Your search keyword '"Rewa Sood"' showing total 5 results

1. Registration of presurgical MRI and histopathology images from radical prostatectomy via RAPSODI

Author

Richard E. Fan, Mirabela Rusu, Rewa Sood, Wei Shao, Simon John Christoph Soerensen, Geoffrey A. Sonn, Leo C Chen, Nikola C. Teslovich, Jeffrey B. Wang, Pejman Ghanouni, James D. Brooks, and Christian A. Kunder

Subjects

Male, medicine.medical_specialty, medicine.medical_treatment, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Prostate cancer, 0302 clinical medicine, Sørensen–Dice coefficient, registration, Prostate, QUANTITATIVE IMAGING AND IMAGE PROCESSING, medicine, Humans, Research Articles, Fixation (histology), Prostatectomy, medicine.diagnostic_test, business.industry, Prostatic Neoplasms, Seminal Vesicles, Magnetic resonance imaging, General Medicine, prostate cancer, medicine.disease, Magnetic Resonance Imaging, medicine.anatomical_structure, cancer labels, 030220 oncology & carcinogenesis, histopathology, Histopathology, Radiology, business, Research Article, MRI

Abstract

Purpose: Magnetic resonance imaging (MRI) has great potential to improve prostate cancer diagnosis; however, subtle differences between cancer and confounding conditions render prostate MRI interpretation challenging. The tissue collected from patients who undergo radical prostatectomy provides a unique opportunity to correlate histopathology images of the prostate with preoperative MRI to accurately map the extent of cancer from histopathology images onto MRI. We seek to develop an open-source, easy-to-use platform to align presurgical MRI and histopathology images of resected prostates in patients who underwent radical prostatectomy to create accurate cancer labels on MRI. Methods: Here, we introduce RAdiology Pathology Spatial Open-Source multi-Dimensional Integration (RAPSODI), the first open-source framework for the registration of radiology and pathology images. RAPSODI relies on three steps. First, it creates a three-dimensional (3D) reconstruction of the histopathology specimen as a digital representation of the tissue before gross sectioning. Second, RAPSODI registers corresponding histopathology and MRI slices. Third, the optimized transforms are applied to the cancer regions outlined on the histopathology images to project those labels onto the preoperative MRI. Results: We tested RAPSODI in a phantom study where we simulated various conditions, for example, tissue shrinkage during fixation. Our experiments showed that RAPSODI can reliably correct multiple artifacts. We also evaluated RAPSODI in 157 patients from three institutions that underwent radical prostatectomy and have very different pathology processing and scanning. RAPSODI was evaluated in 907 corresponding histpathology-MRI slices and achieved a Dice coefficient of 0.97 ± 0.01 for the prostate, a Hausdorff distance of 1.99 ± 0.70 mm for the prostate boundary, a urethra deviation of 3.09 ± 1.45 mm, and a landmark deviation of 2.80 ± 0.59 mm between registered histopathology images and MRI. Conclusion: Our robust framework successfully mapped the extent of cancer from histopathology slices onto MRI providing labels from training machine learning methods to detect cancer on MRI.

Published

2020

2. 3D Registration of pre-surgical prostate MRI and histopathology images via super-resolution volume reconstruction

Author

Christian A. Kunder, Anugayathri Jawahar, Wei Shao, Richard E. Fan, Simon John Christoph Soerensen, Pejman Ghanouni, Jeffrey B. Wang, Rewa Sood, Nikola C. Teslovich, Mirabela Rusu, Nikhil Madhuripan, Geoffrey A. Sonn, and James D. Brooks

Subjects

Male, medicine.medical_specialty, Generative adversarial networks, Computer science, HISTOLOGICAL SECTIONS, medicine.medical_treatment, Health Informatics, images onto MRI, Article, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Prostate, medicine, Humans, Radiology, Nuclear Medicine and imaging, Volume reconstruction, Projection (set theory), nbsp, 3d registration, Radiological and Ultrasound Technology, Prostatectomy, Mapping cancer from histopathology&amp, Prostatic Neoplasms, Super-resolution registration, Magnetic Resonance Imaging, Computer Graphics and Computer-Aided Design, Superresolution, Mapping cancer from histopathology images onto MRI, medicine.anatomical_structure, Radiology pathology fusion, Histopathology, Computer Vision and Pattern Recognition, Radiology, 030217 neurology & neurosurgery, Interpolation

