Your search keyword '"Whiteman, Andrew S."' showing total 8 results

1. Entorhinal volume, aerobic fitness, and recognition memory in healthy young adults: A voxel-based morphometry study

Author

Whiteman, Andrew S., Young, Daniel E., Budson, Andrew E., Stern, Chantal E., and Schon, Karin

Published

2016

2. Bayesian inference for group-level cortical surface image-on-scalar-regression with Gaussian process priors

Author

Whiteman, Andrew S., Johnson, Timothy D., and Kang, Jian

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Statistics - Methodology

Abstract

In regression-based analyses of group-level neuroimage data researchers typically fit a series of marginal general linear models to image outcomes at each spatially-referenced pixel. Spatial regularization of effects of interest is usually induced indirectly by applying spatial smoothing to the data during preprocessing. While this procedure often works well, resulting inference can be poorly calibrated. Spatial modeling of effects of interest leads to more powerful analyses, however the number of locations in a typical neuroimage can preclude standard computation with explicitly spatial models. Here we contribute a Bayesian spatial regression model for group-level neuroimaging analyses. We induce regularization of spatially varying regression coefficient functions through Gaussian process priors. When combined with a simple nonstationary model for the error process, our prior hierarchy can lead to more data-adaptive smoothing than standard methods. We achieve computational tractability through Vecchia approximation of our prior which, critically, can be constructed for a wide class of spatial correlation functions and results in prior models that retain full spatial rank. We outline several ways to work with our model in practice and compare performance against standard vertex-wise analyses. Finally we illustrate our method in an analysis of cortical surface fMRI task contrast data from a large cohort of children enrolled in the Adolescent Brain Cognitive Development study.

Published

2023

3. Interaction between serum BDNF and aerobic fitness predicts recognition memory in healthy young adults

Author

Whiteman, Andrew S., Young, Daniel E., He, Xuemei, Chen, Tai C., Wagenaar, Robert C., Stern, Chantal E., and Schon, Karin

Published

2014

4. Exposure-Focused CBT Outperforms Relaxation-Based Control in an RCT of Treatment for Child and Adolescent Anxiety.

Author

Bilek, Emily, Tomlinson, Rachel C., Whiteman, Andrew S., Johnson, Timothy D., Benedict, Chelsea, Phan, K. Luan, Monk, Christopher S., and Fitzgerald, Kate D.

Subjects

ANXIETY disorders, COGNITIVE therapy, ANXIETY, TEENAGERS, TREATMENT effectiveness

Abstract

The relative contribution of individual cognitive behavioral therapy (CBT) components to treatment outcomes for child anxiety disorders (CADs) is unclear. Recent meta-analyses suggest that exposure may be the primary active ingredient in CBT for CADs, and that relaxation may be relatively less effective. This brief report tests the hypothesis that exposure-focused CBT (EF-CBT) would outperform a relaxation-based active therapy control (Relaxation Mentorship Training; RMT) for the treatment of CADs. Participants were 102 youth with CADs (mean age = 11.91, 26 males; 76.4% White, 14.7% Multiracial, 3.9% Black, 3.9% Asian, 0.9% other/do not wish to identify) as part of an ongoing neuroimaging randomized controlled trial. Participants were randomly assigned (ratio 2:1) to receive 12 sessions of EF-CBT (n = 70) or RMT (n = 32). Clinical improvement was measured at Week 12 (Clinical Global Impression – Improvement scale; CGI-I); treatment response was defined as receiving a rating of "very much" or "much improved" on the CGI-I. Anxiety severity was measured at Weeks 1, 6, 9, 12 (Pediatric Anxiety Rating Scale; PARS). Outcome measures were completed by an independent evaluator unaware of condition. EF-CBT exhibited 2.98 times higher odds of treatment completion than RMT; 13 treatment non-completers were included in analyses. Estimated treatment response rates were higher for EF-CBT (57.3%) than for RMT (19.2%). Longitudinal analyses indicated that EF-CBT was associated with faster and more pronounced anxiety reductions than RMT on the PARS (Hedges' g =.77). Results suggest that EF-CBT without relaxation is effective for CADs, and more effective than a relaxation-based intervention. [ABSTRACT FROM AUTHOR]

Published

2022

5. Hippocampal subfield and medial temporal cortical persistent activity during working memory reflects ongoing encoding.

Author

Nauer, Rachel K., Whiteman, Andrew S., Dunne, Matthew F., Stern, Chantal E., and Schon, Karin

Subjects

BRAIN imaging, TEMPORAL lobe, SHORT-term memory, HIPPOCAMPUS (Brain), FUNCTIONAL magnetic resonance imaging

