Hepatocytes are the most abundant cells within the liver [34] and play an important role in liver-specific functions like glycogen metabolism, bile secretion, lipid metabolism, steroid hormone metabolism, plasma protein synthesis, and detoxification.

Many studies have shown that EVs released from lipotoxic hepatocytes promote inflammation in MAFLD [11, 14, 37–42, 47–49]. Moreover, hypoxic conditions, present in MAFLD, aggravate the pro-inflammatory effect of EVs derived from lipotoxic hepatocytes on KCs [37]. Palmitate and lysophosphatidyl choline (LPC) treatment increased the release of EVs enriched with TRAIL from hepatocytes. This release was mediated by the CHOP-DR5-Caspase-8/Caspase-3-ROCK1 signaling cascade. TRAIL-enriched EVs induced the activation of various types of macrophages. On the one hand, they change the polarization of mouse BMDM towards a classical M1 macrophage phenotype with increased expression of interleukin-1β (IL-1β) and IL-6 in a DR5-dependent manner. On the other hand, human THP-1 macrophages treated with TRAIL-containing EVs were activated in an NF-κB and RIP1-dependent manner, and activation was inhibited by RIP1 inhibitor or loss of RIP1. Moreover, the application of a ROCK1 inhibitor in murine NASH models reduced the release of proinflammatory EVs and thus ameliorated NASH [14]. LPC-treated hepatocytes release active ITGβ1-enriched EVs that were shown to induce macrophage chemotaxis. ITGβ1-containing EVs mediate THP-1 cell adhesion to LSECs [38]. In addition, EVs enriched with ITGβ1 promote the inflammatory phenotype of monocytes, underscoring their proinflammatory role in MAFLD [38]. Several reports highlighted the role of lipotoxic ceramides and S1P in macrophage chemotaxis and inflammation in MAFLD [11, 39, 40]. EVs from lipotoxic hepatocytes enriched in ceramides induce the recruitment of macrophages into the liver and promote inflammation. The release of EVs enriched in ceramides is mediated by IRE1α and decreasing levels of IRE1α in hepatocytes decrease their release of EVs [11]. EVs released from palmitic acid-treated hepatocytes also promote the recruitment of macrophages into the liver via the interaction of exosomal S1P with the S1P receptor in macrophages. Inactivation of S1P signaling by preventing sphingosine phosphorylation via inhibition of SphK1 and SphK2 or deletion of the S1P receptor in macrophages results in the loss of the chemoattractive effects of EVs derived from palmitate-treated hepatocytes on macrophages [40].

Finally, EVs from hydrogen peroxide-damaged hepatocytes are enriched in mtDNA that increase the expression of pro-inflammatory cytokines on murine RAW 264.7 cells in a TLR-9 dependent manner, whereas IL-22Fc pretreatment of these hepatocytes decrease the pro-inflammatory potential of these EVs [42].

Hepatic fibrosis is characterized by the excessive deposition of ECM in the liver. The main producers of ECM in the liver are aHSCs. The HSCs reside in the space of Disse. Under normal conditions, HSCs are quiescent pericyte-like cells. In chronic liver injury, HSCs transdifferentiate into an activated phenotype, characterized by loss of lipid stores, increased synthesis and secretion of ECM components, and increased proliferation. Activation is also associated with a 4.5-fold increase in EV production [43, 44]. Recent studies have shown that exosomes containing specific miRNAs from lipotoxic hepatocytes can promote stellate cell activation, proliferation, and migration [13, 15]. A comparative proteomic analysis of mouse HSC-derived EVs indicated that EVs from HSCs may play a key role in the regulation of HSC function and activation in vivo [43]. The internalization of hepatocyte-derived EVs by HSCs is dependent on the presence of either vanin-1 (VNN-1) or fibronectin (FN) [43, 50, 51]. Once internalized, these EVs stimulate the expression of pro-fibrotic mediators in HSCs, as also observed in our studies: hypoxic, palmitate-treated HepG2 cells release EVs that increase the expression of transforming growth factor-β (TGF-β), connective tissue growth factor (CCN2), collagen type 1 and α-smooth muscle actin (α-SMA) in HSCs [43, 52]. In contrast, EVs secreted by quiescent HSCs contain high levels of Twist 1, which drives miR-214 expression and results in the suppression of fibrogenic signaling. It is therefore relevant to consider the activation state when investigating HSC-derived EVs [43, 53, 54]. EVs can also act in an autocrine manner on HSCs: CCN2 promotes activation of HSCs and was detected in EVs released by HSCs [55].

