Quantifying fat replacement of muscle by quantitative MRI in muscular dystrophy

All muscular dystrophies (MD) are rare orphan diseases, characterized by progressive muscle weakness resulting in functional disability. While the causes for muscle weakness vary between different MDs, they share common histological features, including fibrosis, muscle edema, and fat replacement of muscle tissue. More than 70 distinct variants have been identified, some becoming apparent in early childhood with rapid progression while others are not detected until adulthood with a much slower timescale of progression. Among the muscular dystrophies, Duchenne muscular dystrophy (DMD) is the most common form affecting 1 in 3500–6000 male births [1, 2], tending to show first symptoms at 3–5 years of age and rapid progression leading to loss of ambulation between 10 and 15 years. Deterioration of respiratory function and cardiomyopathy occur in DMD and in many other MDs.

Planning clinical trials of therapy in MDs is challenging for three reasons. First, the progression of the disease does not always follow a linear course when physical abilities are measured. Longitudinal studies using clinical measurements in DMD show an improvement of gross and fine motor function up to the age of 7, a plateau phase up to the age of 10 followed by a phase of rapid decline during which free ambulation is lost [3, 4]. Second, recruitment in rare disease cohorts for large clinical trials is difficult. Third, clinical assessment is dependent on cooperation (especially in children) and the measurements required differ between ambulant and non-ambulant patients.

Therefore, it is essential to have outcome measures that are less dependent on patient cooperation and motivation while being sufficiently sensitive to measure treatment effects even in small and highly heterogeneous patient populations. Quantitative muscle MRI (qMRI) can provide such an outcome measure, as it is non-invasive and can generate a wide range of imaging contrasts over large volumes of muscle. As such, it can visualize and quantify the major hallmarks of muscle degeneration in MDs: muscle hypertrophy and atrophy, muscle edema and inflammation, and the replacement of muscle tissue by fat tissue. Histologically, the content of the muscle fibres is progressively replaced by lipid, resulting in a fatty tissue. On MRI, the overall outline, shape, structure, and appearance of the muscle groups are often preserved despite the extensive fatty tissue content. In contrast to functional scores obtained by physical assessment, qMRI is less biased by patients or observers. Excellent reproducibility of qMRI has been demonstrated in healthy volunteers as well as in patients [5, 6]. In particular, qMRI of fat replacement has the potential to be very valuable as an outcome measure in clinical trials as it has been shown to be more sensitive than clinical evaluation in detecting disease progression [7‐12] and effect sizes of fat replacement measured by qMRI are much greater than those of commonly used clinical scores [10, 13]. Thus, when using qMRI of fat replacement as an end-point to demonstrate the effectiveness of a putative novel treatment, the number of patients required is markedly reduced [9, 10]. Although invasive muscle biopsy is sometimes undertaken (often to determine membrane protein expression) and fat content could be estimated from it, it is an unreliable method of measuring fat content due to the small sample volume, the heterogeneous nature of the fat replacement across muscle groups, and the limitations on repeating biopsy in longitudinal studies.

In this review, we review the MRI sequences used to quantify fat replacement of skeletal muscle by imaging and detail the important factors that need to be taken into account to produce accurate results (“Quantitative fat fraction imaging measurements: how is it done?”), compare these with magnetic resonance spectroscopy methods (“T2-corrected spectroscopy to measure muscle fat content”), and provide a survey of longitudinal and cross-sectional studies of muscular dystrophy which have employed variants of these methods (“Studies which have used quantitative fat fraction measurements in muscular dystrophy”). We then consider the quality assurance required for using these methods (“Quality assurance”) and practical considerations for patient positioning, slice prescription, and data analysis (“Patient placement, acquisition time and scan acceleration, practical issues and segmentation”). Most MR vendors have developed products for measuring liver steatosis and we discuss the necessary considerations for using these in skeletal muscle (“Vendor implementations of quantitative protocols to measure PDFF”).

