Endobronchial adenosine monophosphate challenge causes tachykinin release in the human airway

BACKGROUND: Adenosine 5 monophosphate (AMP) has been shown to cause bronchoconstriction and a sensation of chest tightness when inhaled by asthmatic subjects. This response is attenuated after repeated inhalation of bradykinin, suggesting that AMP may act in part by the release of neuropeptides. OBJECTIVE: This study examined neuropeptide release in the human airway after endobronchial AMP challenge. METHODS: Endobronchial AMP challenge was performed in 20 subjects and tachykinin levels were measured after endobronchial AMP challenge and after placebo endobronchial challenge with saline. RESULTS: All subjects coughed immediately after adenosine challenge. There was a significant increase in neurokinin A and substance P levels (P < .01, P < .01 respectively) when post-saline and post-AMP levels were compared. There was, however, no significant change in calcitonin gene related peptide levels (P = .37). CONCLUSION: This study demonstrates that endobronchial AMP challenge causes tachykinin release in the human airway in vivo.     

Heparin attenuates symptoms and mast cell degranulation induced by AMP nasal provocation

BACKGROUND: Previous studies have shown that inhaled heparin attenuated the airway responses to allergen, exercise, and AMP bronchial provocation, possibly through an inhibition of mast cell activation. OBJECTIVE: The aim of this study was to provide the evidence of in vivo inhibition of human mast cell activation by heparin in a noninvasive model. METHODS: Nine atopic and 6 nonatopic subjects received placebo and unfractionated heparin sodium (5000 IU/mL) 15 minutes before an AMP nasal provocation in a double-blind crossover study design. The nasal lavage was collected from these subjects before or 3, 5, 15, or 30 minutes after the AMP nasal challenge, and concentrations of histamine and tryptase in the nasal lavage were measured. RESULTS: AMP nasal provocation produced considerable sneezing and induced a transient increase in histamine and tryptase release, with peak values achieved at 3 to 5 minutes after the challenge in all atopic subjects. Compared with placebo, inhaled heparin significantly attenuated the release of histamine and tryptase induced by AMP challenge (P=.012 and.004, respectively). Moreover, the AMP-induced sneezing was also inhibited by pretreatment with heparin (P=.016). In nonatopic subjects, AMP did not induce a significant increase in histamine and tryptase release on placebo-treated or heparin-treated days. CONCLUSION: These data suggest that AMP nasal provocation and AMP bronchial provocation cause mast cell mediator release in a similar fashion. In addition, the data support the hypothesis that inhaled heparin plays a protective role against AMP provocation by inhibition of mast cell activation.     

A comparison of three standard methods of identifying mast cells in endobronchial biopsies in normal and asthmatic subjects

Reported mast-cell counts in endobronchial biopsies from asthmatic subjects are conflicting, with different methodologies often being used. This study compared three standard methods of counting mast cells in endobronchial biopsies from asthmatic and normal subjects. Endobronchial biopsies were obtained from atopic asthmatic subjects ( n = 17), atopic nonasthmatic subjects ( n =6), and nonatopic nonasthmatic control subjects ( n =5). After overnight fixation in Carnoy's fixative, mast cells were stained by the short and long toluidine blue methods and antitryptase immunohistochemistry and were counted by light microscopy. Method comparison was made according to Bland & Altman. The limits of agreement were unacceptable for each of the comparisons, suggesting that the methods are not interchangeable. Coefficients of repeatability were excellent, and not different for the individual techniques. These results suggest that some of the reported differences in mast-cell numbers in endobronchial biopsies in asthma may be due to the staining method used, making direct comparisons between studies invalid. Agreement on a standard method is required for counting mast cells in bronchial biopsies, and we recommend the immunohistochemical method, since fixation is less critical and the resultant tissue sections facilitate clear, accurate, and rapid counts.     

