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117 results on '"Plassard, Andrew J."'

1. Deep Learning Captures More Accurate Diffusion Fiber Orientations Distributions than Constrained Spherical Deconvolution

Author

Nath, Vishwesh, Schilling, Kurt G., Hansen, Colin B., Parvathaneni, Prasanna, Hainline, Allison E., Bermudez, Camilo, Plassard, Andrew J., Janve, Vaibhav, Gao, Yurui, Blaber, Justin A., Stępniewska, Iwona, Anderson, Adam W., and Landman, Bennett A.

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition
Abstract

Confocal histology provides an opportunity to establish intra-voxel fiber orientation distributions that can be used to quantitatively assess the biological relevance of diffusion weighted MRI models, e.g., constrained spherical deconvolution (CSD). Here, we apply deep learning to investigate the potential of single shell diffusion weighted MRI to explain histologically observed fiber orientation distributions (FOD) and compare the derived deep learning model with a leading CSD approach. This study (1) demonstrates that there exists additional information in the diffusion signal that is not currently exploited by CSD, and (2) provides an illustrative data-driven model that makes use of this information., Comment: 2 pages, 4 figures. This work was accepted and published as an abstract at ISMRM 2018 held in Paris, France

Published
2019

2. Learning Implicit Brain MRI Manifolds with Deep Learning

Author

Bermudez, Camilo, Plassard, Andrew J., Davis, Larry T., Newton, Allen T., Resnick, Susan M, and Landman, Bennett A.

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

An important task in image processing and neuroimaging is to extract quantitative information from the acquired images in order to make observations about the presence of disease or markers of development in populations. Having a lowdimensional manifold of an image allows for easier statistical comparisons between groups and the synthesis of group representatives. Previous studies have sought to identify the best mapping of brain MRI to a low-dimensional manifold, but have been limited by assumptions of explicit similarity measures. In this work, we use deep learning techniques to investigate implicit manifolds of normal brains and generate new, high-quality images. We explore implicit manifolds by addressing the problems of image synthesis and image denoising as important tools in manifold learning. First, we propose the unsupervised synthesis of T1-weighted brain MRI using a Generative Adversarial Network (GAN) by learning from 528 examples of 2D axial slices of brain MRI. Synthesized images were first shown to be unique by performing a crosscorrelation with the training set. Real and synthesized images were then assessed in a blinded manner by two imaging experts providing an image quality score of 1-5. The quality score of the synthetic image showed substantial overlap with that of the real images. Moreover, we use an autoencoder with skip connections for image denoising, showing that the proposed method results in higher PSNR than FSL SUSAN after denoising. This work shows the power of artificial networks to synthesize realistic imaging data, which can be used to improve image processing techniques and provide a quantitative framework to structural changes in the brain., Comment: SPIE Medical Imaging 2018

Published
2018
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3. A Data Colocation Grid Framework for Big Data Medical Image Processing - Backend Design

Author

Bao, Shunxing, Huo, Yuankai, Parvathaneni, Prasanna, Plassard, Andrew J., Bermudez, Camilo, Yao, Yuang, Llyu, Ilwoo, Gokhale, Aniruddha, and Landman, Bennett A.

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

When processing large medical imaging studies, adopting high performance grid computing resources rapidly becomes important. We recently presented a "medical image processing-as-a-service" grid framework that offers promise in utilizing the Apache Hadoop ecosystem and HBase for data colocation by moving computation close to medical image storage. However, the framework has not yet proven to be easy to use in a heterogeneous hardware environment. Furthermore, the system has not yet validated when considering variety of multi-level analysis in medical imaging. Our target criteria are (1) improving the framework's performance in a heterogeneous cluster, (2) performing population based summary statistics on large datasets, and (3) introducing a table design scheme for rapid NoSQL query. In this paper, we present a backend interface application program interface design for Hadoop & HBase for Medical Image Processing. The API includes: Upload, Retrieve, Remove, Load balancer and MapReduce templates. A dataset summary statistic model is discussed and implemented by MapReduce paradigm. We introduce a HBase table scheme for fast data query to better utilize the MapReduce model. Briefly, 5153 T1 images were retrieved from a university secure database and used to empirically access an in-house grid with 224 heterogeneous CPU cores. Three empirical experiments results are presented and discussed: (1) load balancer wall-time improvement of 1.5-fold compared with a framework with built-in data allocation strategy, (2) a summary statistic model is empirically verified on grid framework and is compared with the cluster when deployed with a standard Sun Grid Engine, which reduces 8-fold of wall clock time and 14-fold of resource time, and (3) the proposed HBase table scheme improves MapReduce computation with 7 fold reduction of wall time compare with a na\"ive scheme when datasets are relative small., Comment: Accepted and awaiting publication at SPIE Medical Imaging, International Society for Optics and Photonics, 2018

Published
2017

4. Splenomegaly Segmentation using Global Convolutional Kernels and Conditional Generative Adversarial Networks

Author

Huo, Yuankai, Xu, Zhoubing, Bao, Shunxing, Bermudez, Camilo, Plassard, Andrew J., Liu, Jiaqi, Yao, Yuang, Assad, Albert, Abramson, Richard G., and Landman, Bennett A.