Traditionally, spectroscopic methods have been used to determine changes in lipid content (both intramyocellular (IMCL) and extramyocellular (EMCL) lipids), lipid saturation, and major muscle metabolites including trimethyl ammonium compounds (e.g., choline and carnitine), creatine, carnosine, acylcarnitines, and lactate [26]. Proton MRS can also be used to determine absolute tissue water and lipid content with high accuracy and reproducibility using both internal and external referencing methods [27, 28]. In the presence of fibrosis and/or edema, commonly found in muscular dystrophies, absolute water content can only be obtained using an external reference method. However, this is currently not commonly applied. As described above for the imaging methods, corrections for T2 and T1 relaxation need to be applied for the individual metabolites to calculate a PDFF. In addition, the relative contribution of each resonance to the overall lipid content signal (Fig. 5) needs to be determined. MRS determined fat fractions have become the standard against which to validate PDFF calculations based on imaging techniques [29‐31]. An advantage of MRS is that the fat fraction measurement is made directly from the spectral peaks representing the lipids present. In imaging methods, a fixed lipid spectral model of lipid is necessary. Therefore, information can sometimes be obtained about triglyceride properties with MRS, including the level of carbon chain unsaturation. Whereas high-resolution MR spectroscopy will resolve all the major lipid resonances, at clinical field strengths, individual lipid resonances may need to be deconvolved using a number of different spectral processing techniques [32].

Whereas accelerated multi-voxel spectroscopic imaging techniques have been developed [33] and implemented in muscle [34], the spatial resolution is less than that obtained with MRI and 3D coverage has been limited by long acquisition times. Signal bleeding from neighboring voxels can influence accuracy. Hence, most MRS measures of PDFF have been based on targeted, single voxel spectroscopy [10, 35‐38]. A disadvantage of this localization method is the relatively large voxel size; voxels are typically an order of magnitude bigger in size than MRI, and range from 5 to 20 ml. While this is beneficial from a signal-to-noise ratio (SNR) perspective and enhances greater detection sensitivity to low fat concentrations, it requires accurate voxel placement and extensive operator training. In practice, it is feasible to obtain MR spectra of only a couple of selected muscles within a single examination.

The first study using the Dixon approach to examine the fat content of dystrophic muscle in humans was published in 2008 (Table 2). In the period since then, and particularly in the last 4 years, qMRI methods to quantify fat replacement have been performed in many neuromuscular diseases. It is arguable that this work has been stimulated by the prospect of first-in-human trials in some conditions, particularly DMD. In this section and the adjoining tables, we summarise the studies that have been undertaken.

In the tables, the studies have been categorised in three groups. First, those studies which have been undertaken on a cross-sectional cohort of a particular form of muscular dystrophy are shown in Table 2. These studies have typically been performed to determine the pattern of fat replacement within a cohort and to describe cross-sectional changes with increasing age. The main focus of these studies has been on the dystrophinopathies. In general, the involvement pattern varies considerably between different diseases, where one muscle can be affected early in one disease and be spared until late in the disease process in another. A typical example is the clear involvement of the soleus muscle in the calf of OPMD patients [5], while this muscle is involved only after the tibialis anterior and peroneal muscles become affected in DMD [39]. In addition to differences between diseases, within a particular disease with the same underlying genetic defect, the fatty replacement of individual muscle groups can vary widely, as demonstrated in a multi-national LGMD2I cross-sectional study [40]. Often, the fat fraction measurements from individual muscle groups have been correlated against physical function tests. In general, fat fractions correlate well with functional tests. However, especially in DMD and BMD, it has been shown that contractile properties are disrupted, because specific force is reduced [39, 41]. This type of analysis is performed using Dixon imaging to generate a maximal contractile cross-sectional area and then comparing this to muscle strength measurements.

To prepare qMRI end-points for clinical trials, it is important to know in which muscle groups fatty replacement will progress in the absence of remedial treatment, as rates of progression vary between different muscle groups and over time. The most suitable muscle group to follow will depend on several factors, including age, type of disease, and mechanism of action of the drug. For instance, the efficacy of a drug that is thought to prevent a further increase in fat replacement would be most suitable to test in a muscle and age group where there is a clear increase in fat replacement over time. This muscle group will then have the highest standardized response mean. In DMD, for instance, it has been suggested that between the ages of 9 and 11 years, the vastus lateralis has the highest standardized response mean [10]. On the other hand, a drug that aims to increase muscle mass can also be evaluated in a muscle that does not show fat replacement yet, merely by assessing at the contractile volume. Table 3 outlines the longitudinal studies that have been performed in different muscular dystrophies to measure the rates of progression. Figure 6 shows two examples of fat fraction progression across 1 year in a slow-progressing muscular dystrophy, LGMD2I [11], and one in the more rapidly progressing DMD. Most of these studies have examined the natural history of different diseases, though Arpan et al. 2014 considered the effects of corticosteroid initiation in DMD boys [35] and Carlier et al. 2015 [42] examined the effect of enzyme replacement therapy in late-onset Pompe’s disease. Commonly, these longitudinal studies contrast the increase in muscle fat fraction revealed by qMRI and disease progression demonstrated by the standard physical function tests that are routinely used in clinical care and clinical trials. These studies have demonstrated the enhanced sensitivity of qMRI compared to the existing measurements in both the legs [9‐11, 24, 43] and the arms [8, 44].

