Allergens, viruses, and asthma exacerbations

In adults and children with asthma, viral infections (rhinovirus [RV] infection being the most prevalent) will often trigger an increase in symptomatology. The mechanisms responsible for viral-induced exacerbations remain uncertain. Proposed mechanisms include direct infection of the lower respiratory tract, the inflammatory response to viruses, increases in bronchial responsiveness and up-regulation of intercellular adhesion molecule-1 expression in bronchial epithelium. In addition, exposure to allergens, especially seasonal allergens, in sensitized asthmatic individuals have been implicated in asthma attacks. Increased levels of exposure in sensitized asthmatics have been related to increases in hospital admissions and emergency room visits, increased bronchial hyperresponsiveness, increased levels of exhaled nitric oxide, lower levels of lung function, increased treatment requirements, and even increased mortality. In recent years studies have suggested that viruses and allergens may have a synergistic effect on individuals with asthma, thus having a greater influence on exacerbation rate together than either factor alone. Models of experimentally induced RV infection in both allergic and nonallergic individuals using bronchoalveolar lavage and segmental allergen challenge have helped researchers to investigate the possibility of an interaction between allergen sensitization, exposure, and virus infection and their role in the induction of an asthma exacerbation. This review aims to summarize the evidence supporting the role of viruses (in particular RV) as well as the role of, and interaction with, allergen sensitization and exposure on exacerbations of asthma.     

Quantitative and qualitative analysis of rhinovirus infection in bronchial tissues

Although rhinovirus (RV) infections can cause asthma exacerbations and alter lower airway inflammation and physiology, it is unclear how important bronchial infection is to these processes. To study the kinetics, location, and frequency of RV appearance in lower airway tissues during an acute infection, immunohistochemistry and quantitative polymerase chain reaction analysis were used to analyze the presence of virus in cells from nasal lavage, sputum, bronchoalveolar lavage, bronchial brushings, and biopsy specimens from 19 subjects with an experimental RV serotype 16 (RV16) cold. RV was detected by polymerase chain reaction analysis on cells from nasal lavage and induced sputum samples from all subjects after RV16 inoculation, as well as in 5 of 19 bronchoalveolar lavage cell samples and in 5 of 18 bronchial biopsy specimens taken 4 days after virus inoculation. Immunohistochemistry detected RV16 in 39 and 36% of all biopsy and brushing samples taken 4 and 15 days, respectively, after inoculation. Infected cells were primarily distributed in discrete patches on the epithelium. These results confirm that infection of lower airway tissues is a frequent finding during a cold and further demonstrate a patchy distribution of infected cells, a pattern similar to that reported in upper airway tissues.     

Innate immunity in the pathogenesis of virus-induced asthma exacerbations

The major asthma morbidity, mortality, and health care costs are a result of acute exacerbations. However, exacerbations are only partially responsive to current therapies and new approaches to treatment are needed. The great majority of acute asthma exacerbations are associated with respiratory viral infections and, of viruses implicated, approximately 60% are human rhinoviruses (RVs). The mechanisms of RV-induced asthma exacerbations are poorly understood. We have previously shown that adults with asthma have increased susceptibility to naturally occurring RV infections. Our recent studies have investigated mechanisms of innate host defense against RV infection. First, primary bronchial epithelial cells from subjects with asthma were shown to replicate RV in vitro to several logs, whereas those of normal control subjects were resistant to infection. This resistance was a result of rapid induction of apoptosis and of interferon (IFN)-beta in the normal cells, whereas these responses were deficient in asthmatic cells. These studies were recently extended to a novel family of three related proteins, the IFN-lambdas 1-3, production of which was also deficient in vitro and related to asthma exacerbation severity in vivo. These studies identify novel mechanisms for the increased susceptibility of subjects with asthma to RV infection. Further studies are now required to investigate whether administration of IFN-beta or IFN-lambda may be beneficial in the treatment of asthma exacerbations, to determine whether similar deficiencies are observed in children and in subjects with nonatopic asthma, and to investigate the mechanisms of deficient IFN production in asthma to help identify better therapeutic strategies for asthma exacerbations.     

