Montelukast exerts no acute direct effect on NO synthases

The cysteinyl leukotrienes (CysLTs) LTC(4), LTD(4) and LTE(4) are potent proinflammatory lipid mediators that play a central role in inflammation, contraction and remodelling of airways observed in asthmatics. Montelukast, a competitive inhibitor of the cysteinyl leukotriene-1 (CysLT(1)) receptor attenuates asthmatic airway inflammation, contraction and remodelling. As a number of studies have shown that montelukast reduced exhaled nitric oxide (NO) levels, a marker of inflammation that correlates with the severity of asthma, we investigated whether or not a direct inhibition of NO synthase (NOS) by montelukast takes place. In an ex vivo rat lung perfusion and ventilation model the NOS-dependent vasodilation effect after lipopolysaccharide (LPS) infusion was assessed with and without montelukast. Functional organ bath studies using isolated aortic rings from the same species aimed to assess effects of montelukast on the inducible and endothelial NOS isoenzymes (i- and eNOS) as well as on iNOS expression. Neuronal NOS (nNOS) was assessed by field stimulated rabbit corpus cavernosum, and isolated human iNOS enzyme activity was assessed for potential inhibition. Montelukast failed to cause vasoconstriction in LPS challenged rat lung, or to inhibit i- and eNOS activity as well as iNOS expression in aortic rings from the same species. Also the assays for nNOS in rabbit corpus cavernosum and on isolated human iNOS enzyme gave no evidence for a direct inhibition by montelukast in physiological and supraphysiological concentrations up to 10(-4)M. We therefore conclude that montelukast has no acute NOS inhibitor action. Its effect on exhaled NO is therefore probably indirectly mediated by a modulation of the asthmatic airway inflammation.     

Mediators of asthma: nitric oxide

Endogenous nitric oxide is an ubiquitous gaseous molecule that regulates many aspects of human airway biology including the modulation of airway and vascular smooth muscle tone. It is generated from the three different enzymes nitric oxide synthases (NOS) -1, -2 and -3 which are all expressed in pulmonary cells. NOS-1 is localised primarily to neuronal structures, where NO is a mediator of the inhibitory Non-Adrenergic Non-Cholinergic System and NOS-3 is present in endothelial cells. While these enzymes are constitutively expressed, NOS-2 is an inducible enzyme independent of calcium and highly induced in inflammatory diseases such as allergic asthma, where NO may act beneficial or deleterious depending on the site of and amount of generation. The use of NO-donor compounds or classical unselective NOS inhibitors did not lead to significant therapeutical effects in asthmatic patients. Insights on the precise role of NO in asthma can only be achieved by targeting NO generation selectively. More potent and selective NOS-2 inhibitors have to clarify a role of NOS-modification based therapy in clinical routine. NO can also be detected in the exhaled air. Increased levels of exhaled NO in asthmatic patients may be useful for a non-invasive determination of airway inflammation.     

Airway nitric oxide output is reduced in bronchiectasis

BACKGROUND: Increased concentrations of exhaled nitric oxide (NO) have been detected in inflammatory lung diseases including asthma and have been attributed to increased expression and activity of inducible nitric oxide synthase (iNOS) within the airways. However, previous studies of exhaled NO in patients with bronchiectasis have yielded conflicting results, with reports of both increased and normal NO values. Recent evidence from animal models suggests that chronic airway infection reduces NO production within the lung, despite causing increased iNOS expression. We tested the hypothesis that, in human subjects with bronchiectasis, chronic airway infection reduces NO output from the conducting airways. METHODS: Using a recently described two-compartment model, we measured separately the contributions of the conducting airways and the alveoli to exhaled NO in nine patients with stable bronchiectasis and eight control subjects before and after inhaled glucocorticoid therapy. RESULTS: We found that airway NO output was significantly lower in bronchiectasis than in normal airways whereas NO output from the alveoli was similar to that of control subjects. High-dose inhaled glucocorticoid therapy did not alter airway or alveolar NO production. CONCLUSIONS: These findings demonstrate that, in patients with bronchiectasis, airway NO output is reduced and that iNOS does not contribute significantly to airway NO production.     

