Metabolic dysfunction-associated steatotic liver disease (MASLD) formerly known as non alcoholic fatty liver disease (NAFLD) occurs due to excessive hepatic fat accumulation in obese patients in the absence of alcohol use [1–4]. It is associated with insulin resistance and other metabolic disorders including diabetes, dyslipidemia and hypertension [1]. NAFLD is diagnosed when fatty changes in the liver occur in the absence of heavy alcohol consumption. In the United States, it is observed in 31 % of adults as well as in 33 % of potential live liver donors noted on liver biopsy [4].

MASLD's pathophysiology is influenced by diet, lifestyle, and inflammation, which directly affects the severity of MASLD's clinicopathologic outcome [5]. The precise pathophysiology and factors causing progressive hepatocellular damage after triglyceride accumulation are unknown; however, it appears that changes in local and systemic factors (particularly insulin resistance) regulate the balance between hepatic lipid influx or synthesis and their export or oxidation, leading to hepatic triglyceride accumulation [1,6]. The pathophysiology of MASLD is influenced by circulating lipids and the various compounds released from adipose, muscle, and liver tissues, as well as pancreatic and gut hormones [5].

MASLD therapy's main aim is to slow the disease's development and prevent liver-related illness and death [7]. There is currently no cure for MASLD, but a variety of medications−including the treatment of high blood pressure, high cholesterol, type 2 diabetes, and obesity−can help slow down the disease progression [8]. Some measures for lowering MASLD risk include losing weight, maintaining a healthy diet, exercising regularly, and quitting smoking [8].

Sarcopenia is a disorder characterized by a widespread progressive loss of skeletal muscle mass and strength, leading to physical and psychological deterioration and, eventually death. Although sarcopenia is more likely to affect the elderly, its onset can occur early in association with other disorders affecting younger patients [9].

Multiple combined factors, including age, gender, and level of physical activity, predispose to sarcopenia development [9]. Its prevalence ranges from 5–13 percent in people 60–70 years old, while the prevalence ranges from 11 to 50 percent in people >80 years old [9].

Sarcopenia's etiopathogenesis is not well understood. Resistance exercise is particularly effective at slowing the age-related loss of skeletal muscle, and age, gender, and level of physical activity are all well-known risk factors for sarcopenia. Obesity, osteoporosis, type 2 diabetes, and insulin resistance are all serious sarcopenia co-morbidities [9].

MASLD and sarcopenia have several risk factors in common [10], of which suggest a possible association between the two conditions. By revising the current literature, we noticed some conflict between the different studies’ results regarding the relationship between sarcopenia and MASLD and the impact of MASLD on the skeletal mass of patients with sarcopenia [11–34]. The exact relation between MASLD and sarcopenia is not fully established yet. Hence we aimed to assess the association between sarcopenia, MASLD, and MASLD-related fibrosis by summarizing the data of 25 studies.

This study was conducted in strict accordance with the “Preferred items for systematic reviews and meta-analyses” (PRISMA) guidelines [35].

Our analysis showed that sarcopenia is associated with a higher probability of developing MASLD. Also, MASLD patients with sarcopenia had a higher probability of liver fibrosis than MASLD patients with no sarcopenia. On the other hand, there was no significant relationship between low SMI values and MASLD.

Multiple cross-sectional observational studies have shown that sarcopenia is linked to an increased risk of MASLD and MASLD-related advanced fibrosis in MASLD patients and that this association is independent of obesity, metabolic syndrome, and insulin resistance [10].

MASLD patients’ liver enzyme levels fluctuate, with typical values present in up to 78 percent of patients at any given time [39,40]. Although liver biopsy is the gold standard for diagnosing MASLD, ultrasonography, CT, and MRI scanning are valuable for detecting moderate to extreme fatty changes in the liver. The fatty liver appears darker and hypodense. The hepatic vessels appear lighter than the rest of the body, and this may be mistaken for contrast injection [41].

