Increased platelet- and endothelium-derived EVs are markers of EC activation and vascular injury (70), and several studies have focused on the alterations and importance of platelet- and endothelium-derived EVs in hypertensive states (71–73). Bao et al. (74) showed that platelet-derived EVs (pEVs), which deliver miR-92a-3p to VSMCs after intimal injury, inhibit PTEN and promote activation of the Akt pathway and the production of Col8a1 in VSMCs, leading to the deposition of Col8a1 at the site of intimal injury and increased arterial wall stiffness. Wang et al. (75) discovered that dysfunctional ECs could also secrete miR-92a-rich EVs, leading to the contractile-to-synthetic phenotype change of VSMCs or causing EC dysfunction in a paracrine manner; that circulating miR-92a levels were increased in hypertensive patients and Ang II-induced hypertensive mice compared to healthy controls; and that human plasma levels of circulating miR-92a were positively correlated with pulse wave velocity (PWV), systolic blood pressure (SBP), and diastolic blood pressure (DBP) and inversely correlated with NO levels. MiR-92a induces vascular dysfunction and is involved in the pathology of endothelial injury and atherosclerosis. However, the correlation between pathological conditions and circulating or cellular levels of miR-92a remains inconclusive, and other works suggest that miR-92a may play a protective role by maintaining vascular homeostasis. MiR-92a expression was downregulated in elderly and aged B6D2F1 mice (a model of vascular aging), which led to age-related vascular dysfunction (76). Inflammatory cell-derived exosomes have also been implicated in EC dysfunction under hypertension. Osada-Oka et al. (77) showed that Ang II-induced macrophages released less of exosomal miR-17-3p, which increased the expression of the proinflammatory factor intracellular adhesion molecule-1 (ICAM-1) in ECs.

Shang et al. (78) revealed that exosomal miR-483-3p released from ECs had a protective effect on ECs. Human umbilical vein endothelial cells (HUVECs) were incubated with Ang II in vitro to simulate the pathophysiological state of hypertension. MiR-483 overexpression reversed Ang II-induced changes in angiotensin-converting enzyme 1 (ACE1), endothelin-1 (ET-1), connective tissue growth factor (CTGF) and transforming growth factor-β (TGF-β) levels in ECs. Telmisartan increased miR-483-3p levels in ECs. In addition, exosomal miR-483-3p released from ECs could also be taken up by SMCs, regulating their functions and reducing hypertension-induced vascular injury by downregulating the expression levels of ACE1, TGF-β and CTGF. MiR-483-3p was also shown to protect ECs against endothelial-mesenchymal transition and inflammation in a recent study by Esmerats et al. (79). Hypertension in its early stages may increase miR-483 levels in ECs due to compensatory mechanisms, but as the disease progresses, this negative feedback effect is suppressed, and increased dysfunction occurs in ECs and SMCs, eventually leading to a decrease in miR-483-3p levels; thus, serum miR-483-3p levels are significantly reduced in patients with long-term chronic hypertension (78).

Tong et al. (80) isolated cells from the thoracic aortas of Wistar-Kyoto (WKY) rats and spontaneously hypertensive rats (SHRs) and found that exosomes released from SHR adventitial fibroblasts (AFs) transferred ACE to VSMCs, thereby increasing Ang II levels within VSMCs and activating AT₁R (Ang II [angiotensin II] type 1 receptor) to promote the migration of VSMCs. Subsequent studies demonstrated that miR-155-5p, which is derived from the EVs of AFs, protects the vasculature, while miR-135a-5p promotes structural changes in blood vessels. Compared to those in WKY rats, miR155-5p levels were reduced in EVs released from SHR extravascular fibroblasts. Intravenous delivery of EVs derived from WKY rats mediated miR155-5p transfer, thereby reducing ACE expression in VSMCs and the arterial blood of SHRs and attenuating vascular remodeling (81). In addition, elevated miR-135a-5p levels in the EVs of SHR AFs decreased FNDC5 expression in VSMCs (82). As FNDC5 can attenuate oxidative stress and inflammatory responses and inhibit the proliferation of VSMCs through the mitogen-activated protein kinase (MAPK) signaling pathway, miR-135a-5p delivery exacerbated VSMC proliferation and vascular remodeling (83, 84). Furthermore, Zou et al. (85) found that EVs from monocytes transferred miR-27a to ECs, decreased Mas receptor expression, reduced eNOS phosphorylation, impaired Ang-(1–7)-mediated vasodilation, and promoted hypertension.