An official JRS statement: The principles of fractional exhaled nitric oxide (FeNO) measurement and interpretation of the results in clinical practice

Nitric oxide (NO) is produced in the body and has been shown to have diverse actions in the abundance of research that has been performed on it since the 1970s, leading to Furchgott, Murad, and Ignarro receiving the Nobel Prize in Physiology or Medicine in 1998. NO is produced by nitric oxide synthase (NOS). NOS is broadly distributed, being found in the nerves, blood vessels, airway epithelium, and inflammatory cells. In asthma, inflammatory cytokines induce NOS activity in the airway epithelium and inflammatory cells, producing large amounts of NO. Measurement of fractional exhaled nitric oxide (FeNO) is a simple, safe, and quantitative method of assessing airway inflammation. The FeNO measurement method has been standardized and, in recent years, this noninvasive test has been broadly used to support the diagnosis of asthma, monitor airway inflammation, and detect asthma overlap in chronic obstructive pulmonary disease (COPD) patients. Since the normal upper limit of FeNO for healthy Japanese adults is 37 ppb, values of 35 ppb or more are likely to be interpreted as a signature of inflammatory condition presenting features with asthma, and this value is used in clinical practice. Research is also underway for clinical application of these measurements in other respiratory diseases such as COPD and interstitial lung disease. Currently, there remains some confusion regarding the significance of these measurements and the interpretation of the results. This statement is designed to provide a simple explanation including the principles of FeNO measurements, the measurement methods, and the interpretation of the measurement results.     

Nitric oxide and intestinal inflammation

Inflammation of the intestinal tract remains a very serious concern in the clinical setting. Unfortunately, to date, the mechanisms underlying many inflammatory conditions such as sepsis or inflammatory bowel diseases are poorly understood and our therapeutic interventions are less than ideal. Over the past decade, an abundance of research has been directed toward the role of nitric oxide (NO) in intestinal inflammation. It has become apparent that NO might have a dichotomous role as both a beneficial and detrimental molecule. Nitric oxide is a weak radical produced from L-arginine via the enzyme nitric oxide synthase (NOS). NOS exists in three distinct isoforms; constitutively (cNOS) expressed neuronal NOS (NOS1 or nNOS) and endothelial NOS (NOS3 or eNOS) or an inducible isoform (NOS2 or iNOS) capable of high production output of NO during inflammation. Constitutively expressed NOS has been shown to be critical to normal physiology and inhibition of these enzymes (nNOS or eNOS) caused damage. It has been proposed that the high output production of NO from iNOS causes injury, perhaps through the generation of potent radicals such as peroxynitrite and hence may explain the apparent dichotomous role of NO. However, recent studies have challenged this simple paradigm providing evidence that iNOS may have some protective role in some inflammatory models. Moreover, the importance of peroxynitrite has been questioned. In this review we discuss the role of cNOS and iNOS in intestinal inflammation and provide an overview of peroxynitrite in intestinal inflammation, highlighting some of the controversy that exists.     

Explorations non invasives des voies aériennes : applications pratiques dans l'asthme et l'allergie

Non-invasive investigation of airway inflammation relies mainly on measurement of exhaled gases (essentially NO) and several markers of inflammation in exhaled breath condensate (EBC). Levels of exhaled nitric oxide (NO) are easily and quickly measured. International recommendations for standardized measurements of exhaled NO have been published. Exhaled NO is increased in patients with untreated asthma; the results of this measurement may be useful when the diagnosis is difficult or when there is a chronic asthma-like cough. Exhaled NO is reduced or normalized with inhaled corticosteroid therapy. An increase in exhaled NO in an asthmatic whose condition has been well controlled may signal a clinical exacerbation. The place of exhaled NO measurement in the diagnosis and treatment of asthma should rapidly be publicised because of its simplicity and because of the availability of reliable devices for its measurement. Many inflammatory mediators can be measured in EBC obtained by rapid cooling of exhaled air on a cold surface. Although collection of EBC is non-invasive, at present lack of standardisation limits its application and interpretation in practice. In cases of asthma, the pH of EBC is lower than normal and the concentrations of leukotrienes, 8-isoprostane and H₂O₂ are higher. Levels of the mediators detected in EBC decrease rapidly in asthmatic patients treated with steroids but this treatment is less effective on oxidative stress markers. Exhaled NO and EBC are complementary in the non-invasive approach to the evaluation of airway inflammation in asthma and atopy.     

