Ross Kleiman scite author profile

Ross Kleiman

5Publications

28Citation Statements Received

91Citation Statements Given

How they've been cited

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118

Affiliations

University of Wisconsin–Madison, Rutgers, The State University of New Jersey, Elucid Bioimaging

Publications

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Spatio‐temporal texture (SpTeT) for distinguishing vulnerable from stable atherosclerotic plaque on dynamic contrast enhancement (DCE) MRI in a rabbit model

et al. 2014

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Purpose:To develop a new spatio-temporal texture (SpTeT) based method for distinguishing vulnerable versus stable atherosclerotic plaques on DCE-MRI using a rabbit model of atherothrombosis. Methods: Aortic atherosclerosis was induced in 20 New Zealand White rabbits by cholesterol diet and endothelial denudation. MRI was performed before (pretrigger) and after (posttrigger) inducing plaque disruption with Russell's-viper-venom and histamine. Of the 30 vascular targets (segments) under histology analysis, 16 contained thrombus (vulnerable) and 14 did not (stable). A total of 352 voxel-wise computerized SpTeT features, including 192 Gabor, 36 Kirsch, 12 Sobel, 52 Haralick, and 60 first-order textural features, were extracted on DCE-MRI to capture subtle texture changes in the plaques over the course of contrast uptake. Different combinations of SpTeT feature sets, in which the features were ranked by a minimum-redundancy-maximum-relevance feature selection technique, were evaluated via a random forest classifier. A 500 iterative 2-fold cross validation was performed for discriminating the vulnerable atherosclerotic plaque and stable atherosclerotic plaque on per voxel basis. Four quantitative metrics were utilized to measure the classification results in separating between vulnerable and stable plaques. Results:The quantitative results show that the combination of five classes of SpTeT features can distinguish between vulnerable (disrupted plaques with an overlying thrombus) and stable plaques with the best AUC values of 0.9631 ± 0.0088, accuracy of 89.98% ± 0.57%, sensitivity of 83.71% ± 1.71%, and specificity of 94.55% ± 0.48%. Conclusions: Vulnerable and stable plaque can be distinguished by SpTeT based features. The SpTeT features, following validation on larger datasets, could be established as effective and reliable imaging biomarkers for noninvasively assessing atherosclerotic risk.

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Recursive Feature Elimination by Sensitivity Testing

Escanilla

Hellerstein

Kleiman

et al. 2018

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There is great interest in methods to improve human insight into trained non-linear models. Leading approaches include producing a ranking of the most relevant features, a non-trivial task for non-linear models. We show theoretically and empirically the benefit of a novel version of recursive feature elimination (RFE) as often used with SVMs; the key idea is a simple twist on the kinds of sensitivity testing employed in computational learning theory with membership queries (e.g., [1]). With membership queries, one can check whether changing the value of a feature in an example changes the label. In the real-world, we usually cannot get answers to such queries, so our approach instead makes these queries to a trained (imperfect) non-linear model. Because SVMs are widely used in bioinformatics, our empirical results use a real-world cancer genomics problem; because ground truth is not known for this task, we discuss the potential insights provided. We also evaluate on synthetic data where ground truth is known.

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Machine Learning-as-a-Service and Its Application to Medical Informatics

Tafti

LaRose

Badger

et al. 2017

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Biomedical Literature Mining for Repurposing Laboratory Tests

Kuusisto

Kleiman

Weiss

2022

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The Effects of Extracellular Matrix Proteins and Stiffness on Neuronal Cell Adhesion

Kleiman

Previtera

Parikh

et al. 2011

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Spinal cord injuries have spurred research interests in finding ways to repair or replace damaged neurons. We are looking to find novel ways to promote proliferation and differentiation of stem cells in order to replace damaged spinal cord neurons. While previous studies have shown that the mechanical properties of the cellular environment influence proliferation and differentiation, these studies have only been performed on polyacrylamide and agarose gels (1, 2). Collagen gels provide the opportunity to promote neuronal precursor cell (NPCs) proliferation and differentiation in a more natural environment by utilizing the mechanical properties of the gel. In this study, we examine the effects of 2D collagen matrices of varying stiffness on proliferation and differentiation of rat, spinal cord NPCs in order to create a more biocompatible tissue-engineered platform.

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Ross Kleiman

Spatio‐temporal texture (SpTeT) for distinguishing vulnerable from stable atherosclerotic plaque on dynamic contrast enhancement (DCE) MRI in a rabbit model

Recursive Feature Elimination by Sensitivity Testing

Machine Learning-as-a-Service and Its Application to Medical Informatics

Biomedical Literature Mining for Repurposing Laboratory Tests

The Effects of Extracellular Matrix Proteins and Stiffness on Neuronal Cell Adhesion

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