Vascular calcification (VC) is an important phenotype of vascular aging that manifests not only in EH but also in atherosclerosis, chronic kidney disease and diabetes mellitus (86). Under normal physiological conditions, VSMCs exhibit a contractile phenotype and regulate microenvironmental homeostasis by actively releasing exosomes carrying endogenous inhibitors of calcification, such as fetuin A, matrix Gla protein (MGP), osteoprotegerin (OPG) and bone morphogenetic protein-7 (BMP-7), thereby inhibiting the development of VC (87). However, in pathological states, factors related to osteogenic differentiation exert their effects. For example, lipopolysaccharide (LPS)-treated macrophage-derived EVs are enriched in proinflammatory cytokines and CAD (cis-aconitate decarboxylase), PAI-1 (plasminogen activator inhibitor-1), and Saa3 (serum amyloid A-3 protein), creating an inflammatory microenvironment for surrounding cells, and these exosomes significantly increase the calcification of VSMCs by increasing the expression of osteogenic markers (osterix and osteocalcin) and decreasing the expression of a contractile marker (alpha-smooth muscle actin) (88). The mechanism by which nicotine promotes VC in clinical patients was revealed by Petsophonsakul et al. (89), who demonstrated that nicotine-induced activation of α7 and α3 nicotinic acetylcholine receptor (nAChR) increased intracellular Ca²⁺ levels and initiated the calcification of VSMCs through increased NADPH oxidase 5 (Nox5) activity, leading to oxidative stress-mediated exosomes release. A positive feedback loop between Ca²⁺, Nox5 and ROS was established that promoted VC and correlated with the action of exosomes. Specifically, Nox5-mediated oxidative stress led to the excessive production of ROS, resulting in increased intracellular Ca²⁺ and the increased release of large amounts of EVs from VSMCs; these exosomes were shown to induce calcification of the extracellular matrix (ECM) and increase the calcification of recipient VSMCs. Ca²⁺ uptake by cells via exosomes or Ca²⁺ channels further contributed to an increase in Nox5 activity (90). Under hyperglycaemic conditions, EV miR-32 in macrophages was upregulated and delivered to VSMCs, promoting osteogenic differentiation and inhibiting autophagy in VSMCs via the miR-32/Mef2d/cGMP-PKG signaling pathway (91). Lipoprotein(a) stimulation led to an increase in the annexin level in the EV cargo of primary human smooth muscle cells (SMCs) and valvular interstitial cells (VICs), and these EVs readily aggregated in the collagen matrix and induced its mineralization, leading to the formation of microcalcifications that coalesced into macrocalcifications (92). Calcifying exosomes may be involved in the formation of ectopic microcalcifications in the ECM of human arterial walls. This possibility offers a new perspective that differs from the previous suggestion that exosomes entering VSMCs alter their phenotype. Notably, warfarin increased ER stress via the UPR-PERK-ATF4 pathway, which further induced Grp78 to be loaded into EVs as cargo and promoted exosome release (93). Deposition of EV Grp78 in the ECM and action of Grp78 on the surface of VSMCs, i.e., the promotion of calcium phosphate crystal formation on the collagen matrix, caused VSMC calcification (93). The traditional oral anticoagulant warfarin may promote VC, whilst inhibition of ER stress represents a new therapeutic possibility.