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Spleen volume estimation using automated image segmentation technique may be used to detect splenomegaly (abnormally enlarged spleen) on Magnetic Resonance Imaging (MRI) scans. In recent years, Deep Convolutional Neural Networks (DCNN) segmentation methods have demonstrated advantages for abdominal organ segmentation. However, variations in both size and shape of the spleen on MRI images may result in large false positive and false negative labeling when deploying DCNN based methods. In this paper, we propose the Splenomegaly Segmentation Network (SSNet) to address spatial variations when segmenting extraordinarily large spleens. SSNet was designed based on the framework of image-to-image conditional generative adversarial networks (cGAN). Specifically, the Global Convolutional Network (GCN) was used as the generator to reduce false negatives, while the Markovian discriminator (PatchGAN) was used to alleviate false positives. A cohort of clinically acquired 3D MRI scans (both T1 weighted and T2 weighted) from patients with splenomegaly were used to train and test the networks. The experimental results demonstrated that a mean Dice coefficient of 0.9260 and a median Dice coefficient of 0.9262 using SSNet on independently tested MRI volumes of patients with splenomegaly., Comment: SPIE Medical Imaging 2018

Published
2017

16. Right Fronto-Subcortical White Matter Microstructure Predicts Cognitive Control Ability on the Go/No-go Task in a Community Sample

Author

Hinton, Kendra E., primary, Lahey, Benjamin B., additional, Villalta-Gil, Victoria, additional, Boyd, Brian D., additional, Yvernault, Benjamin C., additional, Werts, Katherine B., additional, Plassard, Andrew J., additional, Applegate, Brooks, additional, Woodward, Neil D., additional, Landman, Bennett A., additional, and Zald, David H., additional

Published
2018
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28. Evaluation of Atlas-Based White Matter Segmentation with Eve

Author

Plassard, Andrew J., Hinton, Kendra E., Venkatraman, Vijay, Gonzalez, Christopher, Resnick, Susan M., and Landman, Bennett A.

Subjects
education, Article
Abstract

Multi-atlas labeling has come in wide spread use for whole brain labeling on magnetic resonance imaging. Recent challenges have shown that leading techniques are near (or at) human expert reproducibility for cortical gray matter labels. However, these approaches tend to treat white matter as essentially homogeneous (as white matter exhibits isointense signal on structural MRI). The state-of-the-art for white matter atlas is the single-subject Johns Hopkins Eve atlas. Numerous approaches have attempted to use tractography and/or orientation information to identify homologous white matter structures across subjects. Despite success with large tracts, these approaches have been plagued by difficulties in with subtle differences in course, low signal to noise, and complex structural relationships for smaller tracts. Here, we investigate use of atlas-based labeling to propagate the Eve atlas to unlabeled datasets. We evaluate single atlas labeling and multi-atlas labeling using synthetic atlases derived from the single manually labeled atlas. On 5 representative tracts for 10 subjects, we demonstrate that (1) single atlas labeling generally provides segmentations within 2mm mean surface distance, (2) morphologically constraining DTI labels within structural MRI white matter reduces variability, and (3) multi-atlas labeling did not improve accuracy. These efforts present a preliminary indication that single atlas labels with correction is reasonable, but caution should be applied. To purse multi-atlas labeling and more fully characterize overall performance, more labeled datasets would be necessary.

Published
2015

29. Disambiguating the Optic Nerve from the Surrounding Cerebrospinal Fluid: Application to MS-related Atrophy

Author

Harrigan, Robert L., Plassard, Andrew J., Bryan, Frederick W., Caires, Gabriela, Mawn, Louise A., Dethrage, Lindsey M., Pawate, Siddharama, Galloway, Robert L., Smith, Seth A., and Landman, Bennett A.

Subjects
Adult, Male, Models, Statistical, Multiple Sclerosis, Reproducibility of Results, Optic Nerve, Image Enhancement, Magnetic Resonance Imaging, Sensitivity and Specificity, Article, Pattern Recognition, Automated, Optic Atrophy, Young Adult, Subtraction Technique, Image Interpretation, Computer-Assisted, Humans, Computer Simulation, Female, Algorithms, Cerebrospinal Fluid
Abstract

Our goal is to develop an accurate, automated tool to characterize the optic nerve (ON) and cerebrospinal fluid (CSF) to better understand ON changes in disease.Multi-atlas segmentation is used to localize the ON and sheath on T2-weighted MRI (0.6 mm(3) resolution). A sum of Gaussian distributions is fit to coronal slice-wise intensities to extract six descriptive parameters, and a regression forest is used to map the model space to radii. The model is validated for consistency using tenfold cross-validation and for accuracy using a high resolution (0.4 mm(2) reconstructed to 0.15 mm(2)) in vivo sequence. We evaluated this model on 6 controls and 6 patients with multiple sclerosis (MS) and a history of optic neuritis.In simulation, the model was found to have an explanatory R-squared for both ON and sheath radii greater than 0.95. The accuracy of the method was within the measurement error on the highest possible in vivo resolution. Comparing healthy controls and patients with MS, significant structural differences were found near the ON head and the chiasm, and structural trends agreed with the literature.This is a first demonstration that the ON can be exclusively, quantitatively measured and separated from the surrounding CSF using MRI.

Published
2015

35. On the fallacy of quantitative segmentation for T1-weighted MRI

Author

Plassard, Andrew J., additional, Harrigan, Robert L., additional, Newton, Allen T., additional, Rane, Swati, additional, Pallavaram, Srivastan, additional, D'Haese, Pierre F., additional, Dawant, Benoit M., additional, Claassen, Daniel O., additional, and Landman, Bennett A., additional

Published
2016
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