Eosinophil traffic in the circulation following allergen challenge

BACKGROUND: Eosinophils contribute to the pathogenesis of asthma and localize to the lung after allergen exposure by uncertain mechanisms. METHODS: We used intrabronchial instillation of allergen to model the interaction between inhaled allergen and the lung. We measured the number of peripheral blood leukocytes and the expression of VLA-4 (CD49d), Mac-1 (CD11b) and PSGL-1 (CD162) up to 4 h after instillation of allergen into a bronchus of eight atopic asthmatics. For controls, we instilled normal saline into a subset of the asthmatic subjects, and allergen into nonatopic, nonasthmatic subjects. RESULTS: There were changes of total leukocyte number, number of polymorphonuclear leukocytes, lymphocytes, monocytes and eosinophils in all three groups (atopic asthmatics instilled with allergen, atopic asthmatics instilled with saline, nonatopic nonasthmatic subjects instilled with allergen), which were likely related to bronchoscopy. However, the decrease of eosinophils was significant only in the atopic asthmatics instilled with allergen. The remaining eosinophils in the allergen challenged asthmatics were not activated as defined by cell density or change of expression of VLA-4, Mac-1 and PSGL-1. CONCLUSIONS: While eosinophils rapidly and specifically leave the circulation after allergen challenge of atopic asthmatics, the remaining circulating eosinophils are not activated.     

Effects of inhaled corticosteroids on exhaled leukotrienes and prostanoids in asthmatic children

BACKGROUND: Lipid mediators play an important pathophysiologic role in atopic asthmatic children, but their role in the airways of atopic nonasthmatic children is unknown. OBJECTIVE: We sought (1) to measure leukotriene (LT) E 4 , LTB 4 , 8-isoprostane, prostaglandin E 2 , and thromboxane B 2 concentrations in exhaled breath condensate in atopic asthmatic and atopic nonasthmatic children; (2) to measure exhaled nitric oxide (NO) as an independent marker of airway inflammation; and (3) to study the effect of inhaled corticosteroids on exhaled eicosanoids. METHODS: Twenty healthy children, 20 atopic nonasthmatic children, 30 steroid-naive atopic asthmatic children, and 25 atopic asthmatic children receiving inhaled corticosteroids were included in a cross-sectional study. An open-label study with inhaled fluticasone (100 microg twice a day for 4 weeks) was undertaken in 14 steroid-naive atopic asthmatic children. RESULTS: Compared with control subjects, exhaled LTE 4 ( P <.001), LTB 4 ( P <.001), and 8-isoprostane ( P <.001) levels were increased in both steroid-naive and steroid-treated atopic asthmatic children but not in atopic nonasthmatic children (LTE 4 , P=.14; LTB 4 , P=.23; and 8-isoprostane, P=.52). Exhaled NO levels were increased in steroid-naive atopic asthmatic children ( P <.001) and, to a lesser extent, in atopic nonasthmatic children ( P <.01). Inhaled fluticasone reduced exhaled NO (53%, P <.0001) and, to a lesser extent, LTE 4 (18%, P <.01) levels but not LTB 4 , prostaglandin E 2 , or 8-isoprostane levels in steroid-naive asthmatic children. Conclusions Exhaled LTE 4 , LTB 4 , and 8-isoprostane levels are increased in atopic asthmatic children but not in atopic nonasthmatic children. In contrast to exhaled NO, these markers seem to be relatively resistant to inhaled corticosteroids.     

Improved bronchodilator effect of deep inhalation after allergen avoidance in asthmatic children

BACKGROUND: In healthy adults and children, deep inhalation (DI) is able to reverse induced bronchoconstriction. This ability is impaired in asthma, but the reasons are still to be elucidated. OBJECTIVES: This study investigated whether the bronchodilator effect of DI during methacholine-induced bronchoconstriction can be improved by allergen avoidance in asthmatic children, and its relationship with airway inflammation. METHODS: The effect of DI on methacholine-induced bronchoconstriction was studied at the beginning and the end of a 3-month allergen avoidance period at high altitude in 14 allergic asthmatic children who had severe asthma attacks. Changes in airway caliber were inferred from the respiratory resistance (Rrs) measured by a forced oscillation technique. Results were related to the percentage of eosinophils in induced sputum and compared with those obtained in 9 age-matched nonasthmatic children. RESULTS: In asthmatic subjects, DI had no significant effect on methacholine-induced increase in Rrs before (P=.62) but significantly reversed it after (P <.01) allergen avoidance. However, the ability of DI to reverse a methacholine-induced increase in Rrs tended to remain less in asthmatic than nonasthmatic children even after allergen avoidance (P=.05). In the asthmatic children, the percentage of eosinophils in induced sputum was decreased at the end of the allergen avoidance period (P <.001), without any significant correlation between sputum eosinophils and airway responsiveness to methacholine or effect of DI. CONCLUSION: A short period of allergen avoidance may improve the ability of DI to reverse induced bronchoconstriction in some asthmatic children. This effect is associated, yet not correlated, with a reduction in airway inflammation.     

