracy was found to be significantly (p < 0.05) for COLLINARUS compared with MI-driven B-spline registration. Over 11 slices, the mean absolute error in the deformation field recovered by COLLINARUS was found to be 0.8830 mm.

Proceedings Article | 3 March 2009 Paper

A boosted distance metric: application to content based image retrieval and classification of digitized histopathology

Jay Naik, Scott Doyle, Ajay Basavanhally, Shridar Ganesan, Michael Feldman, John Tomaszewski, Anant Madabhushi

Proceedings Volume 7260, 72603F (2009) https://doi.org/10.1117/12.813931

KEYWORDS: Tissues, Databases, Feature extraction, Breast, Image classification, Cancer, Image retrieval, Breast cancer, Content based image retrieval, Lithium

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Distance metrics are often used as a way to compare the similarity of two objects, each represented by a set of features in high-dimensional space. The Euclidean metric is a popular distance metric, employed for a variety of applications. Non-Euclidean distance metrics have also been proposed, and the choice of distance metric for any specific application or domain is a non-trivial task. Furthermore, most distance metrics treat each dimension or object feature as having the same relative importance in determining object similarity. In many applications, such as in Content-Based Image Retrieval (CBIR), where images are quantified and then compared according to their image content, it may be beneficial to utilize a similarity metric where features are weighted according to their ability to distinguish between object classes. In the CBIR paradigm, every image is represented as a vector of quantitative feature values derived from the image content, and a similarity measure is applied to determine which of the database images is most similar to the query. In this work, we present a boosted distance metric (BDM), where individual features are weighted according to their discriminatory power, and compare the performance of this metric to 9 other traditional distance metrics in a CBIR system for digital histopathology. We apply our system to three different breast tissue histology cohorts - (1) 54 breast histology studies corresponding to benign and cancerous images, (2) 36 breast cancer studies corresponding to low and high Bloom-Richardson (BR) grades, and (3) 41 breast cancer studies with high and low levels of lymphocytic infiltration. Over all 3 data cohorts, the BDM performs better compared to 9 traditional metrics, with a greater area under the precision-recall curve. In addition, we performed SVM classification using the BDM along with the traditional metrics, and found that the boosted metric achieves a higher classification accuracy (over 96%) in distinguishing between the tissue classes in each of 3 data cohorts considered. The 10 different similarity metrics were also used to generate similarity matrices between all samples in each of the 3 cohorts. For each cohort, each of the 10 similarity matrices were subjected to normalized cuts, resulting in a reduced dimensional representation of the data samples. The BDM resulted in the best discrimination between tissue classes in the reduced embedding space.

Proceedings Article | 28 February 2009 Paper

Integrating structural and functional imaging for computer assisted detection of prostate cancer on multi-protocol in vivo 3 Tesla MRI

Satish Viswanath, B. Nicolas Bloch, Mark Rosen, Jonathan Chappelow, Robert Toth, Neil Rofsky, Robert Lenkinski, Elizabeth Genega, Arjun Kalyanpur, Anant Madabhushi

Proceedings Volume 7260, 72603I (2009) https://doi.org/10.1117/12.811899

KEYWORDS: Magnetic resonance imaging, Prostate, Image segmentation, Image registration, In vivo imaging, Data fusion, Prostate cancer, Computer aided diagnosis and therapy, Data integration, Binary data

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Screening and detection of prostate cancer (CaP) currently lacks an image-based protocol which is reflected in the high false negative rates currently associated with blinded sextant biopsies. Multi-protocol magnetic resonance imaging (MRI) offers high resolution functional and structural data about internal body structures (such as the prostate). In this paper we present a novel comprehensive computer-aided scheme for CaP detection from high resolution in vivo multi-protocol MRI by integrating functional and structural information obtained via dynamic-contrast enhanced (DCE) and T2-weighted (T2-w) MRI, respectively. Our scheme is fully-automated and comprises (a) prostate segmentation, (b) multimodal image registration, and (c) data representation and multi-classifier modules for information fusion. Following prostate boundary segmentation via an improved active shape model, the DCE/T2-w protocols and the T2-w/ex vivo histological prostatectomy specimens are brought into alignment via a deformable, multi-attribute registration scheme. T2-w/histology alignment allows for the mapping of true CaP extent onto the in vivo MRI, which is used for training and evaluation of a multi-protocol MRI CaP classifier. The meta-classifier used is a random forest constructed by bagging multiple decision tree classifiers, each trained individually on T2-w structural, textural and DCE functional attributes. 3-fold classifier cross validation was performed using a set of 18 images derived from 6 patient datasets on a per-pixel basis. Our results show that the results of CaP detection obtained from integration of T2-w structural textural data and DCE functional data (area under the ROC curve of 0.815) significantly outperforms detection based on either of the individual modalities (0.704 (T2-w) and 0.682 (DCE)). It was also found that a meta-classifier trained directly on integrated T2-w and DCE data (data-level integration) significantly outperformed a decision-level meta-classifier, constructed by combining the classifier outputs from the individual T2-w and DCE channels.