Selective inhibition of inducible nitric oxide synthase: A promising strategy in the therapy of septic shock?

Summary Nitric oxide (NO) is a short-lived effector molecule which is produced from L-arginine by several NO synthase (NOS) isoforms. Physiologically, small amounts of NO are produced by an endothelial constitutive NOS (ecNOS), which is involved in the regulation of vascular tone and blood flow distribution. On stimulation by bacterial products and various cytokines, an inducible NOS (iNOS) becomes diffusely expressed, producing large amounts of NO for extended periods of time, which are implicated in the pathogenesis of septic shock. The pharmacological inhibition of NO synthesis has been, therefore, proposed as a new therapy in this setting. Unfortunately, such inhibition has been frequently reported to be detrimental, and recent evidence reveals that this deleterious potential is a consequence of ecNOS blockade by nonselective NOS inhibitors. Thus, interest is now focusing in the identification of compounds able to selectively inhibit iNOS activity. Although the effects of such selective agents have been only poorly investigated so far, they appear extremely promising. Indeed, in various animal models of septic shock, selective iNOS inhibitors have produced a marked improvement in hemodynamics, tissue oxygenation, and organ function, leading to a reduced mortality. These favorable results, which markedly contrast with the deleterious influence of nonselective NOS inhibitors in similar conditions, suggest that selective iNOS inhibitors might become useful adjuncts to septic shock therapy in the future. Accepted: 26 January 1999     

Continuous nitric oxide synthesis by inducible nitric oxide synthase in normal human airway epithelium in vivo.

Nitric oxide (NO) is an important mediator of inflammatory responses in the lung and a key regulator of bronchomotor tone. An airway NO synthase (NOS; EC 1.14.13.39) has been proposed as a source of endogenous NO in the lung but has not been clearly defined. Through molecular cloning, we conclusively demonstrate that NO synthesis in normal human airways is due to the continuous expression of the inducible NOS (iNOS) isoform in airway epithelial cells. Although iNOS mRNA expression is abundant in airway epithelial cells, expression is not detected in other pulmonary cell types, indicating that airway epithelial cells are unique in the continuous pattern of iNOS expression in the lung. In situ analysis reveals all airway epithelial cell types express iNOS. However, removal of epithelial cells from the in vivo airway environment leads to rapid loss of iNOS expression, which suggests expression is dependent upon conditions and/or factors present in the airway. Quantitation of NOS activity in epithelial cell lysates indicates nanomolar levels of NO synthesis occur in vivo. Remarkably, the high-level iNOS expression is constant in airway epithelium of normal individuals over time. However, expression is strikingly decreased by inhaled corticosteroids and beta-adrenergic agonists, medications commonly used in treatment of inflammatory airway diseases. Based upon these findings, we propose that respiratory epithelial cells are key inflammatory cells in the airway, functioning in host defense and potentially playing a role in airway inflammation.     

Increased nitrosothiols in exhaled breath condensate in inflammatory airway diseases

Nitrosothiols (RS-NOs) are formed by interaction of nitric oxide (NO) with glutathione and may limit the detrimental effect of NO. Because NO generation is increased in airway inflammation, we have measured RS-NOs in exhaled breath condensate in patients with asthma, cystic fibrosis, or chronic obstructive pulmonary disease (COPD). We also measured exhaled NO and nitrite (NO(2-)) in the same subjects. RS-NOs were detectable in exhaled breath condensate of all subjects. RS-NOs were higher in subjects with severe asthma (0.81 +/- 0.06 microM) when compared with normal control subjects (0.11 +/- 0.02 microM, p < 0.01) and with subjects with mild asthma (0.08 +/- 0.01 microM, p < 0.01). Elevated RS-NOs values were also found in patients with cystic fibrosis (0.35 +/- 0.07 microM, p < 0.01), in those with COPD (0.24 +/- 0.04 microM, p < 0.01) and in smokers (0.46 +/- 0.09 microM, p < 0.01). In current smokers there was a correlation (r = 0.8, p < 0.05) between RS-NOs values and smoking history (pack/year). We also found elevated concentrations of NO(2-) in patients with severe asthma, cystic fibrosis, or COPD, but not in smokers or patients with mild asthma. This suggests that exhaled NO(2-) is less sensitive than exhaled RS-NOs. This study has shown that RS-NOs are detectable in exhaled breath condensate of healthy subjects and are increased in patients with inflammatory airway diseases. As RS-NOs concentrations in exhaled breath condensate vary in the different airway diseases and increase with the severity of asthma, their measurement may have clinical relevance as a noninvasive biomarker of nitrosative stress.     

