Optimization of an Adaptive SPECT System With the Scanning Linear Estimator

A method for optimization of an adaptive single photon emission computed tomography (SPECT) system is presented. Adaptive imaging systems can quickly change their hardware configuration in response to data being generated in order to improve image quality for a specific task. In this paper, we simul...

Full description

Saved in:
Bibliographic Details
Published in:IEEE transactions on radiation and plasma medical sciences 2017-09, Vol.1 (5), p.435-443
Main Authors: Ghanbari, Nasrin, Clarkson, Eric, Kupinski, Matthew, Li, Xin
Format: Article
Language:English
Subjects:
Adaptive single photon emission computed tomography (SPECT)
Adaptive systems
Estimation
Image quality
Optimization
Plasmas
simulation study
Single photon emission computed tomography
system optimization
task-based assessment of image quality
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:A method for optimization of an adaptive single photon emission computed tomography (SPECT) system is presented. Adaptive imaging systems can quickly change their hardware configuration in response to data being generated in order to improve image quality for a specific task. In this paper, we simulate an adaptive SPECT system and propose a method for finding the adaptation that maximizes the performance on a signal estimation task. To start with, a simulated object model containing a spherical signal is imaged with a scout configuration. A Markov-chain Monte Carlo technique utilizes the scout data to generate an ensemble of possible objects consistent with the scout data. This object ensemble is imaged by numerous simulated hardware configurations and for each system estimates of signal activity, size, and location are calculated via the scanning linear estimator. A figure of merit, based on a modified dice index (MDI), quantifies the performance of each imaging configuration and it allows for optimization of the adaptive SPECT. This figure of merit is calculated by multiplying two terms: the first term uses the definition of the Dice similarity index to determine the percent of overlap between the actual and the estimated spherical signal and the second term utilizes an exponential function that measures the squared error for the activity estimate. The MDI combines the error in estimates of activity, size, and location, in one convenient metric and it allows for simultaneous optimization of the SPECT system with respect to all the estimated signal parameters. The results of our optimizations indicate that the adaptive system performs better than a nonadaptive one in conditions where the diagnostic scan has a low photon count-on the order of thousand photons per projection. In a statistical study, we optimized the SPECT system for one hundred unique objects and demonstrated that the average MDI on an estimation task is 0.84 for the adaptive system and 0.65 for the nonadaptive system.
ISSN:2469-7311
2469-7303
DOI:10.1109/TRPMS.2017.2715041