Finally, some studies on neuromuscular disease have been performed to investigate new MR methods in these patients, but contain valuable information about patient cohorts (Table 4). These include quality assurance and reproducibility studies [25, 38], work to accelerate image acquisition [43, 45], and correlations between MRI and MRS methods [38, 46].

PDFF as determined by MRI is a derived value based on multiple analytical steps (see “Quantitative fat fraction imaging measurements: how is it done?”). In the pure research environment, each of these steps may be continually monitored and quality controlled using validation data test sets and tissue phantoms. This might not always be possible in the purely clinical environment in which fat/water maps are provided solely as derived DICOM images generated by vendor specific software. As outlined in “What to look out for when processing quantitative fat imaging” and Table 1, techniques for separating fat and water have evolved to include more complex models for lipids as well as to take into T2* relaxation into account. Therefore, it is essential to continually monitor these derived values using known standards to address both the accuracy and precision of the PDFF measurements. Whereas monitoring the precision of the PDFF within a single site may be sufficient, clearly a high level of accuracy is essential for continuity between sites and studies in longitudinal, multi-site trials. During a quality control and validation stage, accuracy and precision can be readily tracked and documented using a combination of MRS and MRI methods on both phantoms and human test subjects. Some clinical trials that use MRI as an end-point now demand that a calibrated test object is scanned before or after every subject visit to monitor system and measurement stability.

Whereas there is currently no standard for quality control measures for PDFF MRI determination, a number of viable options exist.

For leg imaging, the preferred positioning is feet-first supine, with the legs stretched, the patella facing upward, and the ankles in the neutral position (i.e., minimal exo or endorotation). To enhance comfort, a small pillow can be placed under the knees, but the standard leg rest delivered with many scanners will not accommodate this, and the sides of the ankles can be supported with sandbags to prevent unintended movements. In patients with contractures positioning with stretched legs and neutral ankles is not always feasible, and care should be taken to provide optimal support for comfort. Positioning of the upper limb is more challenging, as scan quality is severely reduced at the side of the magnet bore. Experience with scanning of this body part is limited [8, 44, 51, 52], but it will become more common with the need to develop outcome measures for non-ambulant patients. The so-called ‘superman’ position [53] is likely impossible for patients with MDs, and hence, optimal positioning will either be (a) in the fetal position, (b) supine with the upper limb along the trunk, while the trunk is as far off-centre as possible [8, 44, 52, 54], or (c) supine with a dedicated arm rest placed over the abdomen of the patient: all published studies in DMD have so far selected the second option.

Imaging can be performed in 2D or 3D, with slices in the transverse plane perpendicular to the bone to facilitate analysis. The location of the slice stack should be recorded precisely to enable longitudinal measurements, for instance at a fixed distance from a bony landmark, such as the tibial plateau or the patella. Landmarking can either be done during the imaging session using a scout image [5] or prior to the scanning session by placing a fish oil capsule on the skin at a pre-defined distance from surface anatomy landmarks like the iliac crest [55]. Receiver coils can either be array coils for wide coverage of the lower limb or local surface coils. The latter may be more convenient for imaging the upper limb and for patients with contractures.