Interleukin-13 and interleukin-5 in induced sputum of eosinophilic bronchitis: comparison with asthma

STUDY OBJECTIVES: Experimental studies on asthma have indicated that interleukin (IL)-13 induces airway hyperreactivity (AHR). However, it remains unproven that IL-13 is responsible for AHR in asthmatic patients. Eosinophilic bronchitis (EB) shows normal airway responsiveness despite eosinophilic airway inflammation of severity similar to that of asthma. This study evaluated the role of IL-13 in asthma by comparing the sputum IL-5 and IL-13 levels in both groups. METHODS: Comparisons between asthma and EB would clarify the role of IL-13 in AHR. IL-5 and IL-13 were assayed in the sputum and culture supernatants of peripheral blood mononuclear cells (PBMCs) from 22 asthmatic patients, 12 EB patients, and 11 healthy control subjects. RESULTS: IL-13 levels were higher in the asthmatic patients than in the EB patients or healthy control subjects (p = 0.001). IL-5 levels were similar in the asthmatic patients and EB patients, who had significantly higher levels than those of healthy control subjects. Sputum IL-13, but not IL-5, is inversely correlated with the provocative concentration of a substance causing a 20% fall in FEV1 for methacholine in asthmatic patients (r = -0.502; p = 0.017). IL-13 production by PBMCs was significantly higher in asthmatic patients than in EB patients (p = 0.015), but the levels between EB patients and healthy control subjects was comparable. CONCLUSION: The results of the present study indicate that IL-13 is related to AHR in asthmatic patients.     

Different airway inflammatory responses in asthmatic and healthy humans exposed to diesel.

Particulate matter (PM) pollution adversely affects the airways, with asthmatic subjects thought to be especially sensitive. The authors hypothesised that exposure to diesel exhaust (DE), a major source of PM, would induce airway neutrophilia in healthy subjects, and that either these responses would be exaggerated in subjects with mild allergic asthma, or DE would exacerbate pre-existent allergic airways. Healthy and mild asthmatic subjects were exposed for 2 h to ambient levels of DE (particles with a 50% cut-off aerodynamic diameter of 10 microm (PM10) 108 microg x m(-3)) and lung function and airway inflammation were assessed. Both groups showed an increase in airway resistance of similar magnitude after DE exposure. Healthy subjects developed airway inflammation 6 h after DE exposure, with airways neutrophilia and lymphocytosis together with an increase in interleukin-8 (IL-8) protein in lavage fluid, increased IL-8 messenger ribonucleic acid expression in the bronchial mucosa and upregulation of the endothelial adhesion molecules. In asthmatic subjects, DE exposure did not induce a neutrophilic response or exacerbate their pre-existing eosinophilic airway inflammation. Epithelial staining for the cytokine IL-10 was increased after DE in the asthmatic group. Differential effects on the airways of healthy subjects and asthmatics of particles with a 50% cut-off aerodynamic diameter of 10 microm at concentrations below current World Health Organisation air quality standards have been observed in this study. Further work is required to elucidate the significance of these differential responses.     

Analysis of sputum cell counts during spontaneous moderate exacerbations of asthma in comparison to the stable phase.

BACKGROUND: Acute airway inflammation is considered to characterize asthma exacerbations, but its specific cellular pattern has not yet been completely evaluated. AIM: To evaluate the prevalence of sputum eosinophilia during acute asthma exacerbations of moderate severity, compared with a stable phase of the disease, and to assess the concordance between changes in pulmonary function and sputum eosinophilia in the period between exacerbation and post exacerbation. METHODS: We compared sputum and blood inflammatory cell counts in 29 asthmatic subjects during a spontaneous moderate exacerbation of asthma (visit 1) with sputum and blood cell counts measured 4 weeks after the resolution of asthma exacerbation (visit 2). At visit 1, all subjects required an appropriate 1 week treatment with oral corticosteroids. RESULTS: At visit 1, all subjects were able to collect spontaneous sputum, whereas at visit 2 sputum was induced by inhalation of hypertonic saline (NaCl 3, 4, and 5%, 10 minutes each) with beta2-agonist pretreatment. Asthma exacerbation was accompanied by a significant increase in sputum eosinophil percentages compared with levels after exacerbation [25% (1-78) versus 4% (0-23), p<0.05). Only four subjects showed low sputum eosinophil percentages during exacerbation, and these showed no differences in main clinical findings with respect to subjects with sputum eosinophilia. At visit 2, the stability of asthma was assessed on the basis of PEF, FEV1, symptoms, and use of rescue beta2-agonist. Asthma was defined as stable in 21 out of 29 subjects. Sputum eosinophil percentages fell significantly between visit 1 and visit 2 in both stable and unstable patients, but at visit 2 sputum eosinophil percentages were still high in subjects with unstable asthma. In patients who proved to be stable at visit 2, there was a significant correlation between the changes recorded in sputum eosinophil percentages and in FEV1 between the two visits (rho: 0.723, p<0.001). CONCLUSION: Sputum cosinophil but not neutrophil percentages increase in most asthmatic subjects during moderate exacerbation of asthma. Changes in the degree of airway eosinophilic inflammation are related to changes in the severity of airway obstruction during asthma exacerbation.     