CD14-dependent airway neutrophil response to inhaled LPS: role of atopy

BACKGROUND: Inhaled endotoxin (LPS) is associated with airway neutrophilic (PMN) inflammation in both asthmatic and control subjects, with asthmatic subjects demonstrating possibly higher sensitivity. CD14 is the principal receptor mediating LPS responses in vivo. It is unknown whether constitutive CD14 can predict the magnitude of the PMN response after LPS inhalation and whether atopy plays a role in this response. OBJECTIVE: We sought to examine associations between constitutive airway CD14 expression and LPS-induced PMNs after 5 microg of LPS inhalation and to examine associations between markers of atopy (eosinophils and eosinophil cationic protein) and CD14 expression and LPS-induced PMNs. METHODS: Ten atopic asthmatic subjects and 8 healthy control subjects inhaled 0.9% saline and LPS (Escherichia coli 026:B6, 5 microg) separated by 3 weeks. Induced sputum was collected at 24 hours before and 6 hours after inhalation. Induced sputum was analyzed for total and differential cell counts and soluble markers (soluble [s]CD14, eosinophil cationic protein, IL8, and total protein). Flow cytometry was used to analyze membrane-bound CD14 expression. RESULTS: Significant associations were found between the LPS-induced PMN response (PMNs per milligram of sputum) and both constitutive sCD14 (R = 0.7, P =.005) and membrane-bound CD14 (R = 0.9, P =.01). Asthmatic subjects demonstrated significantly higher levels of constitutive sCD14 compared with control subjects, and baseline eosinophils were significantly associated with baseline sCD14 (R = 0.7, P =.01) and LPS-induced PMNs (R = 0.6, P =.03). CONCLUSION: Constitutive airway CD14 expression can predict the magnitude of the PMN response after inhaled LPS. Atopy appears to play a role in the level of CD14 expression and may contribute to LPS sensitivity in asthmatic subjects.     

Basophil recruitment and IL-4 production during human allergen-induced late asthma

BACKGROUND: Basophils represent an important source of inflammatory mediators and cytokines after IgE-dependent activation in human beings. OBJECTIVE: To assess the role of basophils in allergic asthma, we measured the number of basophils in the bronchial mucosa and their capacity to express IL-4 mRNA and protein during allergen-induced late asthmatic responses. METHODS: Fiberoptic bronchoscopic bronchial biopsies were obtained at 24 hours from sites of segmental bronchial allergen challenge and control sites in 19 patients with atopic asthma and 6 nonatopic healthy volunteers. Basophil numbers were assessed by immunohistochemistry through use of mAb 2D7. IL-4 mRNA--positive cells were detected through use of in situ hybridization and colocalized to basophils through use of sequential immunohistochemistry/in situ hybridization. IL-4 protein was detected and colocalized to basophils through use of dual immunohistochemistry. RESULTS: After allergen challenge, there was an increase in the median number of 2D7-positive basophils per square millimeter in the bronchial mucosa in patients with asthma (0.9 cells/mm(2) at baseline to 8.8 cells/mm(2) after challenge; P =.002), which also was significantly higher than what was seen in nonasthmatic controls (P =.01). Similarly, IL-4 mRNA--positive cells were increased at 24 hours in patients with asthma (1.4 to 14) in comparison with controls (0 to 0; P =.02). Colocalization studies revealed that 15% and 41% of the basophil population in patients with asthma after allergen-challenge expressed, respectively, IL-4 mRNA and protein. Conversely, 19% of IL-4 mRNA-positive cells and 72% of IL-4 protein--positive cells were accounted for by basophils. CONCLUSION: After allergen provocation in sensitive patients with atopic asthma, basophils are recruited to the bronchial mucosa and express IL-4 mRNA and protein, which might contribute to local IgE synthesis and/or tissue eosinophilia or other aspects of allergic inflammation during late responses and ongoing asthma.     

