Yamamoto Naho, Kasuga Saki, Kabata Daijiro, Ono Myu, Ando Sakura, Hashimoto Taisuke, Fujikawa Shiori, Fujitani Hiroko, Shintani Ayumi, Hamazaki Takashi
Department of Pediatrics, Osaka Metropolitan University Graduate School of Medicine, Osaka, Japan.
Department of Medical Statistics, Osaka Metropolitan University Graduate School of Medicine, Osaka, Japan.
J Asthma Allergy. 2024 Mar 20;17:251-259. doi: 10.2147/JAA.S445203. eCollection 2024.
Pteridines are metabolites of tetrahydrobiopterin (BH), being coenzymes for nitric oxide synthase (NOS). No study has clarified the relationship among pteridines and NOS, fractional exhaled nitric oxide (FeNO) generated by pteridines, and reactive oxygen species. In this study, we administered arginine, a precursor of NO, and confirmed changes in the levels of pteridines, FeNO, and reactive oxygen species and their relationship to clarify the pathogenesis of airway inflammation in which oxidative stress is involved, such as bronchial asthma.
This is a prospective, randomized open-label study. Children, aged 2 to 15 years, who were scheduled for growth hormone stimulation tests and were able to undergo a respiratory function test were recruited. They were randomly divided into two groups: arginine-administered and control groups. In the former, L-arginine hydrochloride was intravenously administered. After administration, the levels of diacron-reactive oxygen metabolites (d-ROMs), serum pteridines, serum amino acids, and fractional exhaled NO (FeNO) were measured.
We analyzed 15 children aged 4 to 14 years. In the arginine-administered group, there was an increase in the FeNO level and a decrease in the d-ROMs level, reaching a peak 30 min after administration, compared with the control group. In addition, there was a decrease in the serum biopterin level and an increase in the d-ROMs level, reaching peak 60 min after administration.
The administration of L-arginine increased the NO level and decreased the d-ROMs level. Due to this, biopterin may be consumed and decreased, leading to an increase in the d-ROMs level. As a reduction in reactive oxygen species leads to the relief of inflammation, arginine and biopterin may be useful for inhibiting inflammation.
蝶啶是四氢生物蝶呤(BH)的代谢产物,是一氧化氮合酶(NOS)的辅酶。尚无研究阐明蝶啶与NOS、蝶啶产生的呼出气一氧化氮分数(FeNO)以及活性氧之间的关系。在本研究中,我们给予一氧化氮的前体精氨酸,并确认蝶啶、FeNO和活性氧水平的变化及其关系,以阐明涉及氧化应激的气道炎症(如支气管哮喘)的发病机制。
这是一项前瞻性、随机、开放标签研究。招募了计划进行生长激素刺激试验且能够进行呼吸功能测试的2至15岁儿童。他们被随机分为两组:精氨酸给药组和对照组。在前者中,静脉注射盐酸L-精氨酸。给药后,测量二氯荧光素反应性氧代谢产物(d-ROMs)、血清蝶啶、血清氨基酸和呼出气一氧化氮分数(FeNO)水平。
我们分析了15名4至14岁的儿童。与对照组相比,精氨酸给药组的FeNO水平升高,d-ROMs水平降低,给药后30分钟达到峰值。此外,血清生物蝶呤水平降低,d-ROMs水平升高,给药后60分钟达到峰值。
L-精氨酸的给药增加了一氧化氮水平并降低了d-ROMs水平。由此,生物蝶呤可能被消耗并减少,导致d-ROMs水平升高。由于活性氧的减少导致炎症减轻,精氨酸和生物蝶呤可能对抑制炎症有用。