Rhinovirus-16 colds in healthy and in asthmatic subjects: similar changes in upper and lower airways.

Rhinovirus (RV) infections appear to precipitate most asthma exacerbations. To investigate whether RV-16 induces different inflammatory changes in upper and lower airways of asthmatic and healthy subjects, we inoculated 10 nonatopic healthy and 11 atopic asthmatic adults with 2,000 TCID50 RV-16. Subjects recorded symptoms and peak flow daily; and they underwent spirometry, methacholine challenge (PC20), nasal lavage, and sputum induction at baseline and on Days 2, 4, 15, and 29 d after inoculation. One asthmatic subject developed an exacerbation requiring prednisone treatment 5 d after inoculation. The cold symptom severity (Jackson score) did not differ between groups. During the cold, asthma symptoms increased slightly from baseline in the asthmatic group; and PC20 decreased in the healthy group. However, peak flow, bronchodilator use, and spirometry did not change in either group. At baseline, asthmatics had higher neutrophils, eosinophils, and interleukin (IL)-6 in nasal lavage. After inoculation, both groups developed significant increases in nasal neutrophils, IL-6 and IL-8, and modest increases in sputum neutrophils and IL-6, but not IL-8. However, these changes did not differ between groups. IL-5, interferon-gamma, and RANTES were detected only in nasal lavages from two asthmatic subjects, who had the most severe colds. IL-11 was not detected in any sample. We conclude that inflammatory responses of upper and lower airways during RV-16 colds are similar in asthmatic and healthy subjects, and that RV-16 infection is not by itself sufficient to provoke clinical worsening of asthma.     

Smoking and airway inflammation in patients with mild asthma.

STUDY OBJECTIVES: Cigarette smoking is common in asthmatic patients, and we investigated the impact of cigarette smoking on airway inflammation in asthma. DESIGN: Single-center observational study of airway inflammation in asthmatic and healthy smokers and nonsmokers. SETTING: Asthma research unit in a university hospital. PATIENTS OR PARTICIPANTS: Sixty-seven asthmatic and 30 nonasthmatic subjects classified as smokers or nonsmokers. Asthmatics had chronic, stable asthma and were not receiving inhaled or oral steroids at the time of the study. INTERVENTIONS: We examined induced-sputum cell counts and levels of interleukin (IL)-8 and eosinophilic cationic protein (ECP). Bronchial hyperreactivity was assessed using methacholine challenge. MEASUREMENTS AND RESULTS: Asthmatic smokers had higher total sputum cell counts than nonsmoking asthmatics and both smoking and nonsmoking healthy subjects. Smoking was associated with sputum neutrophilia in both asthmatics and nonasthmatics (median, 47% and 41%, respectively) compared with nonsmokers (median, 23% and 22%, respectively), and sputum IL-8 was increased in smokers compared with nonsmokers, both in subjects with asthma (median, 945 pg/mL vs 660 pg/mL, respectively) and in healthy subjects (median, 1,310 pg/mL vs 561 pg/mL, respectively). Sputum eosinophils and ECP levels were higher in both nonsmoking and smoking asthmatics than in healthy nonsmokers. In smoking asthmatics, lung function (FEV(1) percent predicted) was negatively related to both sputum IL-8 (r = - 0.52) and sputum neutrophil proportion (r = - 0.38), and sputum IL-8 correlated positively with smoking pack-years (r = 0.57) and percent neutrophil count (r = 0.51). CONCLUSIONS: In addition to the eosinophilic airway inflammation observed in patients with asthma, smoking induces neutrophilic airway inflammation; a relationship is apparent between smoking history, airway inflammation, and lung function in smoking asthmatics.     