LSECs are a major component of liver NPCs [56, 57]. Whereas vascular ECs form a continuous lining in arteries and veins, LSECs form a discontinuous layer in liver sinusoids. Moreover, in contrast to vascular ECs, LSECs are fenestrated [45, 46]. In chronic liver diseases like NASH, the LSECs dedifferentiate and form a continuous lining and lose their fenestrae. One study [45], using single-cell omics analysis, demonstrated that epigenetic dysregulation of LSECs promotes the dedifferentiation of these cells from a sinusoidal to a vascular phenotype. This was associated with increased production of EVs containing IGFBP7 and ADAMTS1, which further promoted the recruitment of pro-fibrogenic Th17 cells to the liver and exacerbation of hepatic fibrosis [45]. Investigation of the proteome of LSEC-derived EVs during the progression of chronic liver disease demonstrated that LSEC-derived EVs contain high levels of angiocrine effectors and tropomyosin 1. Subsequently, tropomyosin was shown to have a de-activating effect on HSCs [46].

KCs are the liver-specific macrophages. They play an important role as inflammatory cells in the progression of chronic liver diseases and secrete immunosuppressive factors and metabolites, however, not much is known about the role of KC-derived EVs in MAFLD [58, 59].

Steatosis is the accumulation of lipids in hepatocytes and is the earliest and defining feature of MAFLD. Studies in mice have shown that EVs are involved in the response to lipid overload in the liver and that the liver can control lipid remodeling in adipose tissue via EVs in conditions of steatosis [60]. Recent findings suggest that EVs can be mediators of lipotoxicity during MAFLD [32]. Lipid accumulation and in particular lipotoxicity can trigger cell signaling pathways that favor the release of EVs from hepatocytes [7]. In vitro studies using primary mouse hepatocytes and human Huh7 cells have shown that palmitate activates DR5 signaling, which induces the release of EVs that promote the inflammatory phenotype of macrophages [14]. Lipotoxicity induced by saturated fatty acids like palmitate increases membrane lipid saturation causing endoplasmic reticulum (ER) stress. Lipotoxicity has also been shown to induce membrane alterations in the EV membrane and EV lipid cargo, suggesting that these EVs might be useful to track lipotoxic stress in the liver [61].

NASH, the inflammatory stage of MAFLD, is characterized by increased levels of pro-inflammatory and chemotactic cytokines, oxidative stress, mitochondrial and ER stress, lipid peroxidation, and eventually cell death. In particular oxidative stress is considered a central mechanism in the pathophysiology of MAFLD [62]. Lipotoxicity can induce oxidative stress and inflammatory response by increasing lipid peroxidation and the formation of neo-epitopes such as oxidation-specific epitopes (OSEs) [63]. These OSEs have been demonstrated to be present in EVs as well as in circulating lipoproteins and can contribute to the activation of other liver cells such as KCs, promoting inflammation [64]. Lipotoxic stress is also related to organelle dysfunction, including ER stress and mitochondrial dysfunction. In a murine model of diet-induced NASH, mitochondrial stress and oxidative stress correlate with increased release of EVs, containing oxidatively damaged mitochondrial particles. These EVs can contribute to an antioxidant response to protect from acute oxidative stress but they can also be deleterious by enhancing the inflammatory response [65].

