AS and AR are generally IgE-mediated type I allergic diseases (Figure 1). When individuals are exposed to allergens, activated B cells differentiate into plasma cells and subsequently synthesize and secrete specific IgE (sIgE), which binds to high-affinity receptors on the surface of inflammatory cells, such as mast cells and basophils, resulting in a state of sensitization. When exposed to the same allergens again, sIgE antibodies can recognize the allergens and cause a cross-linking reaction, leading to the activation and degranulation of inflammatory cells to release a variety of inflammatory mediators, such as the classic histamine, LT, bradykinin, and prostaglandin, eventually leading to both acute and chronic inflammation, airway smooth muscle contraction, and increased secretion of mucus, etc. (20, 21).

Histamine, bradykinin, and prostaglandin are all known to have a diastolic effect on vascular smooth muscle and can enhance vascular permeability (22, 23). LT can also increase vascular permeability (23). These features may cause a reduction in venous return and inevitably result in relative central hypovolemia, which can be exacerbated by an upright position and facilitate orthostatic intolerance. However, whether these inflammatory mediators play a role in the mechanism of pediatric VVS and POTS still needs to be confirmed.

In addition to the direct role of these classic mediators, the complex interactions among the allergy-related inflammatory mediators may provide some clues for the comorbidity. For example, LT, one of the essential factors in the allergic response, can interact with other factors, such as endothelin (ET) and tumor necrosis factor α (TNF-α) (24) (Figure 2). Studies have shown that ET-1 (25) and TNF-α (26) can induce the production of leukotriene C₄ (LTC₄) by acting on mast cells as well as eosinophils. Conversely, studies in vitro have shown that leukotriene D₄ (LTD₄) can induce the production of TNF by stimulating the high-affinity receptor on alveolar macrophages (27) and that LTC₄ can also regulate the production of ET-1 (28). Interestingly, previous studies have shown that plasma ET levels were increased in children with VVS (29), suggesting an imbalance of vascular tone regulators in children with NMS. Similar to the findings in NMS children, plasma ET-1 levels in children with AS significantly increase in the acute attack stage compared with the remission stage (30). ET-1 is also elevated in the airway epithelium and involved in bronchoconstriction and airway remodeling in patients with AS (31, 32), indicating that ET may be a candidate factor related to the pathogenesis of the comorbidity of NMS and AS in children. For TNF, Gallegos (33) found that soluble tumor necrosis factor receptor 1 (sTNFR1) was detected in the blood of pediatric patients with VVS. Under the influence of predisposing factors, such as prolonged standing and postural changes, sTNFR1 was suddenly reduced, and its inhibitory effect on TNF was weakened, subsequently increasing the secretion of prostaglandin E₂ and nitric oxide (NO) and leading to vasodilation and syncopal attacks. Nevertheless, the role of TNF in the pathogenesis of comorbidity needs further exploration in the future.

Other vasoactive factors are involved in AS and can cause vasodilation and enhance microvascular permeability. When the sensory nerve endings are exposed to antigens or inflammatory mediators due to damage of the top covered airway epithelium, they can reversibly release a group of neuropeptides, such as neurokinin A, calcitonin-related peptides, substance P, bradykinin, tachykinin, and neuropeptide Y, which may lead to bronchial constriction, microvascular leakage, and mucus hypersecretion (34–36). Among them, calcitonin-related peptides, substance P, bradykinin, and tachykinin all have the effect of vasodilatation; in contrast, neuropeptide Y exerts the effect of vasoconstriction. It was reported that the plasma neuropeptide Y level was significantly decreased (37) and substance P was increased (38) in children with VVS in the supine position. It is worth further exploring whether these vasoactive neuropeptides are involved in the pathogenesis of the comorbidity.

NO is an active gasotransmitter that is released when L-arginine transforms into L-citrulline by oxidation under the catalytic action of nitric oxide synthase (NOS) (39). NO can pass through biofilms by free diffusion and play an extensive regulatory role in the nervous, immune, and cardiovascular systems. NO is reported to be involved in the pathogenesis of both pediatric AS and NMS (40–42). In the pathogenesis of AS, exposure to allergens induces helper T cell type 2 (Th2) to produce a series of inflammatory mediators, such as interleukin-4 (IL-4), interleukin-5 (IL-5), and interleukin-13 (IL-13). IL-5 promotes the aggregation of eosinophils (43), and IL-4 and IL-13 trigger downstream signaling and upregulate the synthesis of inducible nitric oxide synthase (iNOS) mRNA, leading to a significant increase in the levels of fractional exhaled nitric oxide (FeNO) (44). iNOS can be detected in the airway epithelial cells of patients with AS (45), and the levels of FeNO in AS are significantly increased (42). Therefore, it is supposed that NO plays an important role in the pathogenesis of AS. A guideline on pediatric pulmonary function and airway nontraumatic inflammation indicators suggests that FeNO is an airway inflammation indicator and a noninvasive indicator that can be used to measure the levels of eosinophilic inflammation in children with AS (46). There is also evidence for interactions between NO and LT (Figure 2), which may be another way that NO participates in the pathogenesis of allergic diseases. For example, NO (47) can increase the production of LT through human mast cells, and leukotriene B₄ (LTB₄), LTC₄, and LTD₄ can promote NO release by activating polymorphonuclear granulocyte surface receptors (48). Studies about the role of NO in pediatric NMS have focused on vascular endothelium-derived NO. Previous studies have shown that children with both POTS and VVS had increased plasma NO levels and significantly enhanced flow-mediated vasodilation (FMD) (40, 41, 49). Moreover, NOS activity was enhanced and was proportional to FMD in children with POTS (40). Genotype analysis of the NOS gene also revealed that greater endothelial NOS activity may be associated with the pathogenesis of POTS (50). These results indicated abnormal vascular endothelial function in children with VVS and POTS, which may result in enhanced vasodilatation and peripheral blood pooling when upright, exacerbating orthostatic intolerance. Another study explored the vascular endothelial function as well as the arterial stiffness using the reactive hyperemia index (RHI) and augmentation index (AIx). However, there was no significant difference in vascular endothelial function between AS and the control group although poorer arterial elasticity was found in the AS group (51). In another study, it was shown that FMD was decreased in children with AS and that reduced FMD was correlated with the decreased forced expiratory volume in 1 second (FEV₁) and the function of the small airway, suggesting that vascular endothelial dysfunction exists in children with AS (52). Because NO plays a significant role in the pathogenesis of both pediatric NMS and AS, it is worth researching FeNO as well as circulatory NO levels in children with allergic diseases comorbid with NMS to find the possible influence of NO in the comorbidity.

Dysregulation of peripheral vascular tone and relative central hypovolemia are important pathogenesis mechanisms that cannot be ignored in children with NMS. Therefore, whether the known allergy-related vasoactive factors contribute to the relative central hypovolemia by enhancing vasodilation and/or increasing vascular permeability in children with the comorbidity of NMS and allergic diseases remains to be further studied. Additionally, the mechanisms for mutual regulation among each factor are not fully understood.