Rhinovirus-induced interferon-gamma and airway responsiveness in asthma

The majority of asthma exacerbations are caused by respiratory infections, with rhinovirus (RV) being the most common virus. Recent evidence has suggested that decreased generation of IFN-gamma is associated with more severe colds and delayed elimination of virus. Whether the generation of IFN-gamma also has any relationship to general features of asthma severity has yet to be determined. To evaluate this hypothesis, peripheral blood mononuclear cells from 19 subjects with atopy and asthma were incubated with RV16 for 6 days to determine IFN-gamma and interleukin (IL)-5 production; these responses were then compared with measurements of airflow obstruction and airway responsiveness. RV16-induced IFN-gamma production correlated significantly with the methacholine PD (r = 0.50, p = 0.03), and the ratio of RV16-induced IFN-gamma:IL-5 correlated with % predicted FEV1 (r = 0.53, p = 0.02). In contrast, there were no significant associations between measures of asthma severity and RV-induced IL-5. These findings suggest that a cytokine imbalance with a deficient Th1 response to RV, but not a Th2 response, is associated with measures of asthma severity and support the concept that impaired antiviral responses may be associated with asthma severity.     

Lipopolysaccharides promote a shift from Th2-derived airway eosinophilic inflammation to Th17-derived neutrophilic inflammation in an ovalbumin-sensitized murine asthma model

Introduction: The currently available treatments for severe asthma are insufficient. Infiltration of neutrophils rather than eosinophils into the airways is an important inflammatory characteristic of severe asthma. However, the mechanism of the phenotypic change from eosinophilic to neutrophilic inflammation has not yet been fully elucidated. Methods: In the current study, we examined the effect of lipopolysaccharides (LPS) on eosinophilic asthmatic mice sensitized with ovalbumin (OVA), as well as the roles of interleukin (IL)-17A/T helper (Th) 17 cells on the change in the airway inflammatory phenotype from eosinophilic to neutrophilic inflammation in asthmatic lungs of IL-17A-deficient mice. Results: Following exposure of OVA-induced asthmatic mice to LPS, neutrophil-predominant airway inflammation rather than eosinophil-predominant inflammation was observed, with increases in airway hyperresponsiveness (AHR), the IL-17A level in bronchoalveolar lavage fluid (BALF) and Th17 cells in the spleen and in the pulmonary hilar lymph nodes. Moreover, the neutrophilic asthmatic mice showed decreased mucus production and Th2 cytokine levels (IL-4 and IL-5). In contrast, IL-17A knockout (KO) mice exhibited eosinophil-predominant lung inflammation, decreased AHR, mucus overproduction and increased Th2 cytokine levels and Th2 cells. Conclusion: These findings suggest that the eosinophilic inflammatory phenotype of asthmatic lungs switches to the neutrophilic phenotype following exposure to LPS. The change in the inflammatory phenotype is strongly correlated with the increases in IL-17A and Th17 cells.     

Dysfonctionnement nasal chronique et obstruction des voies aériennes périphériques

Allergic rhinitis often occur at the same time with many upper and lower airway diseases in which there is asthma. Many patients without clinical asthma may have an asymptomatic bronchial hyperreactivity and an allergic rhinitis at the same time. An overview of these actual knowledges is done including clinical, respiratory functional explorations, therapeutic studies, as well as those observed in chronic nasal dysfunctions (allergic or non allergic eosinophilic rhinitis, nasal polyposis, chronic rhinitis).Objectives. – The aim of this study is to determine bronchial hyperresponsiveness of a chronic nasal dysfunction population having allergic or non allergic rhinitis.Material and methods. – Retrospective study of respiratory functional explorations (using a methacholine provocation test) among non asthmatic patients consulting for rhinology-allergy diseases but with broncho-pulmonary symptomatology.Results. – It has been observed an allergic rhinitis population without upper bronchial hyperreactivity but with a small airway obstruction revealed or worsened during the methacholine bronchoprovocation test.Conclusion. – Chronic nasal dysfunction and small airway obstruction are correlated. This association shows an airway inflammation from the nose through the small bronchi. As upper bronchial hyperreactivity can precede asthma, a small airway obstruction could precede a bronchial hyperreactivity. Nasal chronic dysfunction treatment could act upon small airway obstruction, or central bronchial hyperreactivity or asthma appearance.     

Pattern of airway inflammation and its determinants in children with acute severe asthma.