Exhaled nitric oxide measurements in a population sample of young adults

In epidemiologic studies of asthma there is a group with recent wheeze, but with no airway hyperresponsiveness (AHR), in whom it is unclear whether any significant airway abnormality exists. Exhaled nitric oxide (NO) has been proposed as a measure of airway inflammation. We measured exhaled NO in a population sample of 306 young adults who also underwent bronchial challenge with histamine or a bronchodilator test. Subjects blew into a 3-L Tedlar bag against a 2-mm-diameter resistance to close the soft palate and exclude nasal air. The NO content of expired gas from a single breath was analyzed by chemiluminescent analyzer. Exhaled NO was log-normally distributed in the population sample and duplicate measurements were highly reproducible (intraclass correlation coefficient = 0.98). Exhaled NO correlated significantly with airway responsiveness, measured as the dose-response ratio to histamine (r = 0.39, p < 0.001) and with peripheral blood eosinophils (r = 0.35, p < 0.001). Exhaled NO was significantly greater in asthmatic subjects (geometric mean, 22.2; 95% confidence intervals, 16.1 to 30. 7 ppb) than in normal subjects (7.8, 7.1 to 8.4, p < 0.001) or in subjects with wheeze but no AHR (8.8, 7.5 to 10.3, p < 0.001). We conclude that exhaled NO is log-normally distributed, is highly reproducible and discriminates well among subjects, suggesting that it is both a feasible and useful measurement for epidemiologic studies of asthma. The findings suggest that wheeze in the absence of AHR is unlikely to be associated with airway inflammation.     

Neuronal nitric oxide synthase is associated with airway obstruction in BALB/c mice exposed to ozone

BACKGROUND: The functional role of nitric oxide (NO) and the various nitric oxide synthase (NOS) isoforms in asthma is controversial. OBJECTIVE: To investigate the role of NO in mice exposed to ozone, three known isoforms of NOS [inducible NOS (iNOS), neuronal NOS (nNOS), and endothelial NOS (eNOS)] were studied. METHODS: The expression of iNOS, nNOS, and eNOS was determined in lung by Western blot analysis after exposure to filtered air and ozone (0.12, 0.5, 1 or 2 ppm) for 3 h. Using barometric whole-body plethysmography and increase in enhanced pause (P(enh)) as an index of airway obstruction, we measured airway responses to ozone exposure. Bronchoalveolar lavage (BAL) was performed. Nitrate and nitrite were measured using a modified Griess reaction. RESULTS: The nitrate concentration in BAL fluid, which indicates the in vivo generation of NO in airways, from the ozone-exposed group was significantly greater than that from the group exposed to filtered air (631.0 +/- 86.4 vs. 152.1 +/- 16.9 micromol/l, p < 0.05). The nitrate concentration in BAL fluid was increased more in mice exposed to 2-ppm ozone than that in mice exposed to filtered air or 0.12-, 0.5-, or 1-ppm ozone. Increases in P(enh) after exposure to ozone or filtered air were significantly higher in the ozone-exposed groups than in the group exposed to filtered air (p < 0.01). Increases in P(enh) were dependent on the ozone concentration. Although the protein levels of eNOS and iNOS determined were within normal levels, the amount of nNOS protein was markedly elevated in airway tissue homogenates of the group exposed to 2-ppm ozone. CONCLUSION: These findings demonstrate that the nNOS isoform may be involved in airway obstruction in mice exposed to ozone.     

Exhaled nitric oxide--is it really a good marker of airway inflammation in bronchial asthma?

