The connection between MetS and MAFLD has been evidenced. Technological advances have allowed us to recognize the pathophysiological mechanisms involved in this association and determine how obesity, MetS and MAFLD interact with each other [12]. Obesity is a complex disease resulting from interactions between environmental, genetic, socioeconomic, and internal factors of each individual. The prolonged state of imbalance of energy uptake and energy expenditure leads to metabolic alterations, mainly in adipose tissue [36]. The metabolic alterations induced by this disease, nutrient overload and a sedentary lifestyle have been associated with the development of MAFLD [37–39].

Recently, it has been observed that alcohol intake also plays an important role in the development of MAFLD, due to the fact that moderate drinkers are susceptible to develop liver steatosis. This increased risk is not necessarily attributable only to the direct toxic effects of ethanol. Although heavy alcohol intake is a well-known risk factor for alcoholic liver disease (ALD), recent studies have highlighted the role of increased caloric intake from alcohol as a significant contributing factor to MAFLD. Alcohol itself is high in calories, and its regular intake can contribute to a positive energy balance, leading to weight gain and metabolic disturbances. Furthermore, alcohol intake can induce insulin resistance and impair lipid metabolism, enhancing lipid synthesis and impairing fatty acid oxidation in the liver. These mechanisms, combined with individual susceptibility to MAFLD, may contribute to the development of liver steatosis even in individuals with moderate alcohol intake [40,41].

Under physiological conditions insulin is the hormone responsible for the inhibition of lipolysis and gluconeogenesis at the adipose tissue level in response to high levels of glucose in the blood. In the presence of insulin resistance (IR), that develops as a consequence of obesity, lipolysis inhibition is impaired. Consequently, there is an increase in circulating free fatty acids (FFA) that simultaneously leads to a greater (IR) [28]. The uncontrolled lipolysis in adipose tissue generates excessive mobilization of FFAs to the liver [42]. In the liver, the presence of FFAs promotes gluconeogenesis and lipogenesis de novo, key processes in the onset of MAFLD [43]. In addition, IR induces an alteration in the production and secretion of adipokines and proinflammatory cytokines [36].

Lipotoxicity corresponds to the dysregulation of lipid metabolism and the alterations in their intracellular composition that leads to accumulation of harmful lipids in the liver [44]. In response to elevated levels of circulating FFAs, hepatocytes increase the uptake of FFAs, which results in an increased accumulation of intrahepatic lipid droplets (hepatic steatosis). Increased intrahepatic FFA levels are the main trigger of lipotoxicity. Nevertheless, FFAs are not the only lipids implicated in lipotoxicity. It has been observed that triglycerides, free cholesterol, lysophosphatidyl cholines, ceramides and bile acid also have an important role in the development of lipotoxicity and its deleterious effects on liver cells [45]. The accumulation of harmful lipids triggers the liver damage mechanisms characteristic of lipotoxicity, such as endoplasmic reticulum (ER) stress, oxidative stress, mitochondrial dysfunction and alteration of the electron transport chain, generating an excessive production of reactive oxygen species (ROS), leading to the development of steatohepatitis and liver fibrosis.

The unsuccessful disposal of excess FFA by hepatocytes leads to lipoapoptosis, an active process of steatohepatitis [46]. Apotosis in hepatocytes can occur through an intrinsic pathway activated by intracellular stress (oxidative stress, endoplasmic reticulum (ER) stress and mitochondrial permeabilization) in which multiple genes involved in different apoptosis signaling pathways are up-regulated, including p53 upregulated modulator of apoptosis (PUMA), PKR-like ER kinase (PERK), c-Jun NH2-terminal kinase-1 (JNK), CCAAT/enhancer-binding homologous protein (CHOP) and Bcl-2 interacting mediator (BIM). Or through an extrinsic pathway activated by cell death-associated ligands, both pathways culminate in the activation of caspases and finally in the hepatocyte death [45].

These alterations trigger the activation of Kupffer cells, responsible for liberating proinflammatory cytokines and initiating an inflammatory process. Ultimately the inflammatory process and ROS stimulate hepatic stellate cells, which in response excessively produce extracellular matrix leading to hepatic fibrosis [47,48].

In addition, the liver is not the only tissue affected by lipotoxicity. Adipose tissue, skeletal muscle, heart and pancreas are identified as targets of lipotoxicity. In muscle, lipotoxicity is associated with insulin resistance and an increase in intramyocellular lipids [43]. Furthermore, patients with MAFLD have abnormal endothelial function associated with high levels of circulating lipids and aminotransferases, which confers susceptibility to the development of cardiovascular disease (CVD) [49].

