The Immunopharmacology Research Group, University of Tampere School of Medicine and Tampere University Hospital, Tampere, Finland.
Pediatr Allergy Immunol. 2012 Jun;23(4):360-6. doi: 10.1111/j.1399-3038.2011.01223.x. Epub 2011 Dec 7.
Exercise challenge test is widely used in diagnostics and follow-up of childhood asthma, but the method is complex, time consuming, and expensive. In this study, we aimed to find out whether flow-independent nitric oxide (NO) parameters (bronchial NO flux [J'aw(NO)] and alveolar NO concentration [CA(NO)]) predict exercise-induced bronchoconstriction (EIB) in atopic children and adolescents with asthma-like symptoms. Also, the respective NO parameters corrected for axial backward diffusion (J'aw(NO) [TMAD] and CA(NO) [TMAD]) were calculated and included in the analysis.
Thirty patients (6-19 yr old) with confirmed atopy (positive skin prick tests or allergen-specific IgE) and asthma-like respiratory symptoms were included in the study. Before the current investigations, none of the patients had been diagnosed to have asthma and none were on inhaled corticosteroids. Exhaled NO was measured at multiple exhalation flow rates, and exercise challenge test was carried out. Bronchial NO flux and alveolar NO concentration were calculated according to the linear method with and without correction for axial backward diffusion. Sixty-six healthy school children served as controls.
The patients were divided into two groups according to EIB. Patients with EIB (EIB+ group, n = 18) had enhanced bronchial NO output as compared to patients without EIB (EIB- group, n = 12); but the EIB- group did not differ from healthy controls. EIB+ group had also higher alveolar NO concentration than EIB- group and healthy controls, but EIB- group did not differ from healthy controls. When bronchial NO flux and alveolar NO concentration were corrected for axial diffusion, J'aw(NO) (TMAD) had equal difference as J'aw(NO) between the groups as expected. However, only EIB+ had higher CA(NO) (TMAD) than healthy controls, and the patient groups did not differ from each other. In patients, bronchial NO output correlated with the magnitude of exercise-induced change in PEF (r(s) = -0.388, p = 0.034), FEV(1) (r(s) = -0.395, p = 0.031), and FEF(50%) (r(s) = -0.431, p = 0.020), i.e., the higher the bronchial NO output, the larger the decrease in PEF/FEV(1) /FEF(50%) . Alveolar NO concentrations correlated with the change in FEV(1) (r(s) = -0.439, p = 0.015), FEF(50%) (r(s) = -0.454, p = 0.013), FEF(75%) (r(s) = -0.447, p = 0.017), and FVC (r(s) = -0.375, p = 0.045). For J'aw(NO) (TMAD), the correlations and p-values were equal to those of J'aw(NO) , but, interestingly, CA(NO) (TMAD) had no significant correlations with any of the exercise-induced changes in lung function.
The results showed that in atopic children and adolescents, increased bronchial NO output as well as J'aw(NO) (TMAD) were associated with EIB, while alveolar NO concentration (but not CA(NO) [TMAD]) correlated with the degree of obstruction in smaller airways induced by exercise challenge.
运动激发试验广泛应用于儿童哮喘的诊断和随访,但该方法复杂、耗时且昂贵。本研究旨在探讨气道非依赖性一氧化氮(NO)参数(支气管NO 通量[J'aw(NO)]和肺泡 NO 浓度[CA(NO)])是否可预测伴有类似哮喘症状的特应性儿童的运动激发后支气管收缩(EIB)。此外,还计算了分别校正轴向反向扩散的相应 NO 参数(J'aw(NO)[TMAD]和 CA(NO)[TMAD])并纳入分析。
本研究纳入 30 例(6-19 岁)已确诊特应性(皮试阳性或过敏原特异性 IgE 阳性)且伴有类似哮喘呼吸道症状的患者。在进行目前的研究之前,这些患者均未被诊断为哮喘,也未使用吸入性皮质激素。在多个呼气流量下测量呼出气一氧化氮,进行运动激发试验。根据线性方法计算并校正轴向反向扩散后,得出支气管 NO 通量和肺泡 NO 浓度。66 名健康学龄儿童作为对照组。
根据 EIB 结果,患者被分为两组。EIB 阳性组(EIB+组,n = 18)的支气管 NO 输出明显高于 EIB 阴性组(EIB-组,n = 12);但 EIB-组与健康对照组无差异。EIB+组的肺泡 NO 浓度也高于 EIB-组和健康对照组,但 EIB-组与健康对照组无差异。当校正轴向扩散后,支气管 NO 通量和肺泡 NO 浓度的 J'aw(NO)(TMAD)与预期一样,与组间差异相等。然而,只有 EIB+组的 CA(NO)(TMAD)高于健康对照组,且患者组之间无差异。在患者中,支气管 NO 输出与运动引起的 PEF 变化幅度呈负相关(r(s) = -0.388,p = 0.034),与 FEV(1)(r(s) = -0.395,p = 0.031)和 FEF(50%)(r(s) = -0.431,p = 0.020)的变化也呈负相关,即支气管 NO 输出越高,PEF/FEV(1)/FEF(50%)的下降幅度越大。肺泡 NO 浓度与 FEV(1)(r(s) = -0.439,p = 0.015)、FEF(50%)(r(s) = -0.454,p = 0.013)、FEF(75%)(r(s) = -0.447,p = 0.017)和 FVC(r(s) = -0.375,p = 0.045)的变化呈负相关。对于 J'aw(NO)(TMAD),相关性和 p 值与 J'aw(NO)相同,但有趣的是,CA(NO)(TMAD)与运动引起的任何肺功能变化均无显著相关性。
结果表明,在特应性儿童和青少年中,支气管 NO 输出增加以及 J'aw(NO)(TMAD)与 EIB 相关,而肺泡 NO 浓度(但不是 CA(NO)(TMAD))与运动激发引起的较小气道阻塞程度相关。