Proceedings Article | 17 March 2008 Paper

A consensus embedding approach for segmentation of high resolution in vivo prostate magnetic resonance imagery

Satish Viswanath, Mark Rosen, Anant Madabhushi

Proceedings Volume 6915, 69150U (2008) https://doi.org/10.1117/12.770868

KEYWORDS: Magnetic resonance imaging, Cancer, Prostate, In vivo imaging, Image segmentation, Image resolution, Feature extraction, Spatial resolution, Magnetism, Ultrasonography

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Current techniques for localization of prostatic adenocarcinoma (CaP) via blinded trans-rectal ultrasound biopsy are associated with a high false negative detection rate. While high resolution endorectal in vivo Magnetic Resonance (MR) prostate imaging has been shown to have improved contrast and resolution for CaP detection over ultrasound, similarity in intensity characteristics between benign and cancerous regions on MR images contribute to a high false positive detection rate. In this paper, we present a novel unsupervised segmentation method that employs manifold learning via consensus schemes for detection of cancerous regions from high resolution 1.5 Tesla (T) endorectal in vivo prostate MRI. A significant contribution of this paper is a method to combine multiple weak, lower-dimensional representations of high dimensional feature data in a way analogous to classifier ensemble schemes, and hence create a stable and accurate reduced dimensional representation. After correcting for MR image intensity artifacts, such as bias field inhomogeneity and intensity non-standardness, our algorithm extracts over 350 3D texture features at every spatial location in the MR scene at multiple scales and orientations. Non-linear dimensionality reduction schemes such as Locally Linear Embedding (LLE) and Graph Embedding (GE) are employed to create multiple low dimensional data representations of this high dimensional texture feature space. Our novel consensus embedding method is used to average object adjacencies from within the multiple low dimensional projections so that class relationships are preserved. Unsupervised consensus clustering is then used to partition the objects in this consensus embedding space into distinct classes. Quantitative evaluation on 18 1.5 T prostate MR data against corresponding histology obtained from the multi-site ACRIN trials show a sensitivity of 92.65% and a specificity of 82.06%, which suggests that our method is successfully able to detect suspicious regions in the prostate.

Proceedings Article | 17 March 2008 Paper

Novel kinetic texture features for breast lesion classification on dynamic contrast enhanced (DCE) MRI

Shannon Agner, Salil Soman, Edward Libfeld, Margie McDonald, Mark Rosen, Mitchell Schnall, Deanna Chin, John Nosher, Anant Madabhushi

Proceedings Volume 6915, 69152C (2008) https://doi.org/10.1117/12.770920

KEYWORDS: Magnetic resonance imaging, Breast, Image classification, Breast cancer, Principal component analysis, Computer aided diagnosis and therapy, Mammography, Cancer, Image segmentation, Tissues