BACKGROUND: The concentration of exhaled nitric oxide ([NO]) has been reported to reflect the inflammatory process of airways in patients with bronchial asthma, particularly when they are steroid naive. However, it is not fully understood whether it equally reflects the degree of airway inflammation in patients receiving inhaled corticosteroids, but whose symptoms are not necessarily well controlled. OBJECTIVE: To examine whether the exhaled [NO] really reflects airway inflammation in patients with bronchial asthma, regardless of treatment with inhaled steroids. METHODS: Exhaled [NO] was measured in patients with bronchial asthma (43 steroid treated and 32 steroid naive), chronic obstructive pulmonary disease (COPD) (n = 36), bronchiectasis (n = 10) and in control subjects (n = 26). We examined in each asthmatic group whether the exhaled [NO] correlated with parameters reflecting airway inflammation. RESULTS: Exhaled [NO] was significantly correlated with symptom score, clinical severity, circulating eosinophil count, and the percentage of eosinophils in induced sputum in the steroid-naive asthmatics, but not in the steroid-treated asthmatics, although airway inflammation in this group was not well controlled, as evidenced by clinical symptoms and the higher percentage of eosinophils in induced sputum. Exhaled [NO] from the patients with COPD (6.2 +/- 0. 7 ppb) or bronchiectasis (5.4 +/- 1.3 ppb) was not significantly increased compared with the controls (6.0 +/- 1.0 ppb), and was significantly lower than in the asthmatic patients as a whole (19.0 +/- 2.0 ppb). CONCLUSIONS: Although exhaled [NO] is a useful marker of airway inflammation for differential diagnosis and evaluation of severity in steroid-naive patients with bronchial asthma, it may not be as useful in steroid-treated patients.     

Genetics of the neuronal NO synthase (NOS1) in the etiology of bronchial asthma

The free radical nitric oxide (NO) is endogenously produced by enzymes known as NO synthases. NO in the airways is involved in a number of pathophysiological processes, such as airway inflammation, allergic reactions, and asthma. Asthma is a multifactorial disease that is caused by environmental and genetic factors. Genome wide screening approaches in families revealed evidence for linkage between chromosomal region 12q and allergic diseases, increased serum IgE levels as well as the development of asthma. The gene encoding for neuronal NOS (NOS1) is an attractive candidate gene for asthma, not only because it is localized in chromosomal region 12q24. Experimental studies in animals and humans suggest that NOS1 plays an important role in asthma. For instance, in a murine model of allergic asthma, NOS1 has been shown to be important for the development of bronchial hyperresponsiveness, since mice deficient for the nos1 gene were less responsive to airway challenge than both wild-type mice and mice deficient for the nos2 gene. Case-control studies in humans revealed allelic associations between polymorphic markers in the NOS1 gene and the diagnosis of asthma. Furthermore, increased concentrations of NO in the airways of asthmatics are closely related to the size of an intronic (AAT)(n)-repeat polymorphism in the NOS1 gene. The purpose of this review is to summarize studies that provide evidence for an involvement of NOS1 in the genetics of asthma.     

Level of Nitric Oxide in Bronchoalveolar Lavage Fluid of Asthmatic Mice Model

Background: Asthma is a chronic inflammatory disease with multifactorial and complicated mechanisms. Elevated level of exhaled Nitric Oxide (NO) in asthma and other inflammatory lung diseases has led to many studies examining NO as a potential marker of airway inflammation. Objective: This study was designed to determine the level of NO in Bronchoalveolar Lavage (BAL) fluid during early and late stages of asthmatic attack in mouse model.   Methods: In this study male BALB/c mice were used. The level of NO was determined in BAL fluid of asthmatic mice five minutes, six and sixteen hours after challenge with methacholine, as irritant and smoke and 5% ovalbumin as allergens, using colorimetric assay.   Results: The level of NO increased upon exposure to all three irritants used in this study (52.3   μM for smoke and 49.5 μ   Mfor methacholine) as compared to 22.8 μM for the baseline. Our results showed that NO levels were increased during early phase of asthmatic condition and reached to its maximum level after six hours and decreased at the late stage of asthma (16hrs) possibly by activating a feedback regulatory loop. In addition, high level of NO led to the hypertrophy of smooth muscle that can account for the pathological changes associated with asthma.   Conclusion: Thus, NO is an inflammatory marker in asthma and its measurement, as a non-invasive method during asthmatic attack is suggested. A careful development of specific inhibitors for iNOS enzyme during asthmatic attack is also necessary.     