Exosomes may also improve VC in the context of pharmacological intervention or under other conditions. For example, curcumin (CUR) and exosomes secreted by VSMCs after CUR intervention attenuated VC. In vitro, CUR intervention resulted in high miR-92b-3p expression in both VSMCs and exosomes and delivery of miR-92b-3p to adjacent cells, significantly reducing expression of the transcription factor KLF4 and osteogenic factor RUNX2 in VSMCs; in addition, in a rat calcification model, CUR attenuated vitamin D3-induced VC by increasing miR-92b-3p expression and decreasing KLF4 expression in the aorta (94). Melatonin induced VSMCs to produce exosomes carrying miR-204 and miR-211, which inhibited BMP-2 expression in adjacent cells in a paracrine manner and attenuated VC and senescence (95). Mansour et al. (96) found that the GFOGER peptide may be a novel and promising therapeutic target for decreasing VC, as GFOGER peptide treatment modulated the EV protein composition and inhibited the expression of osteogenic markers (Runt-related transcription factor 2, the matrix-Gla protein, osteocalcin, and tissue non-specific ALP) in VSMCs. Exosomes secreted by MSCs pretreated with advanced glycation end product-bovine serum albumin (AGE-BSA) contained a high level of miR-146a, which was transferred to VSMCs and inhibited AGE-BSA-induced calcification in a thioredoxin-interacting protein (TXNIP)-dependent manner. Thus, miR-146a-carrying exosomes may be a potential therapeutic target in VC (97). AGE stimulation resulted in the enrichment of miR-126-5P in EC-derived exosomes, which were subsequently delivered to VSMCs where they downregulated BMPR1B expression, blocking the Smad1/5/9 signaling pathway and negatively regulating calcification in VSMCs (98). The potential role for miR-126-5P in improving media calcification in the vasculature has been suggested (98).

Urinary albumin excretion (UAE) is an indicator of cardiovascular risk and renal damage in hypertensive patients, and Perez et al. (99) showed in an observational case–control study that plasma exosomal miR-126-3p and miR-26a-5p levels significantly differed between EH patients without UAE and healthy controls, and elevated plasma miR-126 levels were a marker of an increased risk of vascular injury and cardiovascular events and have potential value for early diagnosis. In addition, urinary and plasma exosomal miR-26a-5p and miR-222-3p levels were negatively correlated with UAE, and plasma exosomal miR-191-5p and miR-126-3p levels were positively correlated with the UAE rate in patients with EH plus UAE. MiR-26a-5p is an influential regulator of glomerular development and structure that protects kidney function in animal experiments (100), but its therapeutic value needs to be explored in depth. Riffo-Campos et al. (101) detected characteristic ncRNAs associated with hypertension-related UAE in urinary exosomes or plasma exosomes; among these ncRNAs were five lncRNAs (LINC02614, BAALC-AS1, FAM230B, LOC100505824, LINC01484) and miR-301a-3p, which play critical roles in regulating key pathways associated with filtration barrier integrity and tubular reabsorption and could be used to study the mechanisms of proteinuria and cardiovascular injury. Gonzalez et al. (102) studied urinary exosomal protein alterations in EH patients with renin-angiotensin system inhibition and found 21 proteins that may be associated with glycosaminoglycan degradation, coagulation and complement system abnormalities, and oxidative stress at 3 years of follow-up, and increases in urinary exosomal complement C3, complement C4a, and ceruloplasmin were predictive of de novo albuminuria in hypertensive patients.

Inflammation is a common mediator of many risk factors for AS, including levels of low-density lipoproteins and triglyceride-rich lipoproteins, as well as the altered behavior of cells of the artery wall. The ample preclinical implications of inflammation in AS have opened the door to many new therapeutic targets (109). Recent clinical trials have shown that targeting inflammation can reduce cardiovascular events even in individuals who have been treated with a full panel of effective standard therapies, with relevant anti-inflammatory drugs including canakinumab and colchicine (110, 111). Immune activation in AS concerns both innate and adaptive immunity, involving both immune cells and immune molecules (112). However, studies on intercellular exosome transfer have focused more on the relationship between innate immune cells and the vessel wall. In this section, we focus on the exosomes that cause arterial inflammation, which are mainly derived from inflammatory cells, ECs, and VSMCs.

The presence of a substantial number of intimal VSMCs, such as those involved in the formation of fibrous caps, has been suggested as evidence that VSMC migration and proliferation from the media play an important role in atherogenesis (143). Burtenshaw et al. found that phosphorylation of ERK and Akt was increased in VSMCs treated with foam cell-derived EVs (FC-EVs) and stimulated VSMC migration, and the researchers speculated by proteomic analysis that proteins in EVs might have played a role in this effect (144). In addition, FC-EVs could transfer integrins β1 and α5 to the surface of VSMCs and promote cell adhesion (144). Macrophage-derived EVs containing miR-19b-3p accelerated the migration and promotion of VSMCs by targeting JAZF1, which promoted the development of AS lesions in ApoE^−/− mice (145). Zhu et al. (136) showed that increased levels of exosomal miR-21-3p in nicotine-treated macrophages were transmitted to VSMCs and accelerated AS progression. MiR-21-3p binding sites were present in the 3′-UTR of PTEN, and miR-21-3p promoted the migration and proliferation of VSMCs by inhibiting PTEN. Ren et al. (146) showed that M1 macrophage-derived exosomal miR-186-5p levels were increased in response to ox-LDL stimulation and acted on VSMCs; miR-186-5p downregulated SHIP2 expression, enhancing cell viability, invasiveness, and the phosphatidylinositol-3-kinase/protein kinase B/mammalian target of rapamycin (PI3K/Akt/mTOR) pathway. Inhibition of the mTOR pathway has been shown to alleviate plaque progression and play a protective role against AS (147). Other researchers identified that miR-222 originating from M1 macrophage-derived exosomes triggered functional changes in VSMCs and confirmed that miR-222 played a key role in promoting VSMC proliferation and migration by targeting cyclin-dependent kinase inhibitor 1B (CDKN1B) and cyclin-dependent kinase inhibitor 1C (CDKN1C) in vitro (148). Li et al. (149) demonstrated that inflammatory CD137 signaling decreased the anti-inflammatory effects of ten-eleven translocation 2 (TET2) transfer from ECs to VSMCs, thereby accelerating VSMC proliferation and migration in vitro and neointimal formation in vivo. PVAT was shown to produce EVs containing miR-221-3p, which are subsequently taken up by neighboring VSMCs, leading to dramatically enhanced VSMC proliferation and migration (150). Mechanistically, EV-mediated miRNA-221-3p transport suppressed the downstream target PGC-1α (peroxisome proliferator–activated receptor γ coactivator 1α), a known metabolic modulator of VSMCs (150).

Co-incubation of oxidized low-density lipoprotein (ox-LDL) with human mononuclear cell lines (THP-1) can model foam cells in AS pathology. In vitro, exosomal lncRNA LIPCAR could be transferred from ox-LDL-treated THP-1 cells to VSMCs, resulting in the upregulation of CDK2 and PCNA, which remarkably promoted the viability and migration of VSMCs (151). Another study showed that miR-106a-3p was increased in exosomes from ox-LDL-induced THP-1 cells and could promote cell proliferation and repress cell apoptosis of VSMCs (152). It was proposed that exosome-derived miR-106a-3p could directly bind CASP9 and repress the caspase signaling pathway in VSMCs (152). In contrast, studies suggesting that exosomes may inhibit VSMC migration are uncommon. Exosomal LINC01005 from ox-LDL-treated ECs promoted VSMC phenotype switching, proliferation, and migration by regulating the miR-128-3p/KLF4 axis (153). KLF4 silencing and miR-128-3p mimic alone abrogated the ox-LDL-Exo-mediated promotion of VSMC phenotype switching, proliferation, and migration (153).

