Your search keyword '"Bevington CW"' showing total 2 results

1. Novel voxelwise residual analysis of [ 11 C]raclopride PET data improves detection of low-amplitude dopamine release.

Author

Bevington CW, Hanania JU, Ferraresso G, Cheng JK, Pavel A, Su D, Stoessl AJ, and Sossi V

Subjects

Humans, Male, Adult, Female, Carbon Radioisotopes, Radiopharmaceuticals, Raclopride metabolism, Positron-Emission Tomography methods, Dopamine metabolism, Dopamine analysis, Brain metabolism, Brain diagnostic imaging

Abstract

Existing methods for voxelwise transient dopamine (DA) release detection rely on explicit kinetic modeling of the [ 11 C]raclopride PET time activity curve, which at the voxel level is typically confounded by noise, leading to poor performance for detection of low-amplitude DA release-induced signals. Here we present a novel data-driven, task-informed method-referred to as Residual Space Detection (RSD)-that transforms PET time activity curves to a residual space where DA release-induced perturbations can be isolated and processed. Using simulations, we demonstrate that this method significantly increases detection performance compared to existing kinetic model-based methods for low-magnitude DA release (simulated +100% peak increase in basal DA concentration). In addition, results from nine healthy controls injected with a single bolus of [ 11 C]raclopride performing a finger tapping motor task are shown as proof-of-concept. The ability to detect relatively low magnitudes of dopamine release in the human brain using a single bolus injection, while achieving higher statistical power than previous methods, may additionally enable more complex analyses of neurotransmitter systems. Moreover, RSD is readily generalizable to multiple tasks performed during a single PET scan, further extending the capabilities of task-based single-bolus protocols., Competing Interests: Declaration of conflicting interestsThe author(s) declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Published

2024

2. A Monte Carlo approach for improving transient dopamine release detection sensitivity.

Author

Bevington CW, Cheng JK, Klyuzhin IS, Cherkasova MV, Winstanley CA, and Sossi V

Subjects

Humans, Dopamine metabolism, Monte Carlo Method, Positron-Emission Tomography methods

Abstract

Current methods using a single PET scan to detect voxel-level transient dopamine release-using F-test (significance) and cluster size thresholding-have limited detection sensitivity for clusters of release small in size and/or having low release levels. Specifically, simulations show that voxels with release near the peripheries of such clusters are often rejected-becoming false negatives and ultimately distorting the F-distribution of rejected voxels. We suggest a Monte Carlo method that incorporates these two observations into a cost function, allowing erroneously rejected voxels to be accepted under specified criteria. In simulations, the proposed method improves detection sensitivity by up to 50% while preserving the cluster size threshold, or up to 180% when optimizing for sensitivity. A further parametric-based voxelwise thresholding is then suggested to better estimate the release dynamics in detected clusters. We apply the Monte Carlo method to a pilot scan from a human gambling study, where additional parametrically unique clusters are detected as compared to the current best methods-results consistent with our simulations.

Published

2021