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Dynamic contrast enhanced (DCE) MRI has emerged as a promising new imaging modality for breast cancer screening. Currently, radiologists evaluate breast lesions based on qualitative description of lesion morphology and contrast uptake profiles. However, the subjectivity associated with qualitative description of breast lesions on DCE-MRI introduces a high degree of inter-observer variability. In addition, the high sensitivity of MRI results in poor specificity and thus a high rate of biopsies on benign lesions. Computer aided diagnosis (CAD) methods have been previously proposed for breast MRI, but research in the field is far from comprehensive. Most previous work has focused on either quantifying morphological attributes used by radiologists, characterizing lesion intensity profiles which reflect uptake of contrast dye, or characterizing lesion texture. While there has been much debate on the relative importance of the different classes of features (e.g., morphological, textural, and kinetic), comprehensive quantitative comparisons between the different lesion attributes have been rare. In addition, although kinetic signal enhancement curves may give insight into the underlying physiology of the lesion, signal intensity is susceptible to MRI acquisition artifacts such as bias field and intensity non-standardness. In this paper, we introduce a novel lesion feature that we call the kinetic texture feature, which we demonstrate to be superior compared to the lesion intensity profile dynamics. Our hypothesis is that since lesion intensity is susceptible to artifacts, lesion texture changes better reflect lesion class (benign or malignant). In this paper, we quantitatively demonstrate the superiority of kinetic texture features for lesion classification on 18 breast DCE-MRI studies compared to over 500 different morphological, kinetic intensity, and lesion texture features. In conjunction with linear and non-linear dimensionality reduction methods, a support vector machine (SVM) classifier yielded classification accuracy and positive predictive values of 78% and 86% with kinetic texture features compared to 78% and 73% with morphological features and 72% and 83% with textural features, respectively.

Proceedings Article | 17 March 2008 Paper

A meta-classifier for detecting prostate cancer by quantitative integration of in vivo magnetic resonance spectroscopy and magnetic resonance imaging

Satish Viswanath, Pallavi Tiwari, Mark Rosen, Anant Madabhushi

Proceedings Volume 6915, 69153D (2008) https://doi.org/10.1117/12.771022

KEYWORDS: Magnetic resonance imaging, Prostate, In vivo imaging, Cancer, Feature extraction, Data integration, Computer aided diagnosis and therapy, Prostate cancer, Image registration, Visualization

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Recently, in vivo Magnetic Resonance Imaging (MRI) and Magnetic Resonance Spectroscopy (MRS) have emerged as promising new modalities to aid in prostate cancer (CaP) detection. MRI provides anatomic and structural information of the prostate while MRS provides functional data pertaining to biochemical concentrations of metabolites such as creatine, choline and citrate. We have previously presented a hierarchical clustering scheme for CaP detection on in vivo prostate MRS and have recently developed a computer-aided method for CaP detection on in vivo prostate MRI. In this paper we present a novel scheme to develop a meta-classifier to detect CaP in vivo via quantitative integration of multimodal prostate MRS and MRI by use of non-linear dimensionality reduction (NLDR) methods including spectral clustering and locally linear embedding (LLE). Quantitative integration of multimodal image data (MRI and PET) involves the concatenation of image intensities following image registration. However multimodal data integration is non-trivial when the individual modalities include spectral and image intensity data. We propose a data combination solution wherein we project the feature spaces (image intensities and spectral data) associated with each of the modalities into a lower dimensional embedding space via NLDR. NLDR methods preserve the relationships between the objects in the original high dimensional space when projecting them into the reduced low dimensional space. Since the original spectral and image intensity data are divorced from their original physical meaning in the reduced dimensional space, data at the same spatial location can be integrated by concatenating the respective embedding vectors. Unsupervised consensus clustering is then used to partition objects into different classes in the combined MRS and MRI embedding space. Quantitative results of our multimodal computer-aided diagnosis scheme on 16 sets of patient data obtained from the ACRIN trial, for which corresponding histological ground truth for spatial extent of CaP is known, show a marginally higher sensitivity, specificity, and positive predictive value compared to corresponding CAD results with the individual modalities.

Proceedings Article | 17 March 2008 Paper

Improving supervised classification accuracy using non-rigid multimodal image registration: detecting prostate cancer

Jonathan Chappelow, Satish Viswanath, James Monaco, Mark Rosen, John Tomaszewski, Michael Feldman, Anant Madabhushi

Proceedings Volume 6915, 69150V (2008) https://doi.org/10.1117/12.770703

KEYWORDS: Magnetic resonance imaging, Image registration, Curium, Cancer, Prostate, Computer aided diagnosis and therapy, Prostate cancer, Image segmentation, Independent component analysis, Image classification

