Gaston Benjamin, Kelly Robin, Urban Peter, Liu Lei, Henderson Edward M, Doctor Allan, Teague W Gerald, Fitzpatrick Anne, Erzurum Serpil, Hunt John F
Department of Pediatric Respiratory Medicine, The University of Virginia School of Medicine, Charlottesville, VA 22908, USA.
J Allergy Clin Immunol. 2006 Oct;118(4):817-22. doi: 10.1016/j.jaci.2006.06.040. Epub 2006 Sep 1.
The human airway is believed to be acidified in asthma. In an acidic environment nitrite is converted to nitric oxide (NO).
We hypothesized that buffering airway lining fluid acid would decrease the fraction of exhaled NO (F(ENO)).
We treated 28 adult nonsmoking subjects (9 healthy control subjects, 11 subjects with mild intermittent asthma, and 8 subjects with persistent asthma) with 3 mL of 10 mmol/L phosphate buffered saline (PBS) through a nebulizer and then serially measured F(ENO) levels. Six subjects also received PBS mouthwash alone.
F(ENO) levels decreased after buffer inhalation. The maximal decrease occurred between 15 and 30 minutes after treatment; F(ENO) levels returned to pretreatment levels by 60 minutes. The decrease was greatest in subjects with persistent asthma (-7.1 +/- 1.0 ppb); this was more than in those with either mild asthma (-2.9 +/- 0.3 ppb) or healthy control subjects (-1.7 +/- 0.3 ppb, P < .001). Levels did not decrease in subjects who used PBS mouthwash.
Neutralizing airway acid decreases F(ENO) levels. The magnitude of this change is greatest in persistent asthma. These data suggest that airway pH is a determinant of F(ENO) levels downstream from NO synthase activation.
Airway biochemistry modulates F(ENO) levels. For example, nitrite is converted to NO in the airway, particularly the inflamed airway, by means of acid-based chemistry. Thus airway pH should be considered in interpreting clinical F(ENO) values. In fact, PBS challenge testing integrates airway pH and F(ENO) analysis, potentially improving the utility of F(ENO) as a noninvasive test for the type and severity of asthmatic airway inflammation.
人们认为哮喘患者的气道会酸化。在酸性环境中,亚硝酸盐会转化为一氧化氮(NO)。
我们假设缓冲气道内衬液的酸性会降低呼出一氧化氮分数(F(ENO))。
我们通过雾化器给28名成年不吸烟受试者(9名健康对照受试者、11名轻度间歇性哮喘受试者和8名持续性哮喘受试者)使用3毫升10毫摩尔/升的磷酸盐缓冲盐水(PBS),然后连续测量F(ENO)水平。6名受试者还单独接受了PBS漱口水。
吸入缓冲液后F(ENO)水平下降。最大降幅出现在治疗后15至30分钟之间;F(ENO)水平在60分钟时恢复到治疗前水平。持续性哮喘受试者的降幅最大(-7.1±1.0 ppb);这一降幅大于轻度哮喘受试者(-2.9±0.3 ppb)或健康对照受试者(-1.7±0.3 ppb,P<.001)。使用PBS漱口水的受试者F(ENO)水平未下降。
中和气道酸性可降低F(ENO)水平。这种变化的幅度在持续性哮喘中最大。这些数据表明气道pH是一氧化氮合酶激活下游F(ENO)水平的一个决定因素。
气道生物化学调节F(ENO)水平。例如,亚硝酸盐通过酸碱化学反应在气道,特别是在炎症气道中转化为NO。因此,在解释临床F(ENO)值时应考虑气道pH。事实上,PBS激发试验整合了气道pH和F(ENO)分析,可能会提高F(ENO)作为哮喘气道炎症类型和严重程度无创检测方法的实用性。
