To the Editors:
A variety of isoforms of nitric oxide (NO) synthases are constitutively expressed in human airway and vascular endothelial cells continuously generating NO. NO plays an important role in regulating lung function in health and disease including modulation of pulmonary vascular resistance, airway calibre and host defence. Production of NO and its consumption by fluid-phase reactions can be detected and monitored in the exhaled air, providing an important window to assess the dynamics of NO metabolism in health and inflammatory lung conditions, asthma in particular 1.
A series of milestone studies uncovered a relative deficiency of pulmonary NO availability in cystic fibrosis (CF), a severe chronic inflammatory lung disease with studies generally showing reduced exhaled NO 2, 3. However, there remains controversy regarding the anatomical localisation and mechanisms of NO deficiency, and its relationship with CF disease progression. By using extended exhaled NO analysis at different expiratory flow rates, indirect studies have attempted to distinguish NO production into bronchial and alveolar compartments based on basic models 4–7. However, the fate of NO delivered directly to the alveoli has not been demonstrated in these patients. We aimed to investigate these issues by evaluating endogenous exhaled NO in end-stage CF in intubated patients undergoing lung transplantation and the dynamism of exhaled NO production from pulmonary microvascular metabolism of intravenous nitroglycerin (GTN) 8.
Breath-to-breath tidal measurements of NO concentrations in the lower airways were performed using a real-time, computer-controlled and integrated system (Logan Research Ltd 2000 and 3000 series, Rochester, UK), as described previously [8[ and in detail in the online supplementary material.
To investigate gas-phase NO concentrations in the lower airways of patients with end-stage CF, seven patients (mean age, 26 yrs; five males and two females) presented for lung transplantation were studied after induction of general anaesthetic with endotracheal intubation and mechanical ventilation. CF patients were contrasted to patients undergoing routine open heart surgery for coronary artery bypass grafting (CABG; n = 4) exhibiting normal lung function as judged by preoperative respiratory function testing and evaluation of routine chest radiography (mean age 56 yrs). The studies were approved by the hospital ethics committee and patients provided written consent.
Baseline measurements to evaluate endogenous production and release of NO to the gas phase were performed after induction of anaesthetic, prior to excision of the lungs for transplant patients, and prior to cardiopulmonary bypass in CABG patients. This was followed in haemodynamically-stable patients with administration of a 250-μg bolus of GTN into the central venous catheter with exhaled NO and arterial blood pressure changes recorded, as described previously 8 and in the online supplementary material.
Nearly undetectable levels of NO were found in CF patients representing an output of 7.6±6 ppb over 30 s. This is in contrast to patients presented for routine open heart surgery (91.4±21 ppb over 30 s; fig. 1). Representative traces are shown in figure 1A and C of the online supplementary material.
There was a significant increase in gas-phase NO above baseline levels by 250 μg GTN boluses in CF patients (36.7±6 ppb), which was comparable to that seen in control patients with routine open heart surgery (48.7±4 ppb; fig. 1). Representative traces of GTN-induced exhaled NO are presented in figure 1B and D of the online supplementary material.
These findings provide novel insights into the current debate on NO exchange dynamics in adult CF. Despite the chronic inflammatory nature of the disease, exhaled NO has been reported unchanged or low depending on severity of the disease 2, 4–7. Our study investigating exhaled NO in ventilated patients undergoing lung transplantation clearly demonstrates a profound reduction in endogenous gas-phase NO in the isolated lower airways of patients with end-stage CF. This conclusion must take into consideration both methodological issues regarding tidal measurements of exhaled NO and the potential influence of high endogenous carbon dioxide (CO2) on exhaled NO. However, the same methodology was used for our control population and during the GTN experiments in the CF patients. Regarding CO2, we have not seen major effects of varying endogenous CO2 between 3–6% (unpublished observations) but the potential effects of even higher end tidal CO2 in the CF patients cannot be excluded. Unpublished observations with end-stage pulmonary hypertension demonstrating better-preserved exhaled NO also suggest that the reduced endogenous exhaled NO in CF may be unique, and is unlikely to be the result of end-stage lung disease per se.
The exact mechanisms of relative NO deficiency in CF are not known. Recent studies utilising extended NO exchange analysis resulted in contradictory findings showing no alterations, increased or decreased bronchial fluxes and/or alveolar NO concentrations in CF children and adults 4–7. The emerging consensus suggests that the main mechanism of NO deficiency in adult CF may relate to increased bronchial inflammation and associated defective NO synthase expression, activity and NO production or increased degradation of produced NO 2, 3, 6, 9. The latter may involve bacterial mechanisms, catalytic and chemical consumption by fluid phase reactions, and during passage through the highly viscous mucous layer 6, 9.
Our study expands current understanding of alveolar NO exchange mechanisms by investigating NO fluxes arising from pulmonary microvascular metabolism of exogenous nitroglycerin. Our in vivo studies in patients appear to confirm the ex vivo observations of Henno et al. 10 regarding preserved endothelium independent vasodilation by nitroprusside in isolated vascular rings of CF pulmonary arteries. Our preliminary results extend these studies to the microvasculature and airway compartments by suggesting a notably preserved ability of the end-stage CF lung microvasculature to convert GTN and release NO into the alveoli and airways without evidence of increased consumption either in the alveolar fluid or gas phase. This is remarkable in relation to both the profound reduction in endogenous NO release and the potential for pulmonary vascular dysfunction associated with end-stage CF in some patients 7, 10. Altogether, these data lend strong support for the bronchial epithelial and mucosal consumption hypothesis for the dysregulated NO pathways in CF. Furthermore, they also suggest that the CF airways may be therapeutically targeted for exposure by NO through pulmonary metabolism of nitrovasodilators.
Footnotes
Statement of Interest
None declared
- ©2010 ERS