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Computer-aided diagnosis (CAD) systems for the detection of cancer in medical images require precise labeling of training data. For magnetic resonance (MR) imaging (MRI) of the prostate, training labels define the spatial extent of prostate cancer (CaP); the most common source for these labels is expert segmentations. When ancillary data such as whole mount histology (WMH) sections, which provide the gold standard for cancer ground truth, are available, the manual labeling of CaP can be improved by referencing WMH. However, manual segmentation is error prone, time consuming and not reproducible. Therefore, we present the use of multimodal image registration to automatically and accurately transcribe CaP from histology onto MRI following alignment of the two modalities, in order to improve the quality of training data and hence classifier performance. We quantitatively demonstrate the superiority of this registration-based methodology by comparing its results to the manual CaP annotation of expert radiologists. Five supervised CAD classifiers were trained using the labels for CaP extent on MRI obtained by the expert and 4 different registration techniques. Two of the registration methods were affi;ne schemes; one based on maximization of mutual information (MI) and the other method that we previously developed, Combined Feature Ensemble Mutual Information (COFEMI), which incorporates high-order statistical features for robust multimodal registration. Two non-rigid schemes were obtained by succeeding the two affine registration methods with an elastic deformation step using thin-plate splines (TPS). In the absence of definitive ground truth for CaP extent on MRI, classifier accuracy was evaluated against 7 ground truth surrogates obtained by different combinations of the expert and registration segmentations. For 26 multimodal MRI-WMH image pairs, all four registration methods produced a higher area under the receiver operating characteristic curve compared to that obtained from expert annotation. These results suggest that in the presence of additional multimodal image information one can obtain more accurate object annotations than achievable via expert delineation despite vast differences between modalities that hinder image registration.

Proceedings Article | 11 March 2008 Paper

A multi-modal prostate segmentation scheme by combining spectral clustering and active shape models

Robert Toth, Pallavi Tiwari, Mark Rosen, Arjun Kalyanpur, Sona Pungavkar, Anant Madabhushi

Proceedings Volume 6914, 69144S (2008) https://doi.org/10.1117/12.770772

KEYWORDS: Prostate, Image segmentation, Magnetic resonance imaging, In vivo imaging, Data modeling, Computing systems, Prostate cancer, Cancer, Statistical modeling, Shape analysis

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Segmentation of the prostate boundary on clinical images is useful in a large number of applications including calculating prostate volume during biopsy, tumor estimation, and treatment planning. Manual segmentation of the prostate boundary is, however, time consuming and subject to inter- and intra-reader variability. Magnetic Resonance (MR) imaging (MRI) and MR Spectroscopy (MRS) have recently emerged as promising modalities for detection of prostate cancer in vivo. In this paper we present a novel scheme for accurate and automated prostate segmentation on in vivo 1.5 Tesla multi-modal MRI studies. The segmentation algorithm comprises two steps: (1) A hierarchical unsupervised spectral clustering scheme using MRS data to isolate the region of interest (ROI) corresponding to the prostate, and (2) an Active Shape Model (ASM) segmentation scheme where the ASM is initialized within the ROI obtained in the previous step. The hierarchical MRS clustering scheme in step 1 identifies spectra corresponding to locations within the prostate in an iterative fashion by discriminating between potential prostate and non-prostate spectra in a lower dimensional embedding space. The spatial locations of the prostate spectra so identified are used as the initial ROI for the ASM. The ASM is trained by identifying user-selected landmarks on the prostate boundary on T2 MRI images. Boundary points on the prostate are identified using mutual information (MI) as opposed to the traditional Mahalanobis distance, and the trained ASM is deformed to fit the boundary points so identified. Cross validation on 150 prostate MRI slices yields an average segmentation sensitivity, specificity, overlap, and positive predictive value of 89, 86, 83, and 93&percent; respectively. We demonstrate that the accurate initialization of the ASM via the spectral clustering scheme is necessary for automated boundary extraction. Our method is fully automated, robust to system parameters, and computationally efficient.

