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