The aim of this study was to examine the relationship between sputum cell counts and clinical variables in children with an acute exacerbation of asthma. Sputum was successfully obtained from 37 of 42 children presenting to the Emergency Department with acute asthma, using ultrasonically nebulized normal saline (n = 19) or spontaneous expectoration (n = 18). Sputum portions were selected and dispersed, and total and differential cell counts were performed. Sputum supernatant was assessed for eosinophil cationic protein (ECP), interleukin (IL)-5, and IL-8. The exacerbations were of 3 inflammatory cell patterns: eosinophilic (n = 16 or 43% of total), combined eosinophilic/neutrophilic (E/N; n = 13.3 or 35% of total), or noneosinophilic (n = 8 or 22% of total). IL-5 was highest in eosinophilic exacerbations. Combined E/N exacerbations had increased mast cells (77%) and higher sputum ECP levels than eosinophilic exacerbations: 2,146 ng/mL vs. 666 ng/mL (P = 0.04). The speed of onset of the exacerbation was not related to the inflammatory cell profile. Logistic regression identified maintenance asthma treatment (odds ratio (OR), 5.9; 95% confidence interval (CI), 1.3-26.8) and lung function during the acute episode (OR, 4.0; 95% CI, 1.7-93) as significantly associated with the intensity of sputum eosinophilia. Eosinophils were lowest in children who received maintenance treatment with oral corticosteroids compared to those with no background asthma preventer therapy (P = 0.001). In conclusion, we identified three distinct patterns of airway inflammation in children with acute asthma; they included increased eosinophils, combined eosinophilic-neutrophilic infiltration, and a noneosinophilic pattern. Eosinophil degranulation was greatest with the combined eosinophilic/neutrophilic pattern of airway inflammation. Sputum eosinophils were associated with clinical severity, and background asthma therapy, but not with outcome, nor with speed of onset of exacerbations. These different inflammatory cell profiles imply different etiological agents and may require differing treatment strategies.     

Rhinovirus infection in nonasthmatic subjects: effects on intrapulmonary airways.

The common cold is a highly prevalent, uncomplicated upper airway disease. However, rhinovirus (RV) infection can lead to exacerbation of asthma, with worsening in airway hyperresponsiveness and bronchial inflammation. The current authors questioned whether such involvement of the intrapulmonary airways is disease specific. Twelve nonatopic, healthy subjects (forced expiratory volume in one second (FEV1) >80% predicted, provocation concentration causing a 20% fall in FEV1 (PC20) >8 mg x mL(-1)) were experimentally infected with RV16. Next to PC20 and the maximal response to methacholine (MFEV1 and MV'40p), the numbers of mucosal inflammatory cells and epithelial intercellular adhesion molecule (ICAM)-1 expression in bronchial biopsies were assessed before and 6 days after RV16 inoculation. RV16 infection induced a small but consistent increase in maximal airway narrowing, without a change in PC20. There was a significant increase in bronchial epithelial ICAM-1 expression after RV16, whereas inflammatory cell counts did not change. Nevertheless, the change in the number of submucosal CD3+ cells was correlated with the change in MV'40p. In conclusion, rhinovirus infection in normal subjects induces a limited, but significant increase in maximal airway narrowing, which is associated with changes in bronchial T-cell numbers. Together with the upregulation of bronchial epithelial intercellular adhesion molecule-1, these findings indicate that, even in healthy subjects, rhinovirus infection affects the intrapulmonary airways.     

The interplay between neuroendocrine activity and psychological stress-induced exacerbation of allergic asthma

Psychological stress is recognized as a key factor in the exacerbation of allergic asthma, whereby brain responses to stress act as immunomodulators for asthma. In particular, stress-induced enhanced type 2 T-helper (Th2)-type lung inflammation is strongly associated with asthma pathogenesis. Psychological stress leads to eosinophilic airway inflammation through activation of the hypothalamic-pituitary-adrenal pathway and autonomic nervous system. This is followed by the secretion of stress hormones into the blood, including glucocorticoids, epinephrine, and norepinephrine, which enhance Th2 and type 17 T-helper (Th17)-type asthma profiles in humans and rodents. Recent evidence has shown that a defect of the μ-opioid receptor in the brain along with a defect of the peripheral glucocorticoid receptor signaling completely disrupted stress-induced airway inflammation in mice. This suggests that the stress response facilitates events in the central nervous and endocrine systems, thus exacerbating asthma. In this review, we outline the recent findings on the interplay between stress and neuroendocrine activities followed by stress-induced enhanced Th2 and Th17 immune responses and attenuated regulatory T (Treg) cell responses that are closely linked with asthma exacerbation. We will place a special focus on our own data that has emphasized the continuity from central sensing of psychological stress to enhanced eosinophilic airway inflammation. The mechanism that modulates psychological stress-induced exacerbation of allergic asthma through neuroendocrine activities is thought to involve a series of consecutive pathological events from the brain to the lung, which implies there to be a “neuropsychiatry phenotype” in asthma.     