Increased eNO and pulmonary iNOS expression in eNOS null mice.

Nitric oxide (NO) is a major regulatory molecule of the cardiovascular system; however, measurement of vascular NO synthesis in vivo represents a major challenge. NO stemming from the lower respiratory tract has been used as a marker of vascular endothelial function. Experimental evidence for this concept is lacking. Therefore, the aim of the present study was to investigate this relationship. Lower respiratory tract exhaled NO concentration, together with systemic and pulmonary artery pressure, was measured in endothelial nitric oxide synthase (NOS) (eNOS) null mice (eNOS-/-). Similar studies were performed in inducible NOS (iNOS) null mice (iNOS-/-). Defective endothelial NO synthesis in eNOS-/- mice (evidenced by systemic and pulmonary hypertension) was associated with augmented exhaled NO levels (12.5 +/- 1.9 versus 9.8 +/- 1.2 parts per billion (ppb), eNOS-/- versus wild type), whereas normal endothelial NO synthesis in iNOS-/- mice was associated with decreased exhaled NO levels (4.3 +/- 1.5 ppb). Augmented exhaled NO levels in eNOS-/- mice were associated with upregulation of iNOS expression in the lung. These results indicate that inducible nitric oxide synthase is a major determinant of gaseous nitric oxide production in the lung, and lower respiratory tract exhaled nitric oxide does not always represent a marker of vascular endothelial nitric oxide synthesis.     

Elevated nitric oxide synthase activity concurrent with antigen-induced airway hyperresponsiveness in rats

To characterize the airway nitric oxide synthase (NOS) activities concurrent with airway hyperresponsiveness (AHR), a common feature of allergic asthma, the NOS activities of airway tissue homogenates from the antigen-induced AHR rats were determined by the ability of tissue homogenates to convert L-arginine to L-citrulline (Cit). A significantly higher level of total NOS activities was found in homogenates from the AHR rats (19.9 +/- 1.3 pmol Cit/min/mg protein) compared to those from sensitized control and normal control groups (9.8 +/- 1.2 and 8.8 +/- 1.2 pmol Cit/min/mg protein, respectively; P < .01). The nitrite concentration in bronchoalveolar lavage fluids, which indicates the in vivo generation of NO in airways, from the AHR rats (7.40 +/- 0.71 microM) was significantly greater than that from nonsensitized normal animals (1.45 +/- 1.12 microM, P < .01). Although the protein levels of endothelial (eNOS) and neuronal type NOS (nNOS) determined by immunoblotting were within normal levels, the amount of inducible NOS (iNOS) protein was markedly and significantly elevated in airway tissue homogenates from the AHR rats. Immunohistochemical staining of airway tissues with specific antibody against iNOS demonstrated a distinct localization of iNOS on epithelial cells and infiltrated inflammatory cells in the bronchi of the hyperresponsive rats, but only negligible staining of epithelia was observed in the nonsensitized normal group. No difference in constitutive NOS (eNOS and nNOS) localization was observed between groups. The present findings indicate that the NOS activities in airway tissues are elevated in antigen-induced AHR rats, which is mainly derived from the induction of iNOS in the airways. Downregulation of constitutive eNOS and nNOS is not found in this animal model of AHR.     

Clinical aspects of exhaled nitric oxide.

