Extended Exhaled NO Measurement Differentiates between Alveolar and Bronchial Inflammation

Lehtimäki, Lauri; Kankaanranta, Hannu; Saarelainen, Seppo; Hahtola, Paula; Järvenpää, Ritva; Koivula, Timo; Turjanmaa, Väinö; Moilanen, Eeva

doi:10.1164/ajrccm.163.7.2010171

Cited by 172 publications

(178 citation statements)

References 23 publications

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“…RCT cross-over design Three-arm comparison of fish oil v. evening primrose oil (n-6 group) v. olive oil using liquid oil supplementation 2-week run-in period followed by 30 (57) RCT, double-blind, cross-over, placebocontrolled trial 3-week supplementation period in each arm 2-week washout phase n-3: 3·2 g EPA and 2·0 g DHA Placebo: Matched capsules with olive oil 16 subjects Age 23 ± 1·6 years Participants with clinically treated mild-moderate asthma with a FEV 1 >70 % predicted Improved pulmonary function to below the diagnostic EIB threshold Reduction in medication usage Reduction in induced sputum differential cell count percentage and concentrations of LTC 4 -LTE 4 , PGD 2 , IL-1β and TNF-α before and following exercise on the n-3 fatty acid diet Significant reduction in LTB 4 and a significant increase in LTB 5 generation from activated polymorphonuclear cells on the n-3 fatty acid diet n-3 Fatty acids and asthma (126) RCT, double-blind, cross-over study Subjects entered the study on their normal diet, and then received either fish oil capsules or placebo n-3: 3·2 g EPA and 2·0 g of DHA Placebo: Matched capsules with olive oil 10 athletes and 10 controls Age (asthmatics 23·2 ± 1·9 years; controls 22·4 ± 1·7 years) Participants with clinically diagnosed EIB No effect on pre-exercise pulmonary function in either group Improved post-exercise pulmonary function Reduction in LTE 4 , 9α, 11β-PG F 2 , LTB 4 , TNF-α, and IL-1β, on the n-3 PUFA diet compared with baseline and placebo diets and after exercise challenge Studies reporting benefits of n-3 supplementation (in children)…”

Section: Evidence From N-3 Intervention Trials In Asthmamentioning

confidence: 99%

n-3 Fatty acids and asthma

2016

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Asthma is one of the most common and prevalent problems worldwide affecting over 300 million individuals. There is some evidence from observational and intervention studies to suggest a beneficial effect of n-3 PUFA in inflammatory diseases, specifically asthma. Marine-based n-3 PUFA have therefore been proposed as a possible complementary/alternative therapy for asthma. The proposed anti-inflammatory effects of n-3 fatty acids may be linked to a change in cell membrane composition. This altered membrane composition following n-3 fatty acid supplementation (primarily EPA and DHA) can modify lipid mediator generation via the production of eicosanoids with a reduced inflammatory potential/impact. A recently identified group of lipid mediators derived from EPA including E-series resolvins are proposed to be important in the resolution of inflammation. Reduced inflammation attenuates the severity of asthma including symptoms (dyspnoea) and exerts a bronchodilatory effect. There have been no major health side effects reported with the dietary supplementation of n-3 fatty acids or their mediators; consequently supplementing with n-3 fatty acids is an attractive non-pharmacological intervention which may benefit asthma.

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Section: Evidence From N-3 Intervention Trials In Asthmamentioning

confidence: 99%

n-3 Fatty acids and asthma

2016

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“…Recently, methods for measuring eNO at multiple expiratory flows (MEFeNO) [13,14] have been used to detect elevated levels of alveolar NO in fibrosing alveolitis [13], asthma [15,16] and COPD [17] leading to the refinement of analytical methods to discriminate exhaled NO sources in the lung [18].…”

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confidence: 99%

Exhaled nitric oxide from lung periphery is increased in COPD

Brindicci¹

2005

European Respiratory Journal

181

159

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Single constant flow exhaled nitric oxide (eNO) cannot distinguish between the sources of NO. The present study measured eNO at multiple expired flows (MEFeNO) to partition NO into alveolar (Calv,NO) and bronchial (Jaw,NO) fractions to investigate peripheral lung contribution to eNO in chronic obstructive lung disease (COPD).MEFeNO were made in 81 subjects including 18 nonsmokers, 16 smokers and 47 COPD patients of different severity by the classification of the Global Initiative for Chronic Obstructive Lung Disease (GOLD): 0 (n514), 1 (n57), 2 (n511), 3 (n58) and 4 (n57).COPD severity was correlated with an increased Calv,NO regardless of the patient's smoking habit or current treatment. The levels of Calv,NO (in ppb) were 1.4¡0.09 in nonsmokers, 2.1¡0.1 in smokers categorised as GOLD stage 0 (smokers-GOLD0), 3.3¡0.18 in GOLD1-2 and 3.4¡0.1 in GOLD3-4. Jaw,NO levels (pL?s -1 ) were higher in nonsmokers than smokers-GOLD0 (716.2¡33.3versus 464.7¡41.8), GOLD3-4 (609.4¡71). Diffusion of NO in the airways (Daw,NO pL?ppb -1 s -1 ) was higher (p,0.05) in GOLD3-4 than in nonsmokers (15¡1.2 versus 11¡0.5) and smokers-GOLD0 (11.6¡0.5). MEFeNO measurements were reproducible, free from day-to-day and diurnal variation and were not affected by bronchodilators.In conclusion, chronic obstructive pulmonary disease is associated with elevated alveolar nitric oxide. Measurements of nitric oxide at multiple expired flows may be useful in monitoring inflammation and progression of chronic obstructive pulmonary disease, and the response to anti-inflammatory treatment.KEYWORDS: Chronic obstructive pulmonary disease, exhaled nitric oxide, multiple expiratory flow, small airway inflammation S ingle expiratory flow exhaled nitric oxide (eNO) measurements are simple, highly reproducible [1], have been used to monitor larger airway inflammation in asthma research [2], and are now moving into clinical practice [3]. However, small airways and lung parenchyma are the predominant sites of inflammation in patients with chronic obstructive pulmonary disease (COPD) [4]. Progression of COPD is associated with the accumulation of inflammatory mucous exudates in the lumen and infiltration of the small airway wall by inflammatory cells [4]. There is a high level of expression of inducible NO synthase (iNOS) presence in sputum macrophages [5], alveolar walls, small airway epithelium and vascular smooth muscle of COPD patients [5,6]. In patients with COPD this may result in an increased production of NO and NO-related species in the lung periphery, which through the function of peroxynitrite may amplify the inflammation and lead to inhaled corticosteroid (ICS) resistance, particularly as the disease becomes more severe [7].The current single expiratory technique measures predominantly larger airway-derived NO and may only partially reflect peripheral inflammation [8,9]. eNO is often in the normal range or even reduced in moderate COPD [10], probably due to down-regulation of endothelial NO synthase (eNOS) [11] and iNOS [12] by cigarette ...