The innate immune response plays an important role in inflammation. Classical innate immune receptors include pattern recognition receptors (PRRs) like the TLRs, which detect damage-associated molecular patterns (DAMPs). Activation of TLRs has been demonstrated in MAFLD [66]. mtDNA in EVs released from damaged hepatocytes activates TLR-9 on target cells [41, 42]. Loss of TLR-9 attenuates NASH and specific deletion of TLR-9 in KCs reduced the expression of inflammatory cytokines such as IL-β, IL-6, and tumour necrosis factor α (TNFα) in a high-fat diet (HFD) model of MAFLD [41]. Hepatocytes from HFD hepatocytes release EVs enriched in mtDNA, resulting in TLR-9 activation and increased expression of the TLR-9 downstream target TNFα in KCs. Plasma from obese patients with liver injury contained higher levels of mtDNA and TLR-9 ligand activity, suggesting that mtDNA from damaged hepatocytes and TLR-9 activation is involved in the inflammatory response in NASH, possibly mediated via EVs [41]. EVs derived from hepatocytes mediate the activation of TLR-3 in HSCs. This may aggravate fibrosis by enhancing IL-17 production by γδ T cells at the early stages of liver fibrosis [67].

Other pro-inflammatory PRRs associated with the development of MAFLD include the inflammasome sensor molecule typically a NOD-like receptor (NLR) family pyrin domain containing protein 3 (NLRP3), which is a component of inflammasomes and has been shown to promote inflammation and fibrogenesis during the progression of MAFLD [68]. EVs modulate the activation of NLRP3 [69]. In the choline deficient L-amino acid (CDAA) and HFD mice models of MAFLD, altered levels of proteins related to cell death, stress, and angiogenesis were demonstrated in plasma-derived EVs [69]. Other studies showed the enrichment of miR-7 in hepatic EVs that promote lysosomal membrane barrier permeability, inducing the activation of NLRP3 and microvascular hyperpermeability [70]. Furthermore, it has been shown that steatotic hepatic cells release EVs that induce the expression of NLRP3 and inflammasome activity in target cells, including macrophages. Moreover, in this study increased hepatic expression of NLRP3 was detected in mice with methionine-choline deficient diet-induced NASH [71].

In addition to macrophages, ECs are also a target for EVs. It has been demonstrated that human umbilical vein ECs (HUVECs) can internalize EVs derived from palmitic acid-treated human HepG2 cells and this process appeared to be dependent on the presence of lipid rafts and VNN-1. In fact, VNN-1 is not only involved in the internalization of EVs, but also in EC migration [72]. Another study demonstrated uptake of EVs derived from palmitic acid-treated human Huh7 cells by HUVEC cells, leading to increased expression of inflammation-related genes in HUVECs like E-selectin, intercellular adhesion molecule-1 (ICAM-1), vascular cell adhesion molecule-1 (VCAM-1), IL-1β and matrix metalloproteinase-1 (MMP-1) [73].

To achieve novel interventional and non-interventional strategies to treat patients with MAFLD, a thorough understanding of the mechanisms leading to MAFLD is necessary. It is clear from the available evidence that both paracrine and autocrine communication mediated by EVs play an important role in the pathogenesis of MAFLD. Therefore, more studies, focusing on analyzing the content and effects of the cargo of EVs are necessary.

Research on EVs has given us insights into the possible application of EVs as diagnostic tools. In 2011, the presence of small EVs in plasma from patients with active hepatitis C was reported [74]. Interestingly, these microparticles were derived from CD4⁺ and CD8⁺ T cells. Moreover, these EVs induced the expression of several metalloproteases such as MMP-1, MMP-3, MMP-9, and MMP-13 and reduced the expression of procollagen α1(I) mRNA in the human HSC cell line LX-2 [74].