The discovery of a correlation between sarcopenia and MASLD could help prevent the disease from worsening. Sarcopenia and MASLD have been linked in several previous studies [42]. In Cruz et al.[43], an association was found between the sarcopenic index and non-alcoholic hepatic steatosis. Our results confirmed these findings after pooling different studies’ results. On the other hand, Gan et al.[26], reported in their cross-sectional that low muscle mass and low muscle strength are independently associated with MASLD. Despite their large sample size, the range of age patients varied from 18 to 80 years, which may have affected the quality of evidence of their study [26]. Also, in the previous meta-analysis by Tovo et al.[44], Sarcopenia was independently associated with MASLD and possibly with advanced fibrosis.

Fibrogenesis in MASLD is a critical process that affects clinical management [45]. Non-alcoholic steatohepatitis clinical research network pathology committee developed a staging for MASLD [46]. Four out of 14 features in this staging system take a numerical score as follows: steatosis (0-3), lobular inflammation (0-2), hepatocellular ballooning (0-2), and fibrosis (0-4) [46]. Factors contributing to liver damage include direct cellular injury, cell degeneration and death through apoptosis and other forms of cell death, proinflammatory cytokine expression, hepatic stellate cell activation (HSCs), and irregular wound healing responses leading to fibrosis [47]. An imbalance between pro-oxidant species and antioxidant defense capacities causes oxidative stress. In the setting of hepatic steatosis, an overproduction of toxic lipid metabolites exacerbates oxidative damage to liver cells.

The role of sarcopenia in the development of MASLD may have significant therapeutic consequences in future research. Following our finding that sarcopenic MASLD patients have a higher risk for liver fibrosis, Yu et al.[48], linked sarcopenia to a higher risk of steatohepatitis or advanced liver fibrosis in patients with MASLD. In a biopsy-proven MASLD cohort studied by Koo et al.[11], sarcopenia was linked to metabolic dysfunction-associated steatohepatitis (MASH) and severe fibrosis. Besides, low muscle mass has been linked to the histological severity of MASLD [11]. Lee et al. [30] concluded that sarcopenia is associated with significant liver fibrosis.

Sarcopenic patients are evaluated using the skeletal muscle mass index (SMI), which is calculated by dividing the limb skeletal muscle mass (kg) by the square of the patient's height (m2). Men with an SMI < 7.0 kg/m2 and women with an SMI < 5.7 kg/m2 were identified as having low muscle mass [49]. Our analysis showed no significant relationship between the odds of MASLD and SMI values. However, SMI should be considered in the diagnosis of MASLD [50]. In Kim et al. [28] a low SMI was associated with a high risk of MASLD, independent of other well-known metabolic risk factors; however, this link may vary depending on age group or menopausal status. Our results interfere with that of the previous meta-analysis by Cai et al. [51] stating that people with MASLD have a lower SMI than healthy people. More well-designed prospective studies are needed to reinforce the claims and confirm this relationship.

In this meta-analysis, we included many studies with large sample sizes. Included studies were of fair to good quality. At the same time, limitations include the different designs of included studies, the significant heterogeneity that could not be solved in some outcomes, and different definitions of sarcopenia across included studies. Also, our search strategy include studies until October 2022 and the results of crude analyses were not reported by some studies. Also, an age based subgroup analysis was not conducted due to non-uniform age related data reported in included studies.

In conclusion, sarcopenia raised the risk of MASLD and was linked to a higher risk of liver fibrosis in MASLD patients. However, SMI had no independent predictive value for developing NAFLD.

Adnan Malik - Conceptualization, Methodology, Formal Analysis, Writing (Original Draft), and Review & Editing; Sadia Javaid - Conceptualization, Data Curation, Writing (Review and Editing); Muhammad Imran Malik - Methodology, Writing (Original Manuscript), and Review and Editing; Shahbaz Qureshi - Supervision, Writing, and Editing the manuscript.