Abstract

Previous neuroimaging studies support a role for the medial temporal lobes in maintaining novel stimuli over brief working memory (WM) delays, and suggest delay period activity predicts subsequent memory. Additionally, slice recording studies have demonstrated neuronal persistent spiking in entorhinal cortex, perirhinal cortex (PrC), and hippocampus (CA1, CA3, subiculum). These data have led to computational models that suggest persistent spiking in parahippocampal regions could sustain neuronal representations of sensory information over many seconds. This mechanism may support both WM maintenance and encoding of information into long term episodic memory. The goal of the current study was to use high-resolution fMRI to elucidate the contributions of the MTL cortices and hippocampal subfields to WM maintenance as it relates to later episodic recognition memory. We scanned participants while they performed a delayed match to sample task with novel scene stimuli, and assessed their memory for these scenes post-scan. We hypothesized stimulus-driven activation that persists into the delay period—a putative correlate of persistent spiking—would predict later recognition memory. Our results suggest sample and delay period activation in the parahippocampal cortex (PHC), PrC, and subiculum (extending into DG/CA3 and CA1) was linearly related to increases in subsequent memory strength. These data extend previous neuroimaging studies that have constrained their analysis to either the sample or delay period by modeling these together as one continuous ongoing encoding process, and support computational frameworks that predict persistent activity underlies both WM and episodic encoding. [ABSTRACT FROM AUTHOR]

Published

2015

6. Structural Differences in Hippocampal and Prefrontal Gray Matter Volume Support Flexible Context-Dependent Navigation Ability.

Author

Brown, Thackery I., Whiteman, Andrew S., Aselcioglu, Irem, and Stern, Chantal E.

Subjects

*PREFRONTAL cortex, *HIPPOCAMPUS physiology, *HIPPOCAMPUS (Brain), *VOXEL-based morphometry, *YOUTH health, *NEUROPILINS, *ANATOMY

Abstract

Spatial navigation is a fundamental part of daily life. Humans differ in their individual abilities to flexibly navigate their world, and a critical question is how this variability relates to differences in underlying brain structure. Our experiment examined individual differences in the ability to flexibly navigate routes that overlap with, and must be distinguished from, previously learned trajectories. We related differences in flexible navigation performance to differences in brain morphology in healthy young adults using voxel-based morphometry. Our findings provide novel evidence that individual differences in gray matter volume in the hippocampus and dorsolateral prefrontal cortex correlate with our ability rapidly to learn and flexibly navigate routes through our world. [ABSTRACT FROM AUTHOR]

Published

2014

7. Bayesian inference for group-level cortical surface image-on-scalar regression with Gaussian process priors.

Author

Whiteman AS, Johnson TD, and Kang J

Subjects

Humans, Normal Distribution, Magnetic Resonance Imaging methods, Magnetic Resonance Imaging statistics & numerical data, Child, Cerebral Cortex diagnostic imaging, Computer Simulation, Regression Analysis, Models, Statistical, Image Processing, Computer-Assisted methods, Bayes Theorem, Neuroimaging methods, Neuroimaging statistics & numerical data

Abstract

In regression-based analyses of group-level neuroimage data, researchers typically fit a series of marginal general linear models to image outcomes at each spatially referenced pixel. Spatial regularization of effects of interest is usually induced indirectly by applying spatial smoothing to the data during preprocessing. While this procedure often works well, the resulting inference can be poorly calibrated. Spatial modeling of effects of interest leads to more powerful analyses; however, the number of locations in a typical neuroimage can preclude standard computing methods in this setting. Here, we contribute a Bayesian spatial regression model for group-level neuroimaging analyses. We induce regularization of spatially varying regression coefficient functions through Gaussian process priors. When combined with a simple non-stationary model for the error process, our prior hierarchy can lead to more data-adaptive smoothing than standard methods. We achieve computational tractability through a Vecchia-type approximation of our prior that retains full spatial rank and can be constructed for a wide class of spatial correlation functions. We outline several ways to work with our model in practice and compare performance against standard vertex-wise analyses and several alternatives. Finally, we illustrate our methods in an analysis of cortical surface functional magnetic resonance imaging task contrast data from a large cohort of children enrolled in the adolescent brain cognitive development study., (© The Author(s) 2024. Published by Oxford University Press on behalf of The International Biometric Society.)

Published

2024

8. Bayesian Inference for Brain Activity from Functional Magnetic Resonance Imaging Collected at Two Spatial Resolutions.

Author

Whiteman AS, Bartsch AJ, Kang J, and Johnson TD

Abstract

Neuroradiologists and neurosurgeons increasingly opt to use functional magnetic resonance imaging (fMRI) to map functionally relevant brain regions for noninvasive presurgical planning and intraoperative neuronavigation. This application requires a high degree of spatial accuracy, but the fMRI signal-to-noise ratio (SNR) decreases as spatial resolution increases. In practice, fMRI scans can be collected at multiple spatial resolutions, and it is of interest to make more accurate inference on brain activity by combining data with different resolutions. To this end, we develop a new Bayesian model to leverage both better anatomical precision in high resolution fMRI and higher SNR in standard resolution fMRI. We assign a Gaussian process prior to the mean intensity function and develop an efficient, scalable posterior computation algorithm to integrate both sources of data. We draw posterior samples using an algorithm analogous to Riemann manifold Hamiltonian Monte Carlo in an expanded parameter space. We illustrate our method in analysis of presurgical fMRI data, and show in simulation that it infers the mean intensity more accurately than alternatives that use either the high or standard resolution fMRI data alone.

Published

2022