In 2012, it was demonstrated that patients with NASH have increased plasma levels of circulating EVs derived from invariant natural killer T (iNKT) cells and monocytes (CD14⁺), which were also postulated to play a role in the pathogenesis of NASH [10]. Taken together, these results indicate that the amount and content of circulating EVs can provide information on the clinical status.

Since the pathophysiology of MAFLD involves hepatocyte lipotoxicity and concomitant pro-inflammatory and profibrogenic responses, the macrophage (KC) and the HSC are attractive targets for intervention. Adipose-derived stem cells (ADSCs) secrete EVs that promote M2 polarization in macrophages (high Arg-1 phenotype), with beneficial effects on inflammation, systemic insulin resistance, dyslipidemia, and hepatic steatosis in an in vivo model of NASH [75]. Stem cells (SCs) may be a suitable medium to deliver EVs to target cells. SCs are cell types that can self-renew and differentiate into other cell types. Furthermore, it has been proposed that EVs derived from SCs may induce regenerative programs in injured organs such as the liver by transcriptional or translational modification [76]. EVs from human liver SC (HLSC; HLSC-EVs) improved liver function in a murine diet-induced NASH model [77]. In addition, the transcriptomic analysis demonstrated 29 pro-fibrogenic genes (α-SMA, Col1α1, Ltbp-1, and TGF-β1) and pro-inflammatory genes [TNFα, IL-1β, interferon-γ (IFN-γ)] to be upregulated in hepatic tissue in NASH. Interestingly, the expression of 28 of these genes was significantly reduced after treatment with the HLSC-EVs [77]. Similarly, in a genetic model of NASH (Mc4r knockout mice), treatment with human adipose tissue-derived mesenchymal SC EVs (AT-MSC-EVs) significantly attenuated liver fibrosis. Moreover, different metabolic parameters such as triglyceride (TG), free fatty acids (FFAs), aspartate transaminase (AST), alanine transaminase (ALT), and albumin (ALB), glucose (Glu) or total bilirubin (T-bil) levels were also improved [78].

Since EVs have been shown to have therapeutic value in the resolution of MAFLD and since miRNAs are components of the cargo of EVs and miRNAs are involved in various biological functions, we will discuss the application of EV-derived miRNAs in more detail in the next section.

miRNAs have been implicated in the epigenetic regulation of cell proliferation, fat metabolism, and cell death [79]. Moreover, the role of miRNAs in liver inflammation, fibrosis, and cirrhosis has been acknowledged [80]. miRNAs are detected in biological fluids like blood, urine, tears, saliva, and breastmilk and can be used as diagnostic biomarkers, e.g., in type 2 diabetes, HCC, and MAFLD [81, 82]. miR-122 is released from damaged hepatocytes in alcoholic liver disease, viral hepatitis, and drug-induced liver injury [83–85]. miRNAs constitute an important class of gene-regulatory molecules in both humans and mice [86]. They are small, non-coding RNAs (18–25 nucleotides) and can be incorporated into exosomes and secreted into the extracellular environment [87]. miRNAs are involved in a number of biological functions such as cellular differentiation, proliferation, metabolism, and apoptosis [88, 89]. They regulate gene expression in a posttranscriptional manner via binding complementary mRNA transcripts, suppressing gene expression via mRNA degradation and repression of translation. miRNAs not only interact with mRNAs but also with long non-coding RNAs (lncRNAs), pseudogenes, and circular RNAs (circRNAs) [90]. Several miRNAs have been detected in liver-derived exosomes, e.g., miR-21, miR-125, miR-146, miR-192, miR-223, and miR-378 [91]. Exosomal miRNAs originating from lipotoxic hepatocytes are also crucial in inflammation during the progression of MAFLD [47, 48]. EVs from lipotoxic hepatocytes contain miR-192-5p. This miRNA was able to polarize THP-1 macrophages towards the pro-inflammatory M1 phenotype via targeting the 3’ untranslated region (3’ UTR) of Rictor and suppressing its expression, subsequently inhibiting downstream protein kinase B/forkhead box O1 (Akt/FoxO1) factors. Overexpression of miR-192-5p and lack of Rictor in THP-1 cells further underscored the key role of miR-192-5p in M1 macrophage polarization [47]. Oxidized low-density lipoprotein (ox-LDL) and cholesterol impaired degradation of MVBs in Huh7 cells, leading to increased release of EVs containing miR-122-5p, promoting M1 polarization of THP-1 macrophages [49]. The M1 polarization proved to be miR-122-5p dependent since downregulation of miR-122-5p in Huh7 cells abrogated the exosome-induced M1 polarization of THP-1 macrophages [49]. miR-128-3p was identified as the exosomal messenger that reduced the expression of the stellate cell quiescence marker peroxisome proliferator-activated receptor-γ (PPAR-γ) [15].