The role of histamine in allergen and adenosine-induced bronchoconstriction

We have investigated the role of histamine in allergen and adenosine-5'-monophosphate (AMP)-induced bronchoconstriction in asthmatic subjects by performing inhalation challenge tests with histamine, AMP and allergen after treatment with placebo or the potent H1 histamine receptor antagonist, terfenadine. Single concentrations of each agonist which had previously been shown to produce a 30% fall in FEV1 were used. After placebo, AMP and histamine both produced rapid bronchoconstriction reaching a maximum within 5 min and returning to within 10% of baseline after 25 min. Terfenadine inhibited this reaction to histamine completely and to AMP by 86%. The response to allergen was slower in onset and was sustained over 45 min and was inhibited 50% by terfenadine. We interpret these results as reflecting the contribution of histamine to the various airway challenges, both histamine and newly generated mediators comprise the response to allergen, whereas AMP selectively enhances mast cell degranulation without affecting the production of arachidonic acid derived mediators.     

Airway immunopathology of asthma with exercise-induced bronchoconstriction

BACKGROUND: Exercise-induced bronchoconstriction (EIB) is a common cause of symptoms in a subgroup of asthmatic subjects. The pathobiology that makes this group of asthmatic subjects susceptible to bronchoconstriction after a brief period of exercise remains poorly understood. OBJECTIVE: We sought to determine whether there are differences in lower airway inflammation and production of cytokines and eicosanoids between asthmatic subjects with and without EIB. METHODS: Two distinct groups of asthmatic subjects based on a priori definitions were identified, one with moderate-to-severe EIB and the other without significant bronchoconstriction after exercise challenge. Both groups met the definition of asthma on the basis of bronchodilator response, bronchial hyperresponsiveness, or both. A comparative immunopathology study was conducted by using induced sputum to identify differences in lower airway inflammation and production of cytokines and eicosanoids. RESULTS: The groups had similar baseline lung function and bronchodilator response and did not have any asthma exacerbations within the prior year. The concentration of columnar epithelial cells was markedly higher in the group with EIB (1.4 x 10(5) vs 2.9 x 10(4) cells/mL, P=.01). The concentration of eosinophils was higher in the group with EIB (3.6 x 10(4) vs 4.9 x 10(3) cells/mL P=.04). Cysteinyl leukotrienes (CysLTs; 727.7 vs 151.9 pg/mL, P=.01) and the ratio of CysLTs to prostaglandin E(2) (1.85 vs 1.04, P=.002) in the airways were higher in the group with EIB. CONCLUSION: Injury to the airway epithelium, overexpression of CysLTs, relative under production of prostaglandin E(2), and greater airway eosinophilia are distinctive immunopathologic features of asthma with EIB.     

Effect of ozone and nitrogen dioxide on the release of proinflammatory mediators from bronchial epithelial cells of nonatopic nonasthmatic subjects and atopic asthmatic patients in vitro

