Clinical application of free-breathing 3D whole heart late gadolinium enhancement cardiovascular magnetic resonance with high isotropic spatial resolution using Compressed SENSE

Cardiovascular magnetic resonance (CMR) late gadolinium enhancement (LGE) imaging has become the non-invasive standard of reference for assessment of myocardial viability in different cardiac diseases [1‐3]. In ischemic cardiomyopathy, accurate assessment of the extent of infarct transmurality by LGE as a predictive indicator for prognosis and recovery of contractile function guides revascularisation therapy [4‐7]. For non-ischemic cardiomyopathies, LGE enables differentiation among diseases based on different patterns of hyperenhancement [1, 8‐10].

Traditionally, a two-dimensional (2D) inversion-recovery fast spoiled gradient-echo sequence is applied for LGE imaging with manually chosen inversion time (TI) to null the signal of healthy myocardium [1, 11]. However, 2D acquisition requires multiple breath-holds in pre-defined orientations with associated disadvantages such as non-isotropic resolution with thick slices, incomplete coverage due to slice gaps, low signal-to-noise ratio (SNR), and slice misregistration [11, 12].

The recent development of three-dimensional (3D) imaging allows data acquisition of the entire heart in a single scan without interslice gaps [3, 13]. In this context, accelerated and extended breath-hold approaches have been proposed [14, 15]. However, these techniques are associated with similar constraints on SNR and spatial resolution as 2D LGE since they can only provide highly anisotropic readouts [14, 15]. Further, they are hampered by long breath-hold duration, hence widely unsuitable for clinical routine [15, 16]. When applying different techniques for navigator-gating such as respiratory bellows signal [17], respiratory self-navigation [18‐20], and diaphragmatic pencil-beam navigation [3] to reduce respiratory artifacts, 3D LGE can be performed during free-breathing enabling 3D assessment of the whole heart with higher spatial resolution [21‐24]. Nevertheless, free-breathing 3D LGE techniques suffer from long imaging time, especially when aiming to provide readouts with submillimetre high isotropic spatial resolution [24‐26]. Consequently, drawbacks like susceptibility to varying heart rate and respiratory motion as well as changing accumulation of contrast agent in injured myocardium with inadequate nulling of healthy tissue question their feasibility and usefulness in clinical routine [27, 28].

Recently, Compressed SENSE was introduced, which combines compressed sensing and parallel imaging using SENSitivity Encoding (SENSE) [29‐31]. Compressed SENSE enables image-acquisition acceleration currently not achievable by compressed sensing or parallel imaging alone and has shown promising results in musculoskeletal and cardiovascular imaging [29‐36].

The purpose of this study was to investigate the clinical potential of Compressed SENSE accelerated free-breathing 3D whole heart LGE with high isotropic spatial resolution compared to standard breath-hold LGE imaging for assessment of left ventricular (LV) viability.

In this study, we investigated the clinical potential of Compressed SENSE accelerated free-breathing 3D whole heart LGE with high isotropic spatial resolution compared to standard breath-hold LGE for assessment of LV viability. The major findings of the study are the following: 1. Free-breathing LGE enabled improved depiction of small hyperenhanced lesions of the LV myocardium, in particular of non-ischemic localization, and required a shorter scan time compared to breath-hold LGE. 2. Free-breathing LGE provided good to excellent results for diagnostic confidence, artifacts, and image quality in about 80% of examinations with the latter being independent of heart rate.

Given aforementioned limitations of breath-hold LGE, free-breathing LGE techniques are of particular interest in research and clinical practice. Previous studies have proposed different free-breathing approaches enabling high spatial resolution at 1.5 T and 3 T [18, 21‐23, 25, 26]. However, long acquisition time remains one of the main limitations for the majority of techniques. In this context, Andreu et al. reported scan times of 16.4 ± 7.2 min (for 1.4 mm³ reconstructed resolution) [25], Bizino et al. of 09:34 ± 03:04 min (0.9 mm³ reconstructed resolution) [26], and Lintingre et al. of 8–10 min (1.25 × 1.25 × 2.5 mm acquired resolution) [24]. Bratis et al. introduced respiratory self-navigation for whole heart LGE in 03:52 min with 2.0 mm³ acquired and 1.0 mm³ reconstructed resolution [18] whereas Kino et al. demonstrated the use of phase-sensitive inversion-recovery (PSIR) for free-breathing LGE with 2.0 mm³ acquired resolution in 06:10 ± 02:56 min [23]. Akcakaya et al. [21] and Basha et al. [22], respectively, proposed another promising technique for free-breathing LGE providing the highest isotropic acquisition to date (varying between 1.0 and 1.7 mm³ depending on patient’s size and heart rate) in approximately 4 to 6 min (depending on applied acceleration factor) using LOw-dimensional-structure Self-learning and Thresholding (LOST). However, required reconstruction of acquired data using an offline central processing unit cluster, lasting about an hour, limits its immediate application in clinical routine and feasibility for other centers [21, 22].