Different roles of interleukin-10 in onset and resolution of asthmatic responses in allergen-challenged mice

OBJECTIVE: Although interleukin (IL)-10 is an immunoregulatory cytokine produced by various cells including T cells, its precise role in asthma remains uncertain. The aim of this study was to investigate the role of IL-10 in experimental asthma using ovalbumin (OVA)-sensitized mice. METHODOLOGY: Mice were challenged with OVA aerosol, and airway responsiveness and inflammation were measured. OVA-specific IL-10-producing CD4+ T cells were counted from lung cells collected by enzymatic digestion and stimulated ex vivo with OVA. The effects of an anti-IL-10 antibody on airway responsiveness and inflammation were also evaluated. RESULTS: The OVA challenge caused airway hyperresponsiveness and eosinophilic inflammation. A significant increase in IL-10-producing CD4+ T cells was observed, mainly in the CD45RB(low) subset, for several days after the OVA challenge. Anti-IL-10 antibody treatment before the OVA challenge did not affect eosinophilic inflammation but significantly inhibited airway hyperresponsiveness 24 h after the OVA challenge. However, anti-IL-10 antibody treatment just before the last OVA challenge significantly attenuated the resolution of eosinophilic inflammation without affecting airway responsiveness 2 weeks after the OVA challenge. CONCLUSIONS: Intrinsic IL-10 may have a distinct role in the early and late phases of asthmatic responses. In the early phase, IL-10 induces airway hyperresponsiveness, while in the late phase IL-10 contributes to the resolution of eosinophilic inflammation.     

Persistent airway obstruction after virus infection is not associated with airway inflammation

BACKGROUND: This study examined the contribution of airway inflammation to the delayed lung function recovery that occurs in some people following virus-induced asthma exacerbations. METHODS: Subjects (n = 40) were recruited at hospital admission for acute asthma exacerbation. Respiratory virus infection was diagnosed by viral nucleic acid detection and/or cell culture, using induced sputum, nasal, or throat swabs. Data collected included lung function, answers to common cold and asthma control questionnaires, and induced sputum cellular profiles. Subjects were reexamined 4 to 6 weeks postexacerbation and were compared with stable asthmatic subjects (n = 26) who had been recruited from ambulatory care clinics. RESULTS: Persistent airway obstruction, defined as lung function improvement at follow-up (ie, change in FEV1 percent predicted [Delta%FEV1]) of <15%, was observed in 10 subjects (25%). Airway recovery (Delta%FEV1, > or = 15%) was observed in the remaining subjects (30 subjects; 75%). During the acute episode, the airway-recovery group had increased total cell count (p = 0.019), increased number of neutrophils (p = 0.005), and increased percentage of neutrophils (p = 0.0043) compared to the group of stable subjects with asthma. Postexacerbation, the airway-recovery group had reduced numbers of neutrophils and an increased percentage of eosinophils. In contrast, during exacerbation, subjects with persistent airway obstruction showed no differences in inflammatory cell counts compared to stable subjects with asthma, nor did cell counts change postexacerbation. Symptoms improved in both groups postexacerbation. However, in the persistent-airway-obstruction group, asthma remained uncontrolled. CONCLUSION: Persistent airway obstruction and uncontrolled asthma are observed in some people after viral asthma exacerbations. These abnormalities are not associated with inflammatory cell influx into the airway lining fluid during the exacerbation and may reflect the involvement of noncellular elements. Further work should explore other mechanisms leading to incomplete airway recovery.     