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“…The characteristics of NO gas exchange are unique compared with other endogenous gases because exhaled NO is thought to have a significant alveolar and airway source (6,8,15,22). A two-compartment model is commonly used to characterize NO exchange dynamics for healthy and diseased lungs (9,11,13,20,21,23,24,27,29), by partitioning exhaled NO into airway and alveolar contributions using three flow-independent NO exchange parameters: maximum flux of NO from the airways (JЈaw NO ), the diffusing capacity of NO in the airways (Daw NO ), and the steady-state alveolar concentration (CA NO ). However, the two-compartment model considers only convection of NO in the airways as a transport mechanism and has neglected axial diffusion of NO in the gas phase to preserve mathematical simplicity.…”

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Probing the impact of axial diffusion on nitric oxide exchange dynamics with heliox

Shin

Condorelli

Rose-Gottron

et al. 2004

Journal of Applied Physiology

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Shin, Hye-Won, Peter Condorelli, Christine M. Rose-Gottron, Dan M. Cooper, and Steven C. George. Probing the impact of axial diffusion on nitric oxide exchange dynamics with heliox. J Appl Physiol 97: 874 -882, 2004. First published April 30, 2004 10.1152/ japplphysiol.01297.2003.-Exhaled nitric oxide (NO) is a potential noninvasive index of lung inflammation and is thought to arise from the alveolar and airway regions of the lungs. A two-compartment model has been used to describe NO exchange; however, the model neglects axial diffusion of NO in the gas phase, and recent theoretical studies suggest that this may introduce significant error. We used heliox (80% helium, 20% oxygen) as the insufflating gas to probe the impact of axial diffusion (molecular diffusivity of NO is increased 2.3-fold relative to air) in healthy adults (21-38 yr old, n ϭ 9). Heliox decreased the plateau concentration of exhaled NO by 45% (exhalation flow rate of 50 ml/s). In addition, the total mass of NO exhaled in phase I and II after a 20-s breath hold was reduced by 36%. A single-path trumpet model that considers axial diffusion predicts a 50% increase in the maximum airway flux of NO and a near-zero alveolar concentration (CA NO) and source. Furthermore, when NO elimination is plotted vs. constant exhalation flow rate (range 50 -500 ml/s), the slope has been previously interpreted as a nonzero CANO (range 1-5 ppb); however, the trumpet model predicts a positive slope of 0.4 -2.1 ppb despite a zero CANO because of a diminishing impact of axial diffusion as flow rate increases. We conclude that axial diffusion leads to a significant backdiffusion of NO from the airways to the alveolar region that significantly impacts the partitioning of airway and alveolar contributions to exhaled NO. gas exchange; model; exhaled breath NITRIC OXIDE (NO) performs many important functions in the lungs and has been regarded as a potential noninvasive marker of lung inflammation (2). The characteristics of NO gas exchange are unique compared with other endogenous gases because exhaled NO is thought to have a significant alveolar and airway source (6,8,15,22). A two-compartment model is commonly used to characterize NO exchange dynamics for healthy and diseased lungs (9,11,13,20,21,23,24,27,29), by partitioning exhaled NO into airway and alveolar contributions using three flow-independent NO exchange parameters: maximum flux of NO from the airways (JЈaw NO ), the diffusing capacity of NO in the airways (Daw NO ), and the steady-state alveolar concentration (CA NO ). However, the two-compartment model considers only convection of NO in the airways as a transport mechanism and has neglected axial diffusion of NO in the gas phase to preserve mathematical simplicity.Recently, our laboratory (17) and others (31) separately demonstrated theoretically that axial diffusion may play an important role in NO transport. During exhalation, the concentration of NO is higher in the airways compared with the alveoli, creating a gradient for diffusion of NO from the air...

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Extended Exhaled NO Measurement Differentiates between Alveolar and Bronchial Inflammation

Cited by 172 publications

References 23 publications

n-3 Fatty acids and asthma

n-3 Fatty acids and asthma

Exhaled nitric oxide from lung periphery is increased in COPD

Probing the impact of axial diffusion on nitric oxide exchange dynamics with heliox

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