Partial scan artifact reduction (PSAR) for the assessment of cardiac perfusion in dynamic phase-correlated CT

Cardiac CT achieves its high temporal resolution by lowering the scan range from 2π to π plus fan.angle (partial scan). This, however, introduces CT-value variations depending on the start angle of the π range. These partial scan artifacts are in the order of a few HU and prevent the quantitative ev...

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Bibliographic Details
Published in2008 IEEE Nuclear Science Symposium Conference Record pp. 5203 - 5209
Main Authors Stenner, Philip, Schmidt, Bernhard, Bruder, Herbert, Flohr, Thomas, Kachelriess, Marc
Format Conference Proceeding
LanguageEnglish
Published IEEE 01.10.2008
Subjects
Computed tomography
Data mining
Energy resolution
Fluctuations
Heart
Heuristic algorithms
Image reconstruction
myocardial perfusion measurements
Myocardium
Nuclear and plasma sciences
partial scan artifacts
Spatial resolution
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Summary:Cardiac CT achieves its high temporal resolution by lowering the scan range from 2π to π plus fan.angle (partial scan). This, however, introduces CT-value variations depending on the start angle of the π range. These partial scan artifacts are in the order of a few HU and prevent the quantitative evaluation of perfusion measurements. Our PSAR algorithm corrects a dynamic phase-correlated scan without a priori information. In general a full scan does not suffer from partial scan artifacts since all projections in [0; 2π] contribute to the data. In order to maintain the optimum temporal resolution and the phase-correlation PSAR creates an artificial full scan p n F by projection-wise averaging a set of neighboring partial scans p n P from the same perfusion examination (typically N = 30 phase-correlated partial scans distributed over 20 s). Corresponding to the angular range of each partial scan we extract virtual partial scan data sets p n V from the artificial full scan p n F . A standard reconstruction yields the corresponding images f n P , f n F and f n V . Subtracting the artificial full scan image f n F from the virtual partial scan image f n V yields an artifact image that can be used to correct the original partial scan image: f n C = f n P − (f n V − f n F ). Our method has been validated with a simulated semi-anthropomorphic heart phantom and with clinical scans. For the simulated case real full scans have been performed to provide theoretical reference values. The improvement of the root mean square errors between the full scans and the partial, respectively corrected scans, is up to 54%. The phase-correlated data now appear accurate enough for a quantitative analysis of cardiac perfusion.
ISBN:1424427142
9781424427147
ISSN:1082-3654
2577-0829
DOI:10.1109/NSSMIC.2008.4774407