The expression of specific miRNAs was increased in EVs released from hepatocytes treated with toxic lipids, including miR-24, 19b, 34a, 122, and 192. High levels of exosomal miR-192 promote HSC proliferation and activation [13]. Increased circulating exosomal miR-192 and miR-122 in MAFLD patients further demonstrate that the miRNA profile may be a representative marker in the diagnosis of fibrosis in MAFLD [13].

Several studies indicated the therapeutic potential of exosomal miRNAs. Thus, miR-627-5p overexpressed in EVs from human umbilical cord-derived mesenchymal SCs (HUC-MSC-EVs) effectively reduced serum levels of ALT, AST, TG, and total cholesterol as well as lipid deposition in a high fat-high fructose diet rat model of NASH [92]. Moreover, in in vitro studies, miR-627-5p HUC-MSC-EVs improved cell viability and lipid homeostasis and inhibited apoptosis and fatty acid synthesis in palmitate-treated L-O2 cells [92]. Another relevant miRNA is miRNA-96-5p. Its presence in EVs from bone marrow-derived mesenchymal SCs (BM-MSC-EVs) downregulated fatty acid synthesis and lipid uptake in an HFD rat model of NASH, whereas mitophagy genes [Parkin, phosphatase and tensin homologue (PTEN)-induced putative kinase 1 (PINK1), unc-51 like autophagy activating kinase 1 (ULK1), B-cell lymphoma 2/adenovirus E1B 19 kDa protein-interacting protein 3 (BNIP3L)] and autophagic genes [autophagy related gene 5 (ATG5), ATG7, ATG12] were induced [93]. Liver-derived EVs also have an important role in lipid metabolism. Wu et al. [94] demonstrated, using a murine diet model of MAFLD, that miR-130a-3p regulates Glu metabolism, suppressing PH domain leucine-rich repeat protein phosphatase 2 (PHLPP2) expression and activating Akt-A160-Glu transporter type 4 (GLUT4) signaling in adipocytes, thus increasing Glu uptake. The role of the liver in regulating lipid metabolism, in particular, whether hepatic EVs containing miRNAs play a role in the communication between liver and adipose tissue, was also investigated in a murine MAFLD model [60]. In this study it was shown that Let-7e-5p enhances adipocyte lipid deposition by increasing lipogenesis and inhibiting lipid oxidation via PPAR-γ co-activator 1-alpha (PGC1α), confirming that the liver orchestrates an integrated response involving EVs to modulate lipid metabolism.

In conclusion, EVs as an interventional therapy still represent a largely unexplored field. Nevertheless, promising results in the treatment of MAFLD as well as other liver diseases have been reported. Due to the heterogeneity of EVs, diverse effects on target cells have been reported. This stresses the need to standardize the use of EVs in therapeutic applications (isolation, characterization, standardization of administration, etc.) and to take into account the type of the EV-releasing cell, the state of the releasing cell, the stimulus that led to their secretion, their cargo, as well as the target cell, in order to be able to carry out clinical trials in the near future (see Table 3).