BACKGROUND: Although studies have suggested that ozone (O3) and nitrogen dioxide (NO2) may play a role in the pathogenesis of asthma, the underlying mechanisms are not clear. OBJECTIVE: We aimed to investigate the effects of O3 and NO2 on the release of IL-8, GM-CSF, RANTES, and soluble intercellular adhesion molecule 1 (sICAM-1) from human bronchial epithelial cells (HBECs) of nonatopic nonasthmatic subjects (nonasthmatic subjects) and atopic subjects with mild asthma (asthmatic subjects) in vitro. METHODS: We cultured HBECs from bronchial biopsy specimens of nonasthmatic and asthmatic subjects; exposed these for 6 hours to air, 10 to 100 ppb O3, or 100 to 400 ppb NO2; and analyzed the release of IL-8, GM-CSF, RANTES, and sICAM-1 after 24 hours' incubation. RESULTS: There was no significant difference between the constitutive release of IL-8, GM-CSF, and sICAM-1 from HBECs of asthmatic and nonasthmatic subjects. RANTES was detected only in HBECs derived from asthmatic subjects. Exposure of HBECs of asthmatic subjects to both 50 to 100 ppb O3 and 200 to 400 ppb NO2 significantly increased the release of IL-8, GM-CSF, RANTES, and sICAM-1 from these cells after 24 hours of incubation. However, 50 to 100 ppb O3 and 200 to 400 ppb NO2 led to a significant increase in release of only IL-8 and sICAM-1 from HBECs of nonasthmatic subjects after 24 hours' incubation. A comparison between the pollutant-induced release of mediators demonstrated that 100 ppb O3-induced release of GM-CSF and sICAM-1 was significantly greater in HBECs of asthmatic subjects (medians, 0.59 and 27.4 pg/microg cellular protein, respectively) than in HBECs of nonasthmatic subjects (medians, 0.27 and 14.4 pg/microg cellular protein, respectively; P < .02). CONCLUSION: These results suggest that O3 and NO2 may modulate airway diseases, such as asthma, by increasing the release of inflammatory mediators from bronchial epithelial cells and that the cells of asthmatic subjects may be more susceptible to the adverse effects of these pollutants.     

Inhibition of mast cell tryptase by inhaled APC 366 attenuates allergen-induced late-phase airway obstruction in asthma

BACKGROUND: APC 366, a selective inhibitor of mast cell tryptase, has been shown to inhibit antigen-induced early asthmatic response (EAR), late asthmatic response (LAR), and bronchial hyperresponsiveness (BHR) in a sheep model of allergic asthma. OBJECTIVE: The purpose of this study was to investigate the effects of APC 366 on antigen-induced EAR, LAR, and BHR in mild atopic asthmatics not on any anti-inflammatory therapy. METHODS: Sixteen mild atopic asthmatics, each with a demonstrable antigen-induced EAR, LAR, and BHR to histamine, were recruited into this randomized, double-blinded, crossover study. APC 366 (5 mg)/placebo was administered by aerosol inhalation 3 times per day on treatment days 1 through 4. Allergen challenge was carried out on day 4. Histamine challenge was performed the following morning, 1 hour after final dosing. RESULTS: Subjects were shown to have a significantly smaller overall mean area under the curve for the LAR (P =.012) and mean maximum fall in FEV(1) for the LAR (P =.007) after pretreatment with APC 366 in comparison with placebo. No significant effects on BHR were demonstrable. Although the EAR was reduced by 18% after treatment with APC 366 in comparison with placebo, this was not statistically significant. CONCLUSION: Short-term repeated administration of APC 366 significantly reduced the magnitude of antigen-induced LAR in atopic asthmatics, which supports the role of mast cell tryptase in the pathophysiology of the LAR.     

Identification of IL-16 as the lymphocyte chemotactic activity in the bronchoalveolar lavage fluid of histamine-challenged asthmatic patients

Objective: We have previously demonstrated that the earliest lymphocyte chemotactic factors present in bronchoalveolar lavage fluid (BALF) of subjects with atopic asthma after subsegmental antigen challenge are IL-16 and MIP-1α, of which IL-16 appears to contribute a majority of the chemotactic activity. Because IL-16 is released in vitro after histamine stimulation of CD8⁺ T cells and epithelial cells, we evaluated the potential role of histamine in the release of IL-16 into the airways of allergic asthmatics in vivo. Methods: Eight allergic asthmatic subjects, six normal subjects, and six atopic nonasthmatic subjects were challenged with saline in the lingula and with serial concentrations of histamine (1 × 10^-7 to 5 × 10^-5 mol/L) in the right middle lobe followed by bronchoalveolar lavage (BAL) 15 minutes and 6 hours later. Results: The BALF from saline- and histamine-challenged lobes of normal subjects and atopic nonasthmatic subjects contained no significant lymphocyte chemoattractant activity. In six of the eight atopic asthmatic subjects, the histamine-challenged but not saline-challenged segment contained IL-16 chemotactic activity but no other identifiable lymphocyte chemoattractant activities at 6 hours. Conclusions: IL-16 appears in the airways after histamine challenge and therefore could contribute to the earliest infiltration of CD4⁺T cells and eosinophils observed after antigen challenge due to histamine release from mast cells. (J Allergy Clin Immunol 1998;101:786-792.)     

