Building a comprehensive cardiovascular magnetic resonance exam on a commercial 0.55 T system: A pictorial essay on potential applications

Background Contemporary advances in low-field magnetic resonance imaging systems can potentially widen access to cardiovascular magnetic resonance (CMR) imaging. We present our initial experience in building a comprehensive CMR protocol on a commercial 0.55 T system with a gradient performance of 26 mT/m amplitude and 45 T/m/s slew rate. To achieve sufficient image quality, we adapted standard imaging techniques when possible, and implemented compressed-sensing (CS) based techniques when needed in an effort to compensate for the inherently low signal-to-noise ratio at lower field strength. Methods A prototype CMR exam was built on an 80 cm, ultra-wide bore commercial 0.55 T MR system. Implementation of all components aimed to overcome the inherently lower signal of low-field and the relatively longer echo and repetition times owing to the slower gradients. CS-based breath-held and real-time cine imaging was built utilizing high acceleration rates to meet nominal spatial and temporal resolution recommendations. Similarly, CS 2D phase-contrast cine was implemented for flow. Dark-blood turbo spin echo sequences with deep learning based denoising were implemented for morphology assessment. Magnetization-prepared single-shot myocardial mapping techniques incorporated additional source images. CS-based dynamic contrast-enhanced imaging was implemented for myocardial perfusion and 3D MR angiography. Non-contrast 3D MR angiography was built with electrocardiogram-triggered, navigator-gated magnetization-prepared methods. Late gadolinium enhanced (LGE) tissue characterization methods included breath-held segmented and free-breathing single-shot imaging with motion correction and averaging using an increased number of source images. Proof-of-concept was demonstrated through porcine infarct model, healthy volunteer, and patient scans. Results Reasonable image quality was demonstrated for cardiovascular structure, function, flow, and LGE assessment. Low-field afforded utilization of higher flip angles for cine and MR angiography. CS-based techniques were able to overcome gradient speed limitations and meet spatial and temporal resolution recommendations with imaging times comparable to higher performance scanners. Tissue mapping and perfusion imaging require further development. Conclusion We implemented cardiac applications demonstrating the potential for comprehensive CMR on a novel commercial 0.55 T system. Further development and validation studies are needed before this technology can be applied clinically.

[1]  R. Ahmad,et al.  Technical Report (v1.0)--Pseudo-random Cartesian Sampling for Dynamic MRI , 2022, 2206.03630.

[2]  O. Simonetti,et al.  T2 mapping in myocardial disease: a comprehensive review , 2022, Journal of Cardiovascular Magnetic Resonance.

[3]  O. Simonetti,et al.  Sustainable low-field cardiovascular magnetic resonance in changing healthcare systems , 2022, European heart journal. Cardiovascular Imaging.

[4]  P. Kellman,et al.  Evaluation of Myocardial Infarction by Cardiovascular Magnetic Resonance at 0.55-T Compared to 1.5-T. , 2021, JACC. Cardiovascular imaging.

[5]  M. Francone,et al.  The current landscape of imaging recommendations in cardiovascular clinical guidelines: toward an imaging-guided precision medicine , 2020, La radiologia medica.

[6]  P. Kellman,et al.  A comparison of cine CMR imaging at 0.55 T and 1.5 T , 2020, Journal of Cardiovascular Magnetic Resonance.

[7]  O. Simonetti,et al.  Assessment of cardiac function, blood flow and myocardial tissue relaxation parameters at 0.35 T , 2020, NMR in biomedicine.

[8]  E. Nagel,et al.  Standardized cardiovascular magnetic resonance imaging (CMR) protocols: 2020 update , 2020, Journal of Cardiovascular Magnetic Resonance.

[9]  Waqas Majeed,et al.  Opportunities in Interventional and Diagnostic Imaging by Using High-performance Low-Field-Strength MRI. , 2019, Radiology.

[10]  anonymous,et al.  Comprehensive review , 2019 .

[11]  A. Webb,et al.  Low‐field MRI: An MR physics perspective , 2019, Journal of magnetic resonance imaging : JMRI.

[12]  K. Sung,et al.  Cardiac balanced steady-state free precession MRI at 0.35 T: a comparison study with 1.5 T. , 2018, Quantitative imaging in medicine and surgery.

[13]  O. Simonetti,et al.  Low-Field Cardiac Magnetic Resonance Imaging: A Compelling Case for Cardiac Magnetic Resonance's Future. , 2017, Circulation. Cardiovascular imaging.

[14]  Eike Nagel,et al.  T1 Mapping in Characterizing Myocardial Disease: A Comprehensive Review. , 2016, Circulation research.

[15]  Thomas Witzel,et al.  Low-Cost High-Performance MRI , 2015, Scientific Reports.

[16]  P. Schniter,et al.  Iteratively Reweighted $\ell_1$ Approaches to Sparse Composite Regularization , 2015, IEEE Transactions on Computational Imaging.

[17]  John P Mugler,et al.  Optimized three‐dimensional fast‐spin‐echo MRI , 2014, Journal of magnetic resonance imaging : JMRI.

[18]  Michael Elad,et al.  ESPIRiT—an eigenvalue approach to autocalibrating parallel MRI: Where SENSE meets GRAPPA , 2014, Magnetic resonance in medicine.

[19]  P. Alboni,et al.  Initial Clinical Evaluation , 2013 .

[20]  Michael Schacht Hansen,et al.  Gadgetron: An open source framework for medical image reconstruction , 2013, Magnetic resonance in medicine.

[21]  K. Scheffler,et al.  MR-imaging of the thoracic aorta: 3D-ECG- and respiratory-gated bSSFP imaging using the CLAWS algorithm versus contrast-enhanced 3D-MRA. , 2012, European journal of radiology.

[22]  P. Weale,et al.  Unenhanced MR angiography of the thoracic aorta: initial clinical evaluation. , 2008, AJR. American journal of roentgenology.

[23]  D. Donoho,et al.  Sparse MRI: The application of compressed sensing for rapid MR imaging , 2007, Magnetic resonance in medicine.

[24]  Orlando Simonetti,et al.  T2‐weighted cardiovascular magnetic resonance imaging , 2007, Journal of magnetic resonance imaging : JMRI.

[25]  Andrew C Larson,et al.  Motion‐corrected free‐breathing delayed enhancement imaging of myocardial infarction , 2005, Magnetic resonance in medicine.

[26]  C. Meier,et al.  Cardiovascular flow measurement with phase-contrast MR imaging: basic facts and implementation. , 2002, Radiographics : a review publication of the Radiological Society of North America, Inc.

[27]  O. Simonetti,et al.  An improved MR imaging technique for the visualization of myocardial infarction. , 2001, Radiology.

[28]  O. Simonetti,et al.  MR angiography of the thoracic aorta with an electrocardiographically triggered breath-hold contrast-enhanced sequence. , 2000, Radiographics : a review publication of the Radiological Society of North America, Inc.

[29]  V B Ho,et al.  Gadolinium‐enhanced 3D magnetic resonance angiography of the thoracic vessels , 1999, Journal of magnetic resonance imaging : JMRI.

[30]  N L Kelekis,et al.  HASTE MR imaging: Description of technique and preliminary results in the abdomen , 1996, Journal of magnetic resonance imaging : JMRI.