In the present study, proposed Compressed SENSE accelerated free-breathing 3D whole heart LGE sequence enables high isotropic resolution in acquired (fixed 1.4 mm³, no adaptation to patient’s specifics required) and reconstructed (0.7 mm³) voxel size in an acceptable scan time (04:33 ± 01:17 min) without extensive postprocessing. Image reconstruction took about 30 s and was performed with standard hardware provided by the manufacturer of the CMR system.

As previously shown when comparing free-breathing to breath-hold LGE, readers detected more smaller hyperenhanced lesions using free-breathing LGE, mostly because of its contiguous, high-resolution acquisition in through-plane direction and because breath-hold LGE suffers from partial volume effect due to its lower voxel size [22‐24, 39]. Although a voxel partially contains spins with high signal intensity, an overall elimination of high signal intensity of the voxel may occur if it is also occupied by spins with low signal intensity [39]. Therefore, small hyperenhanced lesions are more difficult to detect and to distinguish from another as two separate findings in breath-hold LGE. In breath-hold sequences, the partial volume effect may also lead to impaired detection of patchy mid-myocardial and, in particular, subepicardial lesions. In contrast, higher resolution of free-breathing LGE with possible 3D assessment facilitates their detection since it enables sufficient differentiation from adjoining structures.

Visually, the signal appearance of free-breathing LGE was lower compared to breath-hold LGE, which might have different reasons except for the distinct sequence details with free-breathing LGE being acquired at a later time point after administration of contrast agent and data acquisition comprising a comparable large timeframe. However, no quantitative SNR comparison was carried out in the current work because of the iterative and wavelet denoising based reconstruction used for free-breathing LGE, which is dependent on the actual image content and results in different numbers of iterations or denoising steps for different images interfering with absolute SNR estimations. The visually reduced signal of the blood pool improved detection of subendocardial lesions in this study, mostly due to visually moderately increased differentiation between blood and injured myocardium, facilitating depiction of scars at this localization, comparable to dark-blood LGE [40, 41].

Free-breathing LGE enabled sufficient detection of intracardiac thrombi and pericardial hyperenhancement. Given the low number of patients in the present study presenting respective pathologies, these findings may carry a bias and should warrant future investigations, including assessment of atrial and right ventricular LGE.

Free-breathing LGE did not fully yield the same high scores for image quality, artifacts, and diagnostic confidence as breath-hold LGE. These differences may be due to acquiring the free-breathing sequence at the end of examination when potential contrast washout leads to a change in optimal TI and patients tend to be exhausted and may present irregular breathing patterns. However, there was no statistical difference regarding diagnostic confidence between both techniques and free-breathing LGE achieved good/excellent image quality in 80% of cases. An earlier acquisition of free-breathing LGE may lead to an improvement of image quality and reduction of artifacts. Further, application of PSIR might reduce effects of dynamic changes of TI during examination [19, 23].

In free-breathing LGE, elevated BMI led to impaired image quality and more pronounced artifacts, while in breath-hold LGE, BMI had no impact on image quality and artifacts. It is of note, however, that diagnostic confidence of free-breathing was unimpaired by BMI. A possible explanation may be that the loss in image quality is counterbalanced by the improved post-processing options for free-breathing LGE such as multiplanar reformation. Further, increased heart rate led to decreased diagnostic confidence and increased artifacts for free-breathing LGE and affected artifacts as well as image quality of breath-hold LGE. However, increased heart rate did not lead to impaired image quality for free-breathing LGE. These findings differ to the study by Basha et al. investigating free-breathing LGE using LOST, for which increased heart rate was associated with significant decreased image quality [22]. The shorter shot duration of free-breathing LGE compared to breath-hold LGE (150 vs. 170 ms) may explain the findings of the present study.

Besides being acquired without any acceleration technique, the longer scan time of breath-hold LGE in this study is mostly due to patient recovery time between breath-holds and repetition of scans if the patient was unable to perform the breath-hold or if planning was not accurately. In contrast, free-breathing LGE can be performed in patients with poor compliance unable to tolerate repetitive breath-holds, proves to be widely user-independent, and enables post-acquisition reformatting in any arbitrary orientation with identical image quality as original transaxial images using multiplanar tools.

Free-breathing Compressed SENSE accelerated 3D whole heart LGE with high isotropic spatial resolution provides good to excellent image quality in 80% of scans independent of heart rate while enabling improved depiction of small hyperenhanced lesions with in particular non-ischemic localization of the LV myocardium in a shorter scan time than standard breath-hold LGE. Given its fast acquisition, wider user-independence, and omission of breath‐holds, Compressed SENSE accelerated free-breathing LGE has the potential to facilitate clinical workflow.