Airway refractoriness to adenosine 5'-monophosphate after repeated inhalation

Adenosine-5'-monophosphate (AMP) is a bronchoconstrictor agonist in subjects with atopic and nonatopic asthma. In this study we have investigated the effect of repeated airway challenge with AMP in 10 atopic, subjects without asthma. At the first visit, subjects had repeated inhalation challenges with increasing doubling concentrations of AMP, and the provocation concentration required to reduce FEV1 by 20% of baseline was determined (PC20 AMP). When the FEV1 had returned to within 5% of the baseline, the AMP challenge test was repeated on a further one or two occasions. When the maximum concentration of AMP (400 mg/ml) failed to produce a PC20, a bronchial provocation test with histamine was performed and the PC20 was determined. On the second visit, the effect of three consecutive inhalation challenge tests with histamine on the airway response to this agonist was determined. On the third visit, the duration of induced refractoriness to AMP was assessed. With the first AMP challenge, all subjects demonstrated bronchoconstriction with a geometric mean (GM) PC20 of 332 mg/ml. With a second AMP challenge, five of the 10 subjects became refractory and failed to achieve a PC20. In the remaining five subjects, the GM PC20 increased from 110 to 583 mg/ml. With a third AMP challenge, these subjects also failed to achieve a PC20. The initial GM PC20 histamine for the group was 22.9 mg/ml, which did not change significantly with two further histamine challenges or when the airways were refractory to AMP, suggesting that loss of AMP effect was not related to loss of contractility of airway smooth muscle or down regulation of H1-histamine receptors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Adenosine-induced bronchoconstriction in asthma: Role of mast cell-mediator release

Adenosine, when it is administered by inhalation to asthmatic subjects, is a potent bronchoconstrictor, although its mechanism of action is not known. Since adenosine has been demonstrated to potentiate IgE-dependent mediator release from mast cells, we have investigated the possible relationship between adenosine-induced bronchoconstriction and release of mast cell mediators in 14 asthmatic subjects. In the first study the effect of the putative mast cell-stabilizing drug cromolyn sodium (SCG) was observed on the dose-related changes in SG_aw and FEV₁ produced by inhaled adenosine and histamine in seven subjects. Inhaled SCG (20 mg) had no effect on the airway responses to histamine. In contrast SCG significantly protected against adenosine-induced bronchoconstriction in four of the seven subjects as reflected by a decrease in the airway response to the highest concentrations of adenosine, from 65 ± 8% to 12 ± 3% (mean ± SEM) for SG_aw and 31 ± 7% to 8 ± 3% for FEV,. Those three subjects whose adenosine response was unaffected by SCG had received regular SCG until 12 hr before the studies. In a separate study on eight subjects, a single inhalation of adenosine, causing a maximum 61 ± 4% fall in SG_aw at 10 min, had no significant effect on circulating levels of histamine, neutrophil chemotactic factor, or cyclic AMP. Together these two studies suggest that bronchoconstriction produced by adenosine is not a consequence of enhanced mast cell-mediator release and that the inhibitory effects of SCG occur by a mechanism other than through mast cell stabilization.     

Differences in mediator release between allergic rhinitis and asthma

To determine why patients with allergic rhinitis alone differ in their airway response to inhaled allergen compared to patients with allergic asthma, bronchial lavage was performed in 10 subjects with allergic asthma and in five subjects with allergic rhinitis, before and after inhalation challenge with antigen to produce an immediate asthmatic reaction. Before antigen challenge, the subjects with asthma had higher absolute neutrophil counts in the lavage fluid. After antigen challenge, the subjects with asