Asthma is a chronic respiratory disease characterized by recurrent episodes of airway inflammation, bronchoconstriction and hyperresponsiveness. It affects >300 million individuals globally and contributes to increasing morbidity and healthcare costs (1,2). The etiopathogenesis of asthma involves crosstalk between genetic predispositions and environmental factors, including allergens, infections and pollutants (3). Pathologically, asthma is marked by chronic inflammation of the airway, leading to structural changes and functional impairment (4). Patients with asthma present with intermittent and variable symptoms such as wheezing, shortness of breath, chest tightness and coughing, which result primarily from reversible airway obstruction and vary in intensity and frequency (5,6). Severity of symptoms ranges from mild to life-threatening exacerbations that may require emergency medical intervention (7). Factors such as respiratory infection, allergens and irritants can trigger these exacerbations, highlighting the need for effective long-term management strategies (8).

Current therapeutic strategies for asthma aim to relieve symptoms, improve lung function and decrease the frequency and severity of exacerbations (9). Primary therapeutic approaches include inhaled corticosteroids, long-acting β-agonists, leukotriene modifiers and monoclonal antibodies that target specific immune pathways (10,11). However, these treatments do not fully address the underlying mechanisms of airway remodeling and chronic inflammation, leading to persistent disease progression in patients with poor asthma control and frequent exacerbations (12,13). Therefore, novel therapeutic strategies are needed.

Mesenchymal stem cells (MSCs) are multipotent stromal cells that differentiate into various cell types, including osteocytes, chondrocytes and adipocytes (14). Extracellular vesicles (EVs) are a broad class of vesicles that are secreted by cells into the extracellular space. They can be classified into three subtypes, exosomes, microvesicles and apoptotic bodies, based on their size and mode of release. Exosomes are the smallest subtype of EV, typically 30–150 nm in diameter, and serve key roles in intercellular communication and disease mechanisms (15). MSC-derived exosomes mediate therapeutic effects of MSCs, and have a key role in cell-to-cell communication by transferring bioactive molecules to recipient cells, affecting their behavior and function (16,17). In asthma, MSC-derived exosomes exert immunomodulatory effects that maintain immune homeostasis and suppress excessive immune responses (18,19). Additionally, they exhibit anti-inflammatory effects by inhibiting inflammation-associated signaling pathways and reducing the levels of pro-inflammatory cytokines, which are beneficial in treating asthma (20,21). Compared with drugs targeting IL-4 and IL-5, such as dupilumab and mepolizumab, MSC-derived exosomes offer a potential advantage by providing a more natural and less invasive approach to modulating immune responses (22). They exert long-term effects because of their ability to simultaneously influence multiple cellular pathways (8). While drugs are designed to target specific cytokines, MSC-derived exosomes serve as a multi-target therapy, potentially exerting more comprehensive effects on asthma (23).

The present review discusses the pathogenesis of asthma and the basics of MSC-derived exosomes and emphasizes their potential therapeutic effect, as well as the prospects and challenges of translating MSC-derived exosome therapy from bench to bedside.

Asthma is characterized by chronic airway inflammation involving immune cells such as eosinophils, T lymphocytes, mast cells and dendritic cells. These cells release cytokines and chemokines, which perpetuate the inflammatory response and facilitate airway hyperresponsiveness and tissue damage (24,25). These immune cells serve a key role in airway inflammation during disease progression. For example, eosinophils secrete pro-inflammatory cytokines, chemokines, growth factors and lipid mediators that disrupt pulmonary homeostasis and induce inflammatory airway damage (26). They regulate immune responses by modulating T helper 2 (Th2) cell activation, M2 macrophage polarization and group 2 innate lymphoid cell (ILC2) differentiation, as well as upregulating the levels of IL-5 and IL-13, which primarily induce inflammatory tissue damage (27,28). Mast cells, in combination with IgE, are key for initiating inflammation in allergic asthma (29). They release histamine and other inflammatory mediators that contribute to bronchoconstriction and further inflammation (30). Neutrophils, particularly in severe asthma, release nuclear proteins and serine proteases that form neutrophil extracellular traps, which activate inflammasomes in monocytes or macrophages, leading to increased expression of inflammatory cytokines (31).