There has been intense research into the role nitric oxide (NO) plays in physiological and pathological mechanisms and its clinical significance in respiratory medicine. Elevated levels of exhaled levels of exhaled NO in asthma and other inflammatory lung diseases lead to many studies examining NO as potential markers of airway inflammation, enabling repeated noninvasive and standardized monitoring of airway inflammation. In airway inflammation, NO is not merely a marker but may have anti-inflammatory and pro-inflammatory effects. Significant correlation has been found between exhaled NO and skin test scores in steroid naive asthmatic patients, allowing to discriminate patients with and without airway responsiveness. Exhaled NO is significantly elevated in acute asthma, or steroid-resistant severe asthma, or when the maintenance dose of inhaled steroids is reduced, and quickly reduced down to the levels in patients with stable asthma after steroid treatment. Exhaled NO has been successfully used to monitor anti-inflammatory treatment with inhaled corticosteroids in asthma. Exhaled NO is extremely sensitive and rapid marker of the dose-dependent effect of steroid treatment, or asthma deterioration, which is increased to any changes in lung function, provocative concentration causing a 20% fall in forced expiratory volume, sputum eosinophilia or asthma symptoms. Exhaled NO is not increased in stable chronic obstructive pulmonary disease (COPD), but patients with unstable COPD, or bronchiectasis have high NO levels. Exhaled and nasal NO are diagnostically low in cystic fibrosis and primary pulmonary dyskinesia. Analysis of exhaled air, including nitric oxide, is feasible and could provide a noninvasive method for use in monitoring and management of lung diseases.     

Low-dose theophylline reduces eosinophilic inflammation but not exhaled nitric oxide in mild asthma.

Theophylline is well-established in the management of asthma, and there is some evidence of an antiinflammatory effect in asthma. It is not known whether theophylline affects inflammatory markers such as sputum eosinophils and exhaled nitric oxide (NO) in patients with mild asthma not receiving inhaled steroid therapy. In a double-blind, placebo-controlled, cross-over study of 15 patients with mild asthma, we assessed the effect of low-dose theophylline therapy (250 mg twice per day) on eosinophils in induced sputum, bronchoalveolar lavage (BAL) and airway biopsies at the end of both the treatment and placebo periods. Measurements of exhaled nitric oxide (NO) were made at the end of the active and placebo treatment periods of 5 wk each. Low-dose theophylline (mean serum level, 6.1 mg/L) led to a significant reduction in mean (95% confidence interval [CI]) sputum eosinophils from 11.3% (7.80-14.76%) to 8.0% (5.46-10.44%), BAL eosinophils from 3.4% (2.4-4.4%) to 1.7% (1.1-2.3%) and biopsy eosinophils from 1.83% (0.76-2.89%) to 1.20% (0.27-2.13%) compared with placebo (all p < 0.05). There was no significant change in levels of exhaled NO or improvement in lung function and bronchial responsiveness. Low-dose theophylline induced antiinflammatory effects in asthma, reflected by a fall in airway eosinophils with no change in exhaled NO or changes in lung function.     

Effects of corticosteroids on noninvasive biomarkers of inflammation in asthma and chronic obstructive pulmonary disease

Exhaled breath analysis may be used to quantify inflammation and oxidative stress in the respiratory tract, in the differential diagnosis of airway diseases, and in the monitoring of therapy. The greatest progress has been made with standardized measurement of exhaled nitric oxide (NO). Bronchial NO is increased in asthma, correlated with other markers of inflammation, and reduced by treatment with corticosteroids and antileukotrienes. Alveolar NO is increased in chronic obstructive pulmonary disease (COPD), reflecting disease severity and progression. Exhaled carbon monoxide and ethane are increased in both asthma and COPD. Increased concentrations of 8-isoprostane, hydrogen peroxide, nitrite, and nitrotyrosine are found in exhaled breath condensate from patients with inflammatory lung diseases. Increased levels of lipid mediators are also found, and the pattern depends on the nature of the disease process. Additional biomarkers are exhaled breath temperature, which is elevated in asthma and reduced in COPD, and bronchial blood flow. It is likely that smaller and more sensitive analyzers will extend the discriminatory value of exhaled breath analysis and that new techniques will become available to diagnose and monitor respiratory diseases in the family practice and home settings.     

Exhaled biomarkers

Assessing airway and lung inflammation is important for investigating the underlying mechanisms of asthma and COPD. Yet these cannot be measured directly in clinical research and practice because of the difficulties in monitoring inflammation. Noninvasive monitoring may assist in early recognition of asthma and COPD, assessment of its severity, and response to treatment, especially during disease exacerbations. There is increasing evidence that breath analysis may have an important place in clinical management of asthma and COPD. The article reviews the role of current noninvasive measurements of exhaled gases, such as nitric oxide (NO), inflammatory markers in exhaled breath condensate (EBC), and exhaled breath temperature, as well as novel methods in monitoring and management of asthma and COPD.