Assessing the qualitative and quantitative impacts of simple two-class vs multiple tissue-class MR-based attenuation correction for cardiac PET/MR.

TitleAssessing the qualitative and quantitative impacts of simple two-class vs multiple tissue-class MR-based attenuation correction for cardiac PET/MR.
Publication TypeJournal Article
Year of Publication2021
AuthorsRobson PM, Vergani V, Benkert T, Trivieri MGiovanna, Karakatsanis NA, Abgral R, Dweck MR, Moreno PR, Kovacic JC, Block KTobias, Fayad ZA
JournalJ Nucl Cardiol
Volume28
Issue5
Pagination2194-2204
Date Published2021 10
ISSN1532-6551
KeywordsAged, Cohort Studies, Female, Fluorodeoxyglucose F18, Heart, Humans, Magnetic Resonance Angiography, Male, Middle Aged, Positron Emission Tomography Computed Tomography, Radiopharmaceuticals
Abstract

BACKGROUND: Hybrid PET/MR imaging has significant potential in cardiology due to its combination of molecular PET imaging and cardiac MR. Multi-tissue-class MR-based attenuation correction (MRAC) is necessary for accurate PET quantification. Moreover, for thoracic PET imaging, respiration is known to lead to misalignments of MRAC and PET data that result in PET artifacts. These factors can be addressed by using multi-echo MR for tissue segmentation and motion-robust or motion-gated acquisitions. However, the combination of these strategies is not routinely available and can be prone to errors. In this study, we examine the qualitative and quantitative impacts of multi-class MRAC compared to a more widely available simple two-class MRAC for cardiac PET/MR.

METHODS AND RESULTS: In a cohort of patients with cardiac sarcoidosis, we acquired MRAC data using multi-echo radial gradient-echo MR imaging. Water-fat separation was used to produce attenuation maps with up to 4 tissue classes including water-based soft tissue, fat, lung, and background air. Simultaneously acquired 18F-fluorodeoxyglucose PET data were subsequently reconstructed using each attenuation map separately. PET uptake values were measured in the myocardium and compared between different PET images. The inclusion of lung and subcutaneous fat in the MRAC maps significantly affected the quantification of 18F-fluorodeoxyglucose activity in the myocardium but only moderately altered the appearance of the PET image without introduction of image artifacts.

CONCLUSION: Optimal MRAC for cardiac PET/MR applications should include segmentation of all tissues in combination with compensation for the respiratory-related motion of the heart. Simple two-class MRAC is adequate for qualitative clinical assessment.

DOI10.1007/s12350-019-02002-5
Alternate JournalJ Nucl Cardiol
PubMed ID31898004
PubMed Central IDPMC7329599
Grant ListFS/14/78/31020 / BHF_ / British Heart Foundation / United Kingdom
R01 HL071021 / HL / NHLBI NIH HHS / United States

Weill Cornell Medicine
Department of Radiology
525 East 68th Street New York, NY 10065