Current limitations of coronary magnetic resonance angiography (MRA) include a suboptimal signal-to-noise ratio (SNR), which limits spatial resolution and the ability to visualize distal and branch vessel coronary segments. Improved SNR is expected at higher field strengths, which may provide improved spatial resolution. However, a number of potential adverse effects on image quality have been reported at higher field strengths. The limited availability of high-field systems equipped with cardiac-specific hardware and software has previously precluded successful in vivo human high-field coronary MRA data acquisition. In the present study we investigated the feasibility of human coronary MRA at 3.0T in vivo. Most recent studies suggest that free-breathing 3D coronary magnetic resonance angiography (MRA) at 1.5T is a valuable tool for the noninvasive assessment of significant proximal to mid coronary artery disease (1). Still, the ability to visualize and assess more distal or branching vessels is desirable, and quantitative grading of the stenoses remains an ultimate goal. Limitations of current coronary MRA approaches include residual motion and signal-tonoise (SNR) constraints. In theory, SNR is directly related to the strength (B 0 ) of the static magnetic field. Thus, improved SNR can be expected from the use of magnets with higher magnetic field strength, for which 3.0T systems have recently been approved for clinical use. However, together with the limited availability of higher-field systems equipped for cardiac applications, other potential impediments (2) include increased susceptibility artifacts, reduced T * 2 (3,4), increased T 1 , radiofrequency (RF) field distortions (5), and changed tissue dielectric constants or body dielectric resonances (6,7). Further, at higher field strengths, increased RF deposition may remove flexibility for general sequence design, and efficient myocardial motion suppression (reliable R-wave triggering) becomes more challenging due the amplified magneto-hydrodynamic (MHD) effects (8). Recent progress in 3.0T hardware (vector ECG (VECG) (8), short-bore magnets, dedicated surface receive coils (5), and body send coils) and the adaptation of cardiac-specific software (T 2 Prep (9) and 2D selective real-time navigators (10)) for 3.0T has made it possible to implement analogous 1.5T coronary MRA methodology on a whole-body 3.0T system. Therefore, we sought to investigate the feasibility of coronary MRA data acquisition at 3.0T. The first in vivo results obtained in nine consecutive healthy adult human subjects are presented.
METHODSCoronary MRA was implemented on a commercial actively shielded whole-body compact magnet (Intera 3.0T, 157 cm magnet length, 60 cm internal diameter; Philips Medical Systems, Best, The Netherlands) equipped with a MASTER ® gradient system (30 mT; 150 mT/m/ms), a VECG module (8), and Release 8.1.3 cardiac scanner software. A prototype body send coil and a prototype sixelement cardiac synergy receive coil were used. Nine consecutive healthy adult human ...
