Contractile properties and magnetic resonance imaging-assessed fat replacement of muscles in myotonia congenita.

BACKGROUND AND PURPOSE: Myotonia congenita (MC) is a muscle channelopathy in which pathogenic variants in a key sarcolemmal chloride channel Gene (CLCN1) cause myotonia. This study used muscle magnetic resonance imaging (MRI) to quantify contractile properties and fat replacement of muscles in a Danish cohort of MC patients. METHODS: Individuals with the Thomsen (dominant) and Becker (recessive) variants of MC were studied. Isometric muscle strength, whole-body MRI, and clinical data were collected. The degree of muscle fat replacement of thigh, calf, and forearm muscles was quantitively calculated on Dixon MRI as fat fractions (FFs). Contractility was evaluated as the muscle strength per contractile muscle cross-sectional area (PT/CCSA). Muscle contractility was compared with clinical data. RESULTS: Intramuscular FF was increased and contractility reduced in calf and in forearm muscles compared with controls (FF = 7.0-14.3% vs. 5.3-9.6%, PT/CCSA = 1.1-4.9 Nm/cm2 vs. 1.9-5.8 Nm/cm2 [p < 0.05]). Becker individuals also showed increased intramuscular FF and reduced contractility of thigh muscles (FF = 11.9% vs. 9.2%, PT/CCSA = 1.9 Nm/cm2 vs. 3.2 Nm/cm2 [p < 0.05]). Individual muscle analysis showed that increased FF was limited to seven of 18 examined muscles (p < 0.05). There was a weak correlation between reduced contractility and severity of symptoms. CONCLUSIONS: Individuals with MC have increased fat replacement and reduced contractile properties of muscles. Nonetheless, changes were small and likely did not impact clinically on their myotonic symptoms.

Muscle fat replacement and contractility in patients with skeletal muscle sodium channel disorders.

Skeletal muscle sodium channel disorders give rise to episodic symptoms such as myotonia and/or periodic paralysis. Chronic symptoms with permanent weakness are not considered characteristic of the phenotypes. Muscle fat replacement represents irreversible damage that inevitably will impact on muscle strength. This study investigates muscle fat replacement and contractility in patients with pathogenic SCN4A variants compared to healthy controls. T1-weighted and 2-point Dixon MRI of the legs were conducted to assess fat replacement. Stationary dynamometry was used to assess muscle strength. Contractility was determined by maximal muscle contraction divided by cross-sectional muscle area. The average cross-sectional intramuscular fat fraction was greater in patients compared with controls by 2.5% in the calves (95% CI 0.74-4.29%, p = 0.007) and by 2.0% in the thighs (95% CI 0.75-3.2%, p = 0.003). Muscle contractility was less in patients vs. controls by 14-27% (p < 0.05). Despite greater fat fraction and less contractility, absolute strength was not significantly less. This study quantitatively documents greater fat fraction and additionally describes difference in muscle contractility in a large cohort of patients with skeletal muscle sodium channel disorders. The clinical impact of these abnormal findings is likely limited as muscle hypertrophy in the patients served to preserve absolute muscle strength. Subgroup analysis indicated significant difference in phenotype by genotype, however these findings lack statistical significance and serve as inspiration for future researchers to probe into the geno- phenotype relationship in these disorders.Trial registration: The study was registered at http://clinicaltrials.gov (identifier: NCT04808388).

Muscle MRI in McArdle Disease: A European Multicenter Observational Study.

BACKGROUND AND OBJECTIVES: Glycogen storage disease type V (GSDV) or McArdle disease is a muscle glycogenosis that classically manifests with exercise intolerance and exercise-induced muscle pain. Muscle weakness and wasting may occur but is typically mild and described as located around the shoulder-girdle in elderly patients. Paraspinal muscle involvement has received little attention in the literature. The present study aimed to quantify fat-replacement of paraspinal, shoulder and lower limb muscles by magnetic resonance imaging in a European cohort of GSDV patients. METHODS: This observational study included patients with verified GSDV and healthy controls (HC). Whole-body MR-images and clinical data were collected. The degree of muscle fat-replacement was evaluated on T1-weighted images with the semi-quantitative visual Mercuri-scale, and on Dixon-images where individual muscle fat fractions (FF) were quantitatively calculated. RESULTS: MR-images and clinical data from a total of 57 GSDV patients (age 44.3±15.2 years) from five European centers were assessed and compared to findings in 30 HC (age 42.4±14.8 years). Patients with GSDV had significantly more fat-replacement of theparaspinal muscles compared to HC on all levels investigated detected both by the Mercuri and the Dixon methods (Dixon, paraspinal composite-FF (GSDV vs HC), at the cervical-: 31.3±13.1 vs 15.4±7.8; thoracic-: 34.5±19.0 vs 16.9±8.6 and lumbar-level: 43.9±19.6 vs 21.8±10.2 (p<0.0001)). Patients with GSDV also had significantly more fat-replacement of the shoulder muscles (evaluated by the Mercuri-scale), along with significantly, but numerically less, fat-replacement of thigh- and calf muscles compared to HC (Dixon, lower limb composite-FF (GSDV vs HC) at the thigh-: 12.0±5.6 vs 8.8±2.7 and calf-level: 13.1±6.7 vs 9.1±2.9 (p≤0.05)). DISCUSSION: The primary findings are that patients with GSDV exhibit severe fat-replacement of the paraspinal muscles, which can have important implications for the future management of patients with GSDV, and also significant fat-replacement of shoulder-girdle muscles as previously described. The clinical relevance of the discrete increases in lower limb FF is uncertain. The changes were found to be age-related in both groups, but an accelerated effect was found in GSDV, probably due to continuous muscle damage.