Your search keyword '"Nagarajan, Mahesh B."' showing total 2 results

1. Building a high-resolution T2-weighted MR-based probabilistic model of tumor occurrence in the prostate

Author

Nagarajan, Mahesh B, Raman, Steven S, Lo, Pechin, Lin, Wei-Chan, Khoshnoodi, Pooria, Sayre, James W, Ramakrishna, Bharath, Ahuja, Preeti, Huang, Jiaoti, Margolis, Daniel JA, Lu, David SK, Reiter, Robert E, Goldin, Jonathan G, Brown, Matthew S, and Enzmann, Dieter R

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Aging, Prostate Cancer, Urologic Diseases, Biomedical Imaging, Clinical Research, Cancer, Adult, Aged, Algorithms, Biopsy, Humans, Image Interpretation, Computer-Assisted, Magnetic Resonance Imaging, Male, Middle Aged, Neoplasm Grading, Probability, Prostatectomy, Prostatic Neoplasms, Retrospective Studies, Prostate cancer, Multi-parametric, MRI, Tumor occurrence probability map, Prostate registration, Multi-parametric MRI

Abstract

PurposeWe present a method for generating a T2 MR-based probabilistic model of tumor occurrence in the prostate to guide the selection of anatomical sites for targeted biopsies and serve as a diagnostic tool to aid radiological evaluation of prostate cancer.Materials and methodsIn our study, the prostate and any radiological findings within were segmented retrospectively on 3D T2-weighted MR images of 266 subjects who underwent radical prostatectomy. Subsequent histopathological analysis determined both the ground truth and the Gleason grade of the tumors. A randomly chosen subset of 19 subjects was used to generate a multi-subject-derived prostate template. Subsequently, a cascading registration algorithm involving both affine and non-rigid B-spline transforms was used to register the prostate of every subject to the template. Corresponding transformation of radiological findings yielded a population-based probabilistic model of tumor occurrence. The quality of our probabilistic model building approach was statistically evaluated by measuring the proportion of correct placements of tumors in the prostate template, i.e., the number of tumors that maintained their anatomical location within the prostate after their transformation into the prostate template space.ResultsProbabilistic model built with tumors deemed clinically significant demonstrated a heterogeneous distribution of tumors, with higher likelihood of tumor occurrence at the mid-gland anterior transition zone and the base-to-mid-gland posterior peripheral zones. Of 250 MR lesions analyzed, 248 maintained their original anatomical location with respect to the prostate zones after transformation to the prostate.ConclusionWe present a robust method for generating a probabilistic model of tumor occurrence in the prostate that could aid clinical decision making, such as selection of anatomical sites for MR-guided prostate biopsies.

Published

2018

2. Improving bone strength prediction in human proximal femur specimens through geometrical characterization of trabecular bone microarchitecture and support vector regression

Author

Yang, Chien-Chun, Nagarajan, Mahesh B, Huber, Markus B, Carballido-Gamio, Julio, Bauer, Jan S, Baum, Thomas, Eckstein, Felix, Lochmüller, Eva, Majumdar, Sharmila, Link, Thomas M, and Wismüller, Axel

Subjects

Bioengineering, Osteoporosis, Musculoskeletal, osteoporosis, trabecular bone, dual x-ray absorptiometry, bone mineral density, quantitative computer tomography, scaling index method, support vector regression, Artificial Intelligence and Image Processing, Artificial Intelligence & Image Processing

Abstract

We investigate the use of different trabecular bone descriptors and advanced machine learning tech niques to complement standard bone mineral density (BMD) measures derived from dual-energy x-ray absorptiometry (DXA) for improving clinical assessment of osteoporotic fracture risk. For this purpose, volumes of interest were extracted from the head, neck, and trochanter of 146 ex vivo proximal femur specimens on multidetector computer tomography. The trabecular bone captured was characterized with (1) statistical moments of the BMD distribution, (2) geometrical features derived from the scaling index method (SIM), and (3) morphometric parameters, such as bone fraction, trabecular thickness, etc. Feature sets comprising DXA BMD and such supplemental features were used to predict the failure load (FL) of the specimens, previously determined through biomechanical testing, with multiregression and support vector regression. Prediction performance was measured by the root mean square error (RMSE); correlation with measured FL was evaluated using the coefficient of determination R2. The best prediction performance was achieved by a combination of DXA BMD and SIM-derived geometric features derived from the femoral head (RMSE: 0.869 ± 0.121, R2: 0.68 ± 0.079), which was significantly better than DXA BMD alone (RMSE: 0.948 ± 0.119, R2: 0.61 ± 0.101) (p < 10-4). For multivariate feature sets, SVR outperformed multiregression (p < 0.05). These results suggest that supplementing standard DXA BMD measurements with sophisticated femoral trabecular bone characterization and supervised learning techniques can significantly improve biomechanical strength prediction in proximal femur specimens.

Published

2014