Proceedings Article | 7 March 2007 Paper

Multimodal image registration of ex vivo 4 Tesla MRI with whole mount histology for prostate cancer detection

Jonathan Chappelow, Anant Madabhushi, Mark Rosen, John Tomaszeweski, Michael Feldman

Proceedings Volume 6512, 65121S (2007) https://doi.org/10.1117/12.710558

KEYWORDS: Magnetic resonance imaging, Cancer, Image registration, Prostate, Image segmentation, Computer aided diagnosis and therapy, Tissues, Visualization, Prostate cancer, Electronic filtering

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Proceedings Article | 29 April 2005 Paper

Generalized ball-scale: theory, algorithms, and application to image inhomogeneity correction

Anant Madabhushi, Jayaram Udupa, Andre Souza

Proceedings Volume 5747, (2005) https://doi.org/10.1117/12.595360

KEYWORDS: Image processing, Magnetic resonance imaging, Binary data, Image segmentation, 3D modeling, Algorithms, Medical imaging, Visualization, Brain, Multiscale representation

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Proceedings Article | 29 April 2005 Paper

New methods of MR image intensity standardization via generalized scale

Anant Madabhushi, Jayaram Udupa

Proceedings Volume 5747, (2005) https://doi.org/10.1117/12.595925

KEYWORDS: Tissues, Magnetic resonance imaging, Tumors, Seaborgium, Brain, Image segmentation, Medical imaging, Image processing, 3D image processing, Neuroimaging

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Image intensity standardization is a post-acquisition processing operation designed for correcting acquisition-to-acquisition signal intensity variations (non-standardness) inherent in Magnetic Resonance (MR) images. While existing standardization methods based on histogram landmarks have been shown to produce a significant gain in the similarity of resulting image intensities, their weakness is that, in some instances the same histogram-based landmark may represent one tissue, while in other cases it may represent different tissues. This is often true for diseased or abnormal patient studies in which significant changes in the image intensity characteristics may occur. In an attempt to overcome this problem, in this paper, we present two new intensity standardization methods based on the concept of generalized scale. In reference 1 we introduced the concept of generalized scale (g-scale) to overcome the shape, topological, and anisotropic constraints imposed by other local morphometric scale models. Roughly speaking, the g-scale of a voxel in a scene was defined as the largest set of voxels connected to the voxel that satisfy some homogeneity criterion. We subsequently formulated a variant of the generalized scale notion, referred to as generalized ball scale (g_B-scale), which, in addition to having the advantages of g-scale, also has superior noise resistance properties. These scale concepts are utilized in this paper to accurately determine principal tissue regions within MR images, and landmarks derived from these regions are used to perform intensity standardization. The new methods were qualitatively and quantitatively evaluated on a total of 67 clinical 3D MR images corresponding to four different protocols and to normal, Multiple Sclerosis (MS), and brain tumor patient studies. The generalized scale-based methods were found to be better than the existing methods, with a significant improvement observed for severely diseased and abnormal patient studies.

Proceedings Article | 29 April 2005 Paper

Generalized scale-based image filtering

Andre Souza, Jayaram Udupa, Anant Madabhushi

Proceedings Volume 5747, (2005) https://doi.org/10.1117/12.595784

KEYWORDS: Diffusion, Image filtering, Image processing, Radon, Anisotropic diffusion, Medical imaging, Signal to noise ratio, Fourier transforms, Optical fiber cables, Process control

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Proceedings Article | 12 May 2004 Paper

Generalized scale: theory, algorithms, and application to image inhomogeneity correction

Anant Madabhushi, Jayaram Udupa, Andre Souza

Proceedings Volume 5370, (2004) https://doi.org/10.1117/12.535696

KEYWORDS: Image processing, Magnetic resonance imaging, Tissues, Image segmentation, Visualization, Multiscale representation, Algorithms, Brain, Medical imaging, Image analysis

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Proceedings Article | 15 May 2003 Paper

Interplay between intensity standardization and field inhomogeneity correction in MR image processing

Anant Madabhushi, Jayaram Udupa

Proceedings Volume 5032, (2003) https://doi.org/10.1117/12.481345

KEYWORDS: Image quality standards, Magnetic resonance imaging, Image quality, Image processing, Tissues, Image segmentation, Image analysis, Medical imaging, Statistical modeling, Standards development

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Proceedings Article | 9 May 2002 Paper

Automatic quantification of liver-heart cross-talk for quality assessment in SPECT myocardial perfusion imaging

Guo-Qing Wei, Anant Madabhushi, JianZhong Qian, John Engdahl

Proceedings Volume 4684, (2002) https://doi.org/10.1117/12.467049

KEYWORDS: Heart, Liver, Single photon emission computed tomography, Expectation maximization algorithms, Image segmentation, 3D modeling, Reconstruction algorithms, Computed tomography, Roads, 3D image reconstruction

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