Chronic inflammation in asthma leads to structural airway alterations, collectively termed airway remodeling (1). This includes epithelial damage, mucous gland hyperplasia, subepithelial collagen deposition and increased proliferation of airway smooth muscle cells (ASMCs) (32–34). These changes cause persistent airflow limitation and airway hyperresponsiveness (35). Airway remodeling is driven by numerous factors, including transforming growth factor (TGF)-β, primarily secreted by bronchial epithelial cells and eosinophils (36). TGF-β promotes extracellular matrix deposition by stimulating fibroblasts and myofibroblasts to produce collagen and fibronectin, contributing to airway hyperresponsiveness (37). However, TGF-β exerts both pro-inflammatory and immunosuppressive effects in asthma during airway inflammation depending on cellular context. Elevated TGF-β1 expression in asthmatic airways aggravate eosinophilic inflammation by activating CD8⁺ T cells while inhibiting Th1 and Th2 cell differentiation (38). It also modulates regulatory T cell (Treg) differentiation and limits the pathogenicity of CD4⁺ T cells, thereby alleviating airway inflammation (39).

Numerous signaling pathways contribute to asthma pathogenesis. The NF-κB pathway regulates airway inflammation (40). Various stimuli, including pro-inflammatory factors, viruses, drugs and cigarette smoke, activate NF-κB (41). Once activated, NF-κB translocates to the nucleus and upregulates inflammatory gene expression (42). Another key signaling cascade in asthma is the toll-like receptor 4 (TLR4)/myeloid differentiation primary response 88 (MyD88) pathway (43). Lipopolysaccharide (LPS) binding to TLR4 activates MyD88, leading to NF-κB nuclear translocation and amplification of the inflammatory response (44). Moreover, the phosphatidylinositol 3-kinase (PI3K)/Akt and Wnt/β-catenin signaling pathways are implicated in airway remodeling and hyperresponsiveness (45,46). These pathways contribute to ASMC proliferation and migration and epithelial-mesenchymal transition (EMT), enhancing airway remodeling (47,48).

MSCs were first identified by Friedenstein et al (49) in the 1960s when they isolated fibroblast colony-forming units from bone marrow. MSCs are present in virtually all postnatal organs and tissues, including the bone marrow, adipose tissue, umbilical cord and placenta (50,51). MSCs express specific surface markers such as CD73, CD90 and CD105 but lack hematopoietic markers such as CD34 and CD45 (52). MSCs can differentiate into osteoblasts, adipocytes and chondroblasts, making them promising candidates for therapeutic application due to their plasticity (53,54).

Exosomes are small EVs ranging from 30 to 150 nm in diameter, released by various cell types into the extracellular environment (55). They originate within the endosomal compartment of the cell and are secreted when multivesicular bodies fuse with the plasma membrane (56) (Fig. 1). Exosomes carry proteins, lipids and nucleic acids, reflecting the content and physiological state of the originating cells (57). This cargo includes mRNA, microRNAs (miRNAs or miRs) and other non-coding RNAs (58–60). The biological properties of exosomes make them key mediators of intercellular communication (61). They influence target cells by transferring their cargo, thereby modulating cellular processes, such as proliferation, differentiation and immune responses (62).