As fat replacement of muscle tissue can be non-uniform along the muscle length [51], it is important that the slice stack covers as much of the muscle as possible. Commonly, this is achieved by selecting a field of view from joint to joint, i.e., malleolus to patella for the leg, and patella to iliac crest for the thigh. Slice thickness is usually between 2 and 10 mm with a 0–5 mm gap, resulting in 10–50 slices per body part. This poses a significant burden in terms of data processing as traditionally, data are being processed by outlining every single muscle in a pre-defined number of slices by a trained operator—which is a labour intensive process. In the last decade, several techniques have been developed that can quantify total adipose tissue volume and total muscle volume based on either T1 weighted or Dixon images [52, 56‐58]. In these approaches, the total muscle volume of an entire slice stack can automatically be segmented, thereby severely reducing the processing time. Unfortunately, severe fatty replacement is still a problem, as it is difficult to separate fat replacement from subcutaneous fat, and hence, user input is required to solve this [56, 59]. More importantly, as fatty replacement occurs in a muscle specific way, it is preferable to obtain information of each muscle separately instead of the entire muscle volume—and this is not possible using this methodology. While, semi-automatic approaches have been developed that can segment individual muscles [60, 61], these have not been applied in NMDs yet. In the absence of such an approach, segmentation is unfortunately still often performed manually and the field is in dire need of adequate approaches to solve this.

Depending on the choice of repetition time and number of signal averages used, a common Dixon acquisition of the entire upper leg can take 3–5 min. Using scan acceleration techniques, acquisition time can be reduced dramatically to about 1 min [43, 45]. However, these techniques are not yet standard on clinical systems.

The basic types of multi-echo acquisition sequences described in “Quantitative fat fraction imaging measurements: how is it done?” can be achieved by most clinical MRI scanners in skeletal muscle, even where the echoes have to be collected in separate acquisitions. Historically, it has not been possible to buy directly from the vendor an integrated system that will both perform the data acquisition and reconstruct the proton density fat fraction images at the time of acquisition. Most of the studies described in “Studies which have used quantitative fat fraction measurements in muscular dystrophy” have extracted the complex image data from the scanner and applied custom algorithms, such as those described in [15, 17, 62] to separate the fat and water and produce fat fraction images. Of particular note was the ISMRM Workshop on Water–fat separation, which collated examples of MATLAB code which can achieve this task and have been made available [15].

Of course, the methods for measuring fat fraction have also found extensive use in the measurement of hepatic steatosis in type 2 diabetes and non-alcoholic fatty liver disease [63]. Given the size of these markets, the main MRI vendors have now released products, usually sold as optional upgrades to the base scanner hardware, which claim to reliably measure hepatic steatosis: IDEAL-IQ (GE), mDixon Quant (Philips), and LiverLab (Siemens). However, it is important to note that these products and their optimised settings have not been validated in skeletal muscle and it should not be assumed that they will automatically give acceptable answers outside of their intended terms of use. The same quality assurance procedures outlined in “Quality assurance” should be adopted and consideration should also be given to the effect of a change of vendor software during the course of a longitudinal study.

Characterising rare muscle diseases with qMRI is an important task, because these techniques may be substantially more responsive than the existing clinical measures of function currently used as end-points in clinical trials [9‐11]. However, there are various qMRI approaches available that are influenced by details of acquisition and reconstruction, and this should be taken into consideration when comparing results from different centres. In this paper, we have given a conceptual and practical introduction to Dixon fat fraction imaging and MRS, drawing attention to the advantages and potential confounding factors of each. The authors believe that fat fraction imaging and MRS will both have an important role to play in future scientific and therapeutic studies, with quantitative MRI methods more familiar to operators in most institutions. Regardless of the method used, adequate operator training, qualification, and quality assurance processes will be needed over and above those used for standard radiological imaging. This will demand specialist input to co-ordinate and oversee clinical trials involving quantitative MRI. Given the low prevalence of many of the muscular dystrophies, high quality data may demand that patients travel to a smaller number of centres specialising in quantitative MRI. Many new clinical trials for DMD now require quantitative MRI in at least a subset of patients.

Practical considerations for quality assurance, patient positioning, slice prescription, and the available vendor systems were introduced. By summarising the available literature describing the application of Dixon-based fat fraction imaging in muscle dystrophies, we hope to highlight the power and promise of these techniques, while emphasising that a pragmatic consideration of the limitations is essential to maximise the potential advantages that fat fraction imaging confers on longitudinal clinical trials in this important class of diseases.

The authors would suggest that, with the increasing availability of quantitative MRI methods on modern scanners, and the increasing bodies of longitudinal literature identifying target muscle groups to study in therapeutic interventions, the quantitative MRI methods are reaching maturity and will have a critical and central role to play and end-points in future therapeutic trials.