Hyperglycaemia is known to increase haemopoiesis in the bone marrow, thereby increasing the levels of monocytes and neutrophils, which readily enter the lesions of AS-susceptible mice and increase the burden on macrophages, accelerating AS (154). Compared to nondiabetic AS plaques, diabetic plaques are prone to becoming vulnerable AS plaques with abundant foam cells, larger necrotic core sizes, a greater extent of SMC, higher levels of macrophage apoptosis, and increased infiltration of inflammatory cells (155). Bouchareychas et al. (156) showed that exosomes from BMDMs exposed to high concentrations of glucose increased the number of hematopoietic and myeloid cells in the circulation of ApoE^−/− mice, leading to an increase in the number of macrophages in the lesion, as well as an increase in the area of apoptosis and AS progression. The mechanism involved the delivery of miR-486-5p via BMDM-derived exosomes to macrophages and a significant reduction in ABCA1 mRNA expression in macrophages. Liu et al. (157) also demonstrated that miR-486-5p reduced ABCA1 expression in THP-1 macrophages. Wang et al. (158) showed that insulin-resistant adipocytes increased the vulnerability of aortic plaques in diabetic ApoE^−/− mice by secreting exosomes containing sonic hedgehog (shh). The factor shh activated intracellular pathways by binding the Patched (Ptch) receptor on recipient cells (HUVECs and murine aortic endothelial cells), increasing the expression levels of TNF-α, IL-1β, IL-6, vascular endothelial growth factor A (VEGF-A), ICAM-1, matrix metalloproteinase-2 (MMP2), and MMP9 in plaques and promoting vasa vasorum (VV) angiogenesis. The VV is an important entry pathway for immune cells, promoting the development of chronic inflammatory and necrotic cores and leading to plaque instability (159).

VSMC necrosis and apoptosis play progressive roles in plaque instability and AS lesions, and the migration of VSMCs accelerates AS progression despite the possible role of these cells in stabilizing the fibrous cap (160). Wang et al. (161) showed that macrophage-derived EVs carrying miR-503-5p inhibited the proliferation, migration and angiogenesis of HCAECs while promoting the proliferation and migration of human coronary artery smooth muscle cells (HCASMCs) by downregulating Smad7, smurf1, and smurf2 and elevating TGF-β1, thereby exacerbating AS. In VSMCs, exosomal miR-223, miR-339, and miR-21 from thrombin-activated platelets inhibited the proliferation of VSMCs by reducing the expression of PDGF receptors. Because reduced PDGF receptor expression was also observed in VSMCs surrounding thrombotic areas in vivo, these miRNAs may be biomarkers for predicting atherosclerotic thrombosis (162). Another study showed that platelet-derived exosomes inhibited thrombogenesis in AS by reducing macrophage CD36-dependent lipid loading and inhibiting platelet aggregation (163).

There is proof that BMPR2 is closely linked to miRNAs in the pathological alterations associated with PAH. A decline in BMPR-2 signaling in patients with hereditary PAH (HPAH) was shown to cause a decrease in miR-27 in ECs and an increase in translationally controlled tumor protein (TCTP) expression, resulting in EC resistance to apoptosis in patients with HPAH (184). In IPAH patients and animal models of PAH, the BMPR2 protein may be decreased even when the gene is normally expressed, indicating that the inhibition of BMPR2 transcription by miRNAs plays an important role in the pathogenesis of PAH. The depletion of miR-20a could restore BMPR2 signaling and attenuate the development of hypoxic PAH (185). IPAH patients with BMPR2 mutations have significantly more exosomes released from blood outgrowth ECs (BOECs) and contain more TCTP, which is transferred to pulmonary arterial smooth muscle cells (PASMCs), decreases caspase-3 activity and contributes to cell resistance to apoptosis (186). TCTP has potential value for diagnosing or assessing the severity of PAH. Zhang et al. (187) showed that exosomal miR-191 released from adipose-derived mesenchymal stem cells (ASCs) regulated the proliferation of pulmonary artery endothelial cells (PAECs) in vitro, and higher miR-191 levels were associated with faster PAEC proliferation and vice versa. In addition, miR-191 overexpression has been shown to be associated with PAH (188). MiR-191 antagonists reduced right ventricular systolic pressure (RVSP), increased BMPR2 levels in MCT-PAH rats and relieved PAH. The miR-191 inhibitor may have potential therapeutic value by preventing BMPR2 degradation to improve PAH. Zhang et al. (189) treated MCT-induced PAH mice with of MSC-derived exosomes via tail vein injection for 3 weeks and concluded that MSC-derived exosomes significantly reduced RVSP and the right ventricular hypertrophy index and attenuated pulmonary vascular remodeling and pulmonary fibrosis in vivo. In vivo and in vitro experiments confirmed that MSC-derived exosomes could regulate the Wnt5a/BMP signaling pathway in PAECs and PASMCs, including upregulating the expression of Wnt5a, Wnt11, BMPR2, BMP4, and BMP9 and downregulating the expression of β-catenin, cyclin D1, and TGF-β1.

In PAH and cancer, mitochondrial metabolism and redox signaling are reversibly disordered, creating a pseudohypoxic redox state characterized by normoxic decreases in ROS, a shift from oxidative to glycolytic metabolism, and hypoxia-inducible factor-1α (HIF-1α) activation (190, 191), which lead to sustained ATP production, uncontrolled cell growth and cellular resistance to apoptosis (192–194). Kumar et al. (195) showed that AFs obtained from humans with PAH and calves with hypoxia-induced PAH secreted exosomes containing complement C3, which mediated BMDM activation toward a proinflammatory and metabolically altered phenotype in vitro, and the latter was characterized by increased aerobic glycolysis and the accumulation of succinic acid. Mitochondrial dysfunction in PAH might cause alterations in circulating exosomes, i.e., low expression of the proliferator-activated receptors gamma-coactivator 1-alpha and sirtuin 1 in exosomes, and circulating exosomes affect on other organs, such as the brain (196). Researchers observed upregulated expression of manganese SOD, downregulated expression of HIF-1α and the preservation of antioxidant enzyme expression in the brain, explaining the potential role of exosomes in PAH and antioxidant defense mechanisms in protecting cells from disease progression (196, 197). As hypoxia exposure increases, sirtuin 4 (SIRT4) gene expression also increases, and Hogan et al. (198) showed that the administration of MSC-secreted exosomes to PASMCs inhibited SIRT4 and pyruvate dehydrogenase kinase 4 (PDK4) expression, upregulated pyruvate dehydrogenase (PDH) and glutamate dehydrogenase 1 (GLUD1) expression levels, allowed glutamine and pyruvate to enter the TCA cycle and improved mitochondrial dysfunction associated with PAH. Other studies have also suggested that some exosomes may contain mitochondrial material (38, 199), but their association with PAH-related cancer-like metabolism remains to be further investigated.

Intercellular communication between ECs and other components of the pulmonary vascular wall is a critical signature of PAH pathogenesis (168). In an in vitro healing assay, Deng et al. (200) demonstrated the involvement of miR-143 in intercellular communication between PASMCs and PAECs, as miR-143 induced the migration of PAECs and reduced the death of PAECs. In a mouse hypoxia model, miR-143-3p expression was upregulated in the whole lung and right ventricle. Furthermore, histopathological and haemodynamic data collected under hypoxic conditions showed significantly reduced pulmonary vascular remodeling in miR-143^−/− mice compared to wild-type mice. The expression levels of miR-143-3p and miR-143-5p were also significantly upregulated in PASMCs from PAH patients compared to healthy controls. Anti-miR-143 treatment reversed hypoxia-induced RVSP elevation and right ventricular hypertrophy and reduced vascular remodeling in mice. Zhang et al. (201) showed that hypoxia increased the secretion of exosomes from PAECs to exert their proliferative effects on recipient PAECs in a paracrine or autocrine manner, which was attributed at least partially to the enrichment of lipid-peroxidizing enzyme 15-lipoxygenase2 (15-LO2) in exosomes, which then activated the STAT3 signaling pathway. Aliotta et al. (202) showed that exosomal miRNAs that were commonly increased in MCT-PAH mice and IPAH patients included the miR-17-92 cluster, miR-21 and miR-145. Among them, the miR-17-92 cluster (including miR-17, miR-18a, miR-19a, miR-20a, miR-19b-1, and miR-92-1) is a well-characterized family of miRNAs that are known to play an important role in the regulation of cell proliferation and apoptosis (202). Khandagale et al. (203) confirmed that the expression of miR-486-5p and miR-26a-5p was altered in circulating exosomes from the plasma of PAH patients and found that overexpression of miR-486-5p and downregulation of miR-26a-5p induced the proliferation of PAECs as well as the transcription and protein expression of VEGF, partly by targeting NF-κB signaling. However, some studies on myocardial infarction and cancer have shown that PTEN, PIK3R1, and MMPs may be downstream target genes of miR-26a and miR-486-5p (204–207).