Minerals such as iron are crucial for maintaining the body's oxidative/redox balance. Recently, impaired mineral homeostasis has been observed in patients with MAFLD. Hepatic iron accumulation has been identified in patients with MAFLD. Iron accumulation produces liver injury through the release of free radicals (Fe2+) and generation of ROS produced during the Fenton's reaction enhanced the inflammatory response oxidative stress and the occurrence of ferroptosis [50]. Ferroptosis is defined as a form of programmed cell death caused by iron-dependent lipid peroxide accumulation, which leads to mitochondrial membrane injury. Ferroptosis can be triggered by two pathways, by disruption of the system Xc−/GSH/GPX4 axis and by lipid peroxidation caused by the increase in Fe2+ levels and the enhancement of arachidonic acid metabolism. Finally, the two pathways converge in the production of lipid peroxides. The accumulation of lipid peroxides leads to an increased formation of lipid droplets and eventually to ferroptosis, causing exacerbation of MAFLD and contributing to disease progression [51,52].

Pyroptosis is a type of programmed cell death caused by inflammasomes. There are three types of pyroptosis, each one is triggered by a different signaling pathway. The canonical pathway is activated when inflammasome sensors, such as NOD-like receptor family and pyrin domain-containing-1 and 3 (NLRP1, NLRP3) are stimulated by pathogens, pathogen-associated molecular patterns (PAMPs), and DAMPs. As a consequence, CASP1 is recruited and activates Gasdermin D (GSDMD) [53]. Activated GSDMD binds to membrane phospholipids and initiates pore formation. Presence of pores in the cell membrane allows release of intracellular proteins, ion decompensation, water influx, and cell swelling, leading eventually to cell death [54]. Recently, it has been studied how pyroptosis influences the development and progression of MAFLD. Activated GSDMD induces the expression of proinflammatory cytokines, activates NF-kB signaling pathway, increases lipogenesis and decreases lipolysis [55]. Furthermore, unrepressed NLRP3 activation has been found to increase inflammation and promote HSC activation [54]. The combination of these mechanisms contributes to the development of steatohepatitis and liver fibrosis. Nevertheless, further evidence is still being searched to elucidate the underlying mechanisms linking pyroptosis and MAFLD.

Multiple research studies have been undertaken to evaluate and validate the use of MAFLD instead of NAFLD. These studies have robustly shown the superior utility of the MAFLD criteria in identifying high risk patients compared to the former NAFLD criteria [62–66]. It has observed that patients who meet the definition of MAFLD tend to have a more severe fibrosis, higher risk of disease progression, higher risk of extra-hepatic complications and mortality compared to those who meet the NAFLD definition [65].

The spectrum of clinical MAFLD extends from patients with low or normal BMI who are metabolically dysfunctional to metabolically dysfunctional overweight/obese patients. A study conducted in 2018 showed that metabolically unhealthy patients have a higher amount of steatohepatitis and fibrosis despite their BMI. Furthermore, the prevalence of these more severe forms of MAFLD was observed to be similar among non-obese and obese patients [67]. The renaming of the disease is intended to encompass all affected individuals, especially for those with high risks of metabolic disorders, regardless of their BMI [68]. Although the advantages of using MAFLD have been identified, there is a lot of controversy about its use [69].

The MAFLD definition has been endorsed by multiple stakeholders from different medical disciplines and fields of health sciences from more than 134 countries around the world [70]. Despite this self-speaking evidence, a debate rebound and several questions have been raised particularly regarding the methodology that was used to develop the consensus.

Recent studies have been investigating the use of machine-learning algorithms and artificial intelligence (AI) approaches to predict and diagnose metabolic syndrome, as well as its association. These innovative techniques have shown great potential in identifying robust prediction and diagnostic markers for both conditions. By leveraging large-scale datasets and sophisticated algorithms, machine learning models can analyze diverse clinical and genetic factors associated with metabolic syndrome and MAFLD. These factors include anthropometric measurements, blood biomarkers, liver function tests, genetic variants, and imaging data. The integration of machine learning and AI approaches allows for the development of accurate prediction models that can identify individuals at risk of developing metabolic syndrome and subsequent MAFLD. These models also provide valuable insights into the underlying mechanisms and pathophysiology of both conditions. By identifying high-risk individuals and understanding the complex interplay between metabolic syndrome and MAFLD, these studies offer opportunities for early intervention, personalized treatment strategies, and improved patient outcomes [71–74].

For decades the term NAFLD has contributed to stigma, trivialization and confusion among NAFLD patients. Such factors have been observed to negatively affect patient´s life quality, adherence to treatment and the individual's perception of the disease. Increased disease burden reflects the bidirectional interactions existing between FLD and metabolic disorders and diseases. Generating a positive impact on the perception and understanding of the disease [75]. Removing the word "alcohol" from the FLD definition has been found to reduce stigmatization among patients about the disease. Compared to NAFLD, it has been observed that MAFLD increases awareness of patients about the disease and the risks associated with it [76,77]. Empowering patients and physicians to acquire a clearer picture of the disease is the cornerstone of improving the care and management of patients with MAFLD.