Monte Carlo-based Scatter Correction for the SMARTZOOM Collimator

Overview

Journal EJNMMI Phys

Specialty Radiology

Date 2020 Jul 24

PMID 32700063

Citations 1

Authors

Martijn M A Dietze

Britt Kunnen

Martina Stella

Hugo W A M de Jong

Affiliations

Soon will be listed here.

Abstract

Background: Myocardial perfusion imaging is a commonly performed SPECT protocol and hence it would be beneficial if its scan duration could be shortened. For traditional gamma cameras, two developments have separately shown to allow for a shortened scan duration: (i) reconstructing with Monte Carlo-based scatter correction instead of dual-energy window scatter correction and (ii) acquiring projections with the SMARTZOOM collimator instead of a parallel-hole collimator. This study investigates which reduction in scan duration can be achieved when both methods are combined in a single system.

Results: The SMARTZOOM collimator was implemented in a Monte Carlo-based reconstruction package and the implementation was validated through image quality phantom experiments. The potential for scan duration reduction was evaluated with a phantom configuration that is realistic for myocardial perfusion imaging. The original reconstruction quality was achieved in 76 ± 8% of the original scan duration when switching from dual-energy window scatter correction to Monte Carlo-based scatter correction. The original reconstruction quality was achieved in 56 ± 13% of the original scan duration when switching from the parallel-hole to the SMARTZOOM collimator. After combining both methods in a single system, the original reconstruction quality was achieved in 34 ± 7% of the original scan duration.

Conclusions: Monte Carlo-based scatter correction combined with the SMARTZOOM collimator can further decrease the scan duration in myocardial perfusion imaging.

Citing Articles

A compact and mobile hybrid C-arm scanner for simultaneous nuclear and fluoroscopic image guidance.

Dietze M, Kunnen B, Brontsema F, Ramaekers P, Beijst C, Afifah M Eur Radiol. 2021; 32(1):517-523.

PMID: 34132877 PMC: 8660732. DOI: 10.1007/s00330-021-08023-4.

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