Uncontrolled EC proliferation is the main contributor to the characteristic plexiform lesions of PAH, but it is undeniable that medial thickening caused by SMC proliferation is also involved in vascular remodeling in PAH (208); however, there have been few relevant exosomal studies. In vitro, miR-181 and miR-324 in exosomes released by KLF2-overexpressing PAECs were found to be elevated and transmitted to PASMCs, in which they alleviated hypoxia and platelet-derived growth factor (PDGF)-induced cell proliferation (209). MiR-181a-5p and miR-324-5p act together to attenuate pulmonary vascular remodeling, and their actions are mediated by Notch4, ETS1 and other key regulators of vascular homoeostasis (209). Researchers have demonstrated that therapeutic supplementation with miR-181a-5p and miR-324-5p reduced proliferative and angiogenic responses in patient-derived cells and attenuated disease progression in PAH mice (209). Zhang et al. (210) identified a role for the HIF-1-let-7b-ACE2 axis: miR-let-7b expression was elevated in rat lungs under chronic hypoxic conditions, and in vitro and in vivo experiments showed that let-7b promoted PAH by inhibiting ACE2 expression and thus inducing PASMC proliferation and migration. Nevertheless, in contrast to the above, Wang et al. (211) concluded that let-7b-5p, miR-92b-3p and miR-100-5p in human neural stem cell line (ReNcell)-derived EVs reduced vascular remodeling and RVSP in Su/Hx mice. Chen et al. (212) found that PVEC-derived EVs contained both miR-210-3P, which promoted the proliferation of PASMCs, and miR-3,057-5P, 212-5P and 34C-3P, which inhibited the proliferation of PASMCs; however, it is noteworthy that these EVs are more likely to be microvesicles than exosomes.

Pulmonary vascular ECs in PAH release specific populations of exosomes and can induce PAH alterations in healthy lungs; a positive feedback loop that propagates vascular remodeling may exist, and although it is difficult to completely reverse PAH (202), MSC-derived exosomes provide hope. Aliotta et al. (202) showed that miRNAs isolated from MSC-derived exosomes had increased levels of anti-proliferative and anti-inflammatory miRNAs, including miRs-34a, −122, −124, and −127. Other studies confirmed that MSC-derived exosomes or EVs could improve PAH by inhibiting cell proliferation and inflammatory responses. Lee et al. (213) showed that intravenous injection of MSC-derived exosomes inhibited vascular remodeling and hypoxic pulmonary hypertension. Mechanistically, MSC-derived exosomes suppressed the hypoxic activation of STAT3 and the upregulation of the miR-17 superfamily of microRNA clusters, whereas they increased lung levels of miR-204, which had pleiotropic protective effects on the lung and suppressed PAH by inhibiting the hyperproliferative pathway. MSC-derived EVs also induced macrophage polarization toward the M2 type and partially inhibited the inflammatory response of macrophages (134). Klinger et al. (214) studied a Sugen5416/hypoxia-induced PAH rat model and showed that MSC-EVs reduced macrophage recruitment, promoted a shift from an inflammatory to a reparative macrophage phenotype, promoted angiogenesis, and reduced the expression of inflammatory cytokines such as IL-6, macrophage inflammatory protein 2 (MIP-2) and TNF-α. The researchers (214) also noted that miR-196b levels were hundreds of times higher in MSC-EVs than in fibroblast-derived EVs, that HOXA5 expression was increased in PAH patients and that miR-196b reduced HOXA5 expression (215, 216). However, other studies have shown that HOXA5 can inhibit the release of inflammatory factors from macrophages (217). Therefore, it is unclear whether miR-196b plays a role in the reversal of PAH mediated by MSC-EVs. Several reports on lung injury have shown that MSC-EVs reduced macrophage recruitment in lung tissue, reduced macrophage expression of proinflammatory cytokines associated with the development of PAH, such as IL-6, MIP-2, and TNF-α, limited alveolar injury in animal models of acute lung injury and attenuated PAH in animal models of bronchopulmonary dysplasia (134, 214). In addition, Li et al. (218) showed that miR-150 prevented hypoxia-induced pulmonary vascular remodeling, fibrosis, and abnormal proliferation in PASMCs and PAECs.