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EJNMMI Research
Published in: EJNMMI Research 1/2019

Open Access 01-12-2019 | Original research

Evaluation of data-driven respiratory gating waveforms for clinical PET imaging

Authors: Matthew D. Walker, Andrew J. Morgan, Kevin M. Bradley, Daniel R. McGowan

Published in: EJNMMI Research | Issue 1/2019

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Abstract

Background

We aimed to evaluate the clinical robustness of a commercially developed data-driven respiratory gating algorithm based on principal component analysis, for use in routine PET imaging.

Methods

One hundred fifty-seven adult FDG PET examinations comprising a total of 1149 acquired bed positions were used for the assessment. These data are representative of FDG scans currently performed at our institution. Data were acquired for 4 min/bed position (3 min/bed for legs). The data-driven gating (DDG) algorithm was applied to each bed position, including those where minimal respiratory motion was expected. The algorithm provided a signal-to-noise measure of respiratory-like frequencies within the data, denoted as R. Qualitative evaluation was performed by visual examination of the waveforms, with each waveform scored on a 3-point scale by two readers and then averaged (score S of 0 = no respiratory signal, 1 = some respiratory-like signal but indeterminate, 2 = acceptable signal considered to be respiratory). Images were reconstructed using quiescent period gating and compared with non-gated images reconstructed with a matched number of coincidences. If present, the SUVmax of a well-defined lesion in the thorax or abdomen was measured and compared between the two reconstructions.

Results

There was a strong (r = 0.86) and significant correlation between R and scores S. Eighty-six percent of waveforms with R ≥ 15 were scored as acceptable for respiratory gating. On average, there were 1.2 bed positions per patient examination with R ≥ 15. Waveforms with high R and S were found to originate from bed positions corresponding to the thorax and abdomen: 90% of waveforms with R ≥ 15 had bed centres in the range 5.6 cm superior to 27 cm inferior from the dome of the liver. For regions where respiratory motion was expected to be minimal, R tended to be < 6 and S tended to be 0. The use of DDG significantly increased the SUVmax of focal lesions, by an average of 11% when considering lesions in bed positions with R ≥ 15.

Conclusions

The majority of waveforms with high R corresponded to the part of the patient where respiratory motion was expected. The waveforms were deemed suitable for respiratory gating when assessed visually, and when used were found to increase SUVmax in focal lesions.
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Metadata
Title
Evaluation of data-driven respiratory gating waveforms for clinical PET imaging
Authors
Matthew D. Walker
Andrew J. Morgan
Kevin M. Bradley
Daniel R. McGowan
Publication date
01-12-2019
Publisher
Springer Berlin Heidelberg
Published in
EJNMMI Research / Issue 1/2019
Electronic ISSN: 2191-219X
DOI
https://doi.org/10.1186/s13550-018-0470-9

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