Numerous methods have been developed for exosome isolation and characterization, which are key for studying their biological functions and clinical application. Ultracentrifugation is the most commonly used technique, and is considered the gold standard for exosome isolation. It involves sequential centrifugation steps to remove cells, apoptotic bodies and other EVs, followed by high-speed ultracentrifugation to pellet exosomes (63). By using sucrose or iodixanol gradients to separate exosomes based on density, density gradient centrifugation refines ultracentrifugation and improves purity by separating exosomes from contaminants (64). Size-exclusion chromatography separates vesicles based on size using porous columns, allowing exosomes to be eluted while smaller proteins and particles are retained, which maintains exosome integrity and biological activity (65). Additionally, polymer-based precipitation uses polymers such as polyethylene glycol to precipitate exosomes from biofluids, followed by low-speed centrifugation to collect the pellet, which is suitable for processing large sample volumes (66). For small sample volumes, microfluidic platforms use nanoscale filtration, immunoaffinity capture or acoustic forces to isolate exosomes with high precision (67). Serving as a highly specific isolation method for exosome subpopulations, immunoaffinity-based isolation uses antibodies targeting exosome surface markers conjugated to magnetic beads or chromatography matrices (68). Standard characterization techniques of exosomes include morphological analysis, size determination, marker profiling and functional validation. Nanoparticle tracking analysis measures the size distribution and concentration of exosomes in a liquid suspension based on Brownian motion (69). Transmission electron microscopy provides high-resolution images of exosomes, allowing visualization of their characteristic cup-shaped morphology (70). By analyzing scattered light fluctuations, dynamic light scattering determines the hydrodynamic diameter of exosomes (71). In addition, western blotting detects exosome-specific protein markers, whereas flow cytometry allows high-throughput analysis using fluorescently labeled antibodies (72). Thus, the combination of multiple techniques can ensure accurate identification and functional validation. Future research should focus on developing standardized protocols and scalable isolation techniques to enhance reproducibility and facilitate clinical translation.

MSC-derived exosomes are key for mediating the therapeutic effects of MSCs. They promote tissue repair and regeneration by transferring growth factors and miRNAs that enhance cell proliferation and differentiation (73). In addition, they modulate immune responses by altering the phenotype and function of immune cells such as T and B cells and macrophages (74). MSC-derived exosomes suppress pro-inflammatory cytokine production and induce anti-inflammatory cytokine release (75). By inhibiting inflammation-associated signaling pathways such as NF-κB, they decrease pro-inflammatory cytokines levels and exert potent anti-inflammatory effects (76). These properties make MSC-derived exosomes promising therapeutic tools for inflammatory and degenerative disease. Their ability to mimic MSC functions while avoiding the risks associated with direct cell transplantation makes them attractive candidates for clinical application.

MSC-derived exosomes offer a novel therapeutic approach for asthma with the potential to modulate immune responses, decrease inflammation and repair airway damage (83,86). Their ability to deliver bioactive molecules such as proteins, lipids and nucleic acids to target cells makes them a versatile tool for therapeutic intervention. The immunomodulatory and anti-inflammatory properties of MSC-derived exosomes have been demonstrated in various preclinical models (103–105), demonstrating promise for decreasing asthma symptoms and improving lung function.

Despite their therapeutic potential, several challenges must be addressed before MSC-derived exosomes can be translated into clinical application. First, standardizing exosome isolation and characterization methods is essential to ensure reproducibility and consistency. Different techniques used to isolate exosomes, such as ultracentrifugation, size exclusion chromatography and immunoaffinity capture, yield exosomes with varying purity and characteristics, potentially affecting their therapeutic efficacy. Secondly, understanding the pharmacokinetics and biodistribution of MSC-derived exosomes is key for optimizing their therapeutic use. The mechanisms underlying their uptake, distribution and clearance in vivo need to be investigated to improve targeted delivery to the lungs and minimize off-target effects. Additionally, the potential immunogenicity and long-term safety of MSC-derived exosomes require evaluation in both preclinical and clinical studies.

Further research is essential to elucidate the therapeutic potential of MSC-derived exosomes. Future studies should focus on defining their mechanisms of action, determining optimal dosing regimens and exploring combination therapies to enhance their efficacy. Advances in exosome engineering may enable the customization of exosome content and surface modification to improve their targeting and therapeutic effects. Moreover, the development of advanced delivery systems to enhance targeted lung delivery is key for maximizing the therapeutic potential of MSC-derived exosomes.