Literature DB >> 35506130

Compressed Sensing Cardiac Cine Imaging Compared with Standard Balanced Steady-State Free Precession Cine Imaging in a Pediatric Population.

Francesco Secchi1, Aurelio Secinaro1, Davide Curione1, Paolo Ciliberti1, Caterina Beatrice Monti1, Davide Capra1, Veronica Bordonaro1, Paolo Ciancarella1, Teresa Pia Santangelo1, Carmela Napolitano1, Dolores Ferrara1, Marco Alfonso Perrone1.   

Abstract

Purpose: To compare real-time compressed sensing (CS) and standard balanced steady-state free precession (bSSFP) cardiac cine imaging in children. Materials and
Methods: Twenty children (mean age, 15 years ± 5 [SD], range, 7-21 years; 10 male participants) with biventricular congenital heart disease (n = 11) or cardiomyopathy (n = 9) were prospectively included. Examinations were performed with 1.5-T imagers by using both bSSFP and CS sequences in all participants. Quantification of ventricular volumes and function was performed for all images by two readers blinded to patient diagnosis and type of sequence. Values were correlated with phase-contrast flow measurements by one reader. Intra- and interreader agreement were analyzed.
Results: There were no significant differences between ventricular parameters measured on CS compared with those of bSSFP (P > .05) for reader 1. Only ejection fraction showed a significant difference (P = .02) for reader 2. Intrareader agreement was considerable for both sequences (bSSFP: mean difference range, +1 to -2.6; maximum CI, +7.9, -13; bias range, 0.1%-4.1%; intraclass correlation coefficient [ICC] range, 0.931-0.997. CS: mean difference range, +7.4 to -5.6; maximum CI, +37.2, -48.8; bias range, 0.5%-7.5%; ICC range, 0.717-0.997). Interreader agreement was acceptable but less robust, especially for CS (bSSFP: mean difference range, +2.6 to -5.6; maximum CI, +60.7, -65.3; bias range, 1.6%-6.2%; ICC range, 0.726-0.951. CS: mean difference range, +10.7 to -9.1; maximum CI, +87.5, -84.6; bias range, 1.1%-17.3%; ICC range, 0.509-0.849). The mean acquisition time was shorter for CS (20 seconds; range, 17-25 seconds) compared with that for bSSFP (160 seconds; range, 130-190 seconds) (P < .001).
Conclusion: CS cardiac cine imaging provided equivalent ventricular volume and function measurements with shorter acquisition times compared with those of bSSFP and may prove suitable for the pediatric population.Keywords: Compressed Sensing, Balanced Steady-State Free Precession, Cine Imaging, Cardiovascular MRI, Pediatrics, Cardiac, Heart, Cardiomyopathies, Congenital, Segmentation© RSNA, 2022.
© 2022 by the Radiological Society of North America, Inc.

Entities:  

Keywords:  Balanced Steady-State Free Precession; Cardiac; Cardiomyopathies; Cardiovascular MRI; Cine Imaging; Compressed Sensing; Congenital; Heart; Pediatrics; Segmentation

Year:  2022        PMID: 35506130      PMCID: PMC9059096          DOI: 10.1148/ryct.210109

Source DB:  PubMed          Journal:  Radiol Cardiothorac Imaging        ISSN: 2638-6135


  25 in total

Review 1.  Compressed sensing MRI: a review of the clinical literature.

Authors:  Oren N Jaspan; Roman Fleysher; Michael L Lipton
Journal:  Br J Radiol       Date:  2015-09-24       Impact factor: 3.039

2.  Multicenter review: role of cardiovascular magnetic resonance in diagnostic evaluation, pre-procedural planning and follow-up for patients with congenital heart disease.

Authors:  Nicolò Schicchi; Aurelio Secinaro; Giuseppe Muscogiuri; Paolo Ciliberti; Benedetta Leonardi; Teresa Santangelo; Carmela Napolitano; Giacomo Agliata; Maria Chiara Basile; Francesca Guidi; Paolo Tomà; Andrea Giovagnoni
Journal:  Radiol Med       Date:  2015-12-11       Impact factor: 3.469

Review 3.  Utility of Cardiac Magnetic Resonance Imaging in the Management of Adult Congenital Heart Disease.

Authors:  Giuseppe Muscogiuri; Aurelio Secinaro; Paolo Ciliberti; Megan Fuqua; Arni Nutting
Journal:  J Thorac Imaging       Date:  2017-07       Impact factor: 3.000

Review 4.  Statistical power and sample size calculations: A primer for pediatric surgeons.

Authors:  Steven J Staffa; David Zurakowski
Journal:  J Pediatr Surg       Date:  2019-05-16       Impact factor: 2.545

5.  Real-time SPARSE-SENSE cine MR imaging in atrial fibrillation: a feasibility study.

Authors:  Juliane Goebel; Felix Nensa; Haemi P Schemuth; Stefan Maderwald; Harald H Quick; Thomas Schlosser; Kai Nassenstein
Journal:  Acta Radiol       Date:  2016-01-01       Impact factor: 1.990

6.  Validation of 3D echocardiographic assessment of left ventricular volumes, mass, and ejection fraction in neonates and infants with congenital heart disease: a comparison study with cardiac MRI.

Authors:  Mark K Friedberg; Xioahong Su; Wayne Tworetzky; Brian D Soriano; Andrew J Powell; Gerald R Marx
Journal:  Circ Cardiovasc Imaging       Date:  2010-09-20       Impact factor: 7.792

7.  Three-dimensional echocardiographic measurement of right ventricular volume in children with congenital heart disease validated by magnetic resonance imaging.

Authors:  D P Papavassiliou; W J Parks; K L Hopkins; D A Fyfe
Journal:  J Am Soc Echocardiogr       Date:  1998-08       Impact factor: 5.251

Review 8.  Normal values for cardiovascular magnetic resonance in adults and children.

Authors:  Nadine Kawel-Boehm; Alicia Maceira; Emanuela R Valsangiacomo-Buechel; Jens Vogel-Claussen; Evrim B Turkbey; Rupert Williams; Sven Plein; Michael Tee; John Eng; David A Bluemke
Journal:  J Cardiovasc Magn Reson       Date:  2015-04-18       Impact factor: 5.364

9.  Real-time assessment of right and left ventricular volumes and function in children using high spatiotemporal resolution spiral bSSFP with compressed sensing.

Authors:  Jennifer A Steeden; Grzegorz T Kowalik; Oliver Tann; Marina Hughes; Kristian H Mortensen; Vivek Muthurangu
Journal:  J Cardiovasc Magn Reson       Date:  2018-12-06       Impact factor: 5.364

10.  Interpolated compressed sensing for 2D multiple slice fast MR imaging.

Authors:  Yong Pang; Xiaoliang Zhang
Journal:  PLoS One       Date:  2013-02-08       Impact factor: 3.240
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