Abstract

The use of MRI for prostate cancer diagnosis and treatment is increasing rapidly. However, identifying the presence and extent of cancer on MRI remains challenging, leading to high variability in detection even among expert radiologists. Improvement in cancer detection on MRI is essential to reducing this variability and maximizing the clinical utility of MRI. To date, such improvement has been limited by the lack of accurately labeled MRI datasets. Data from patients who underwent radical prostatectomy enables the spatial alignment of digitized histopathology images of the resected prostate with corresponding pre-surgical MRI. This alignment facilitates the delineation of detailed cancer labels on MRI via the projection of cancer from histopathology images onto MRI. We introduce a framework that performs 3D registration of whole-mount histopathology images to pre-surgical MRI in three steps. First, we developed a novel multi-image super-resolution generative adversarial network (miSRGAN), which learns information useful for 3D registration by producing a reconstructed 3D MRI. Second, we trained the network to learn information between histopathology slices to facilitate the application of 3D registration methods. Third, we registered the reconstructed 3D histopathology volumes to the reconstructed 3D MRI, mapping the extent of cancer from histopathology images onto MRI without the need for slice-to-slice correspondence. When compared to interpolation methods, our super-resolution reconstruction resulted in the highest PSNR relative to clinical 3D MRI (32.15 dB vs 30.16 dB for BSpline interpolation). Moreover, the registration of 3D volumes reconstructed via super-resolution for both MRI and histopathology images showed the best alignment of cancer regions when compared to (1) the state-of-the-art RAPSODI approach, (2) volumes that were not reconstructed, or (3) volumes that were reconstructed using nearest neighbor, linear, or BSpline interpolations. The improved 3D alignment of histopathology images and MRI facilitates the projection of accurate cancer labels on MRI, allowing for the development of improved MRI interpretation schemes and machine learning models to automatically detect cancer on MRI.

Published

2021

3. CorrSigNet: Learning CORRelated Prostate Cancer SIGnatures from Radiology and Pathology Images for Improved Computer Aided Diagnosis

Author

Arun Seetharaman, Wei Shao, Rewa Sood, Mirabela Rusu, Pejman Ghanouni, Indrani Bhattacharya, Nikola C. Teslovich, Richard E. Fan, Christian A. Kunder, Simon John Christoph Soerensen, Jeffrey B. Wang, James D. Brooks, and Geoffrey A. Sonn

Subjects

medicine.medical_specialty, Pathology, medicine.diagnostic_test, Prostatectomy, business.industry, medicine.medical_treatment, 030232 urology & nephrology, Cancer, Magnetic resonance imaging, medicine.disease, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Prostate cancer, 0302 clinical medicine, medicine.anatomical_structure, Prostate, Computer-aided diagnosis, medicine, Radiology, Medical diagnosis, business, Feature learning

Abstract

Magnetic Resonance Imaging (MRI) is widely used for screening and staging prostate cancer. However, many prostate cancers have subtle features which are not easily identifiable on MRI, resulting in missed diagnoses and alarming variability in radiologist interpretation. Machine learning models have been developed in an effort to improve cancer identification, but current models localize cancer using MRI-derived features, while failing to consider the disease pathology characteristics observed on resected tissue. In this paper, we propose CorrSigNet, an automated two-step model that localizes prostate cancer on MRI by capturing the pathology features of cancer. First, the model learns MRI signatures of cancer that are correlated with corresponding histopathology features using Common Representation Learning. Second, the model uses the learned correlated MRI features to train a Convolutional Neural Network to localize prostate cancer. The histopathology images are used only in the first step to learn the correlated features. Once learned, these correlated features can be extracted from MRI of new patients (without histopathology or surgery) to localize cancer. We trained and validated our framework on a unique dataset of 75 patients with 806 slices who underwent MRI followed by prostatectomy surgery. We tested our method on an independent test set of 20 prostatectomy patients (139 slices, 24 cancerous lesions, 1.12M pixels) and achieved a per-pixel sensitivity of 0.81, specificity of 0.71, AUC of 0.86 and a per-lesion AUC of \(0.96 \pm 0.07\), outperforming the current state-of-the-art accuracy in predicting prostate cancer using MRI.