Dose-response evaluation of the therapeutic index for inhaled budesonide in patients with mild-to-moderate asthma

PURPOSE: Inhaled corticosteroids have beneficial effects on pulmonary function and inflammation in patients with asthma, but they also cause systemic adverse effects, such as adrenal suppression. We evaluated the therapeutic index of inhaled corticosteroids in asthmatic patients by comparing their dose-response effects on lung function, surrogate markers of airway inflammation, and tests of adrenal function. SUBJECTS AND METHODS: After a 10-day placebo run-in, we evaluated the effects of 200 microg, 400 microg, and 800 microg of inhaled budesonide, each dose given twice daily sequentially for 3 weeks in 26 patients, aged 35 +/- 12 years (mean +/- SD), with mild-to-moderate asthma. Measurements were made of bronchial reactivity, exhaled nitric oxide (a marker of airway inflammation), spirometry, serum eosinophilic cationic protein concentration, and 10-hour overnight urinary cortisol excretion. Plasma cortisol levels were measured at 8 AM and after stimulation with human corticotropin releasing factor. RESULTS: For measurements of pulmonary function and exhaled nitric oxide, there was a plateau in the mean response to budesonide between 400 microg (low dose) and 800 microg (medium dose) per day, whereas for eosinophilic cationic protein and bronchial challenge, maximal benefits occurred between 800 and 1,600 microg (high dose) per day. Effects on plasma cortisol levels showed maximal suppression at 1,600 microg of budesonide per day. The proportion of patients with an optimal therapeutic index, in terms of a good airway response (fourfold decrease in bronchial hyperreactivity) and minimal systemic response (overnight urinary cortisol greater than 20 nmol), was similar at low-dose (46%) and at high-dose (52%) budesonide. The proportion of patients with a suboptimal therapeutic index, a good airway response with a marked systemic response (overnight urinary cortisol greater than 20 nmol), increased from 4% at low dose to 38% at high dose. CONCLUSIONS: In patients with mild-to-moderate atopic asthma, there were dose-related effects of budesonide on surrogate markers of inflammation (bronchial hyperreactivity and serum eosinophilic cationic protein), although higher doses were associated with adrenal suppression and a decrease in the therapeutic index.     

Possible pathogenic roles of nitric oxide in asthma

Nitric oxide (NO) has broad physiologic functions, including vasodilation, bronchodilatation, neurotransmission, inflammation, and host defense. Fraction of exhaled NO (FeNO) is used as a biomarker of eosinophilic airway inflammation for asthma control. However, the role of NO in the pathogenesis and progression of asthma is not well understood. Additionally, the absence of bronchial eosinophilic inflammation, mucus hypersecretion, and increased Th2 cytokine levels in mice lacking NO synthase isoforms (n/i/eNOS^?/-), suggests that NO has an essential role in the promoting the pathogenesis of asthma. Recent clinical data investigating antibodies for interleukin (IL)-4 receptor α, which inhibits both IL-4 and IL-13 signaling, and anti-IL-13 antibody suggest a unique association between NO and the pathogenesis and progression of asthma. Antibody therapies targeting several cytokines may provide clues to elucidate the mechanisms underlying the pathogenesis and progression of asthma.     

Changes in bronchial inflammation during acute exacerbations of chronic bronchitis.

There are little data describing noncellular changes in bronchial inflammation during exacerbations of chronic bronchitis. The relationship between sputum colour and airway inflammation at presentation has been assessed during an exacerbation in patients with chronic bronchitis and a primary care diagnosis of chronic obstructive pulmonary disease. Sputum myeloperoxidase, neutrophil elastase, leukotriene B4 (LTB4), interleukin-8 (IL-8), sol:serum albumin ratio and serum C-reactive protein were measured in patients presenting with an exacerbation and mucoid (n = 27) or purulent sputum (n = 42). Mucoid exacerbations were associated with little bronchial or systemic inflammation at presentation, and sputum bacteriology was similar to that obtained in the stable state. Purulent exacerbations were associated with marked bronchial and systemic inflammation (p < 0.025 for all features) and positive sputum cultures (90%). Resolution was related to a significant reduction in LTB4 (p < 0.01), but no change in IL-8, suggesting that LTB4 may be more important in neutrophil recruitment in these mild, purulent exacerbations. In the stable state, IL-8 remained higher in patients who had experienced a purulent exacerbation (2p < 0.02). The presented results indicate that exacerbations of chronic bronchitis, defined by sputum colour, differ in the degree of bronchial and systemic inflammation. Purulent exacerbations are related to bacterial infection, and are associated with increased neutrophilic inflammation and increased leukotriene B4 concentrations.