Published

2020

4. Anisotropic Super Resolution In Prostate Mri Using Super Resolution Generative Adversarial Networks

Author

Rewa Sood and Mirabela Rusu

Subjects

FOS: Computer and information sciences, Structural similarity, Computer science, Computer Vision and Pattern Recognition (cs.CV), Computer Science - Computer Vision and Pattern Recognition, 030218 nuclear medicine & medical imaging, Image (mathematics), 03 medical and health sciences, 0302 clinical medicine, FOS: Electrical engineering, electronic engineering, information engineering, medicine, Computer vision, Anisotropy, medicine.diagnostic_test, business.industry, Image and Video Processing (eess.IV), Isotropy, Resolution (electron density), Process (computing), Magnetic resonance imaging, Electrical Engineering and Systems Science - Image and Video Processing, Superresolution, Computer Science::Computer Vision and Pattern Recognition, Bicubic interpolation, Artificial intelligence, Enhanced Data Rates for GSM Evolution, business, 030217 neurology & neurosurgery

Abstract

Acquiring High Resolution (HR) Magnetic Resonance (MR) images requires the patient to remain still for long periods of time, which causes patient discomfort and increases the probability of motion induced image artifacts. A possible solution is to acquire low resolution (LR) images and to process them with the Super Resolution Generative Adversarial Network (SRGAN) to create a super-resolved version. This work applies SRGAN to MR images of the prostate and performs three experiments. The first experiment explores improving the in-plane MR image resolution by factors of 4 and 8, and shows that, while the PSNR and SSIM (Structural SIMilarity) metrics are lower than the isotropic bicubic interpolation baseline, the SRGAN is able to create images that have high edge fidelity. The second experiment explores anisotropic super-resolution via synthetic images, in that the input images to the network are anisotropically downsampled versions of HR images. This experiment demonstrates the ability of the modified SRGAN to perform anisotropic super-resolution, with quantitative image metrics that are comparable to those of the anisotropic bicubic interpolation baseline. Finally, the third experiment applies a modified version of the SRGAN to super-resolve anisotropic images obtained from the through-plane slices of the volumetric MR data. The output super-resolved images contain a significant amount of high frequency information that make them visually close to their HR counterparts. Overall, the promising results from each experiment show that super-resolution for MR images is a successful technique and that producing isotropic MR image volumes from anisotropic slices is an achievable goal., International Symposium on Biomedical Imaging, 4 pages, 4 figures, 1 table

Published

2019

5. An Application of Generative Adversarial Networks for Super Resolution Medical Imaging

Author

Mirabela Rusu, Rohit Sood, Karthik Choutagunta, Binit Topiwala, and Rewa Sood

Subjects

FOS: Computer and information sciences, Structural similarity, Computer science, Mean opinion score, Computer Vision and Pattern Recognition (cs.CV), Computer Science - Computer Vision and Pattern Recognition, Context (language use), 02 engineering and technology, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, 0202 electrical engineering, electronic engineering, information engineering, Medical imaging, medicine, FOS: Electrical engineering, electronic engineering, information engineering, Computer vision, Image resolution, medicine.diagnostic_test, business.industry, Resolution (electron density), Image and Video Processing (eess.IV), Magnetic resonance imaging, Sparse approximation, Electrical Engineering and Systems Science - Image and Video Processing, Superresolution, 020201 artificial intelligence & image processing, Artificial intelligence, business

Abstract

Acquiring High Resolution (HR) Magnetic Resonance (MR) images requires the patient to remain still for long periods of time, which causes patient discomfort and increases the probability of motion induced image artifacts. A possible solution is to acquire low resolution (LR) images and to process them with the Super Resolution Generative Adversarial Network (SRGAN) to create an HR version. Acquiring LR images requires a lower scan time than acquiring HR images, which allows for higher patient comfort and scanner throughput. This work applies SRGAN to MR images of the prostate to improve the in-plane resolution by factors of 4 and 8. The term 'super resolution' in the context of this paper defines the post processing enhancement of medical images as opposed to 'high resolution' which defines native image resolution acquired during the MR acquisition phase. We also compare the SRGAN to three other models: SRCNN, SRResNet, and Sparse Representation. While the SRGAN results do not have the best Peak Signal to Noise Ratio (PSNR) or Structural Similarity (SSIM) metrics, they are the visually most similar to the original HR images, as portrayed by the Mean Opinion Score (MOS) results., Comment: International Conference on Machine Learning Applications, 6 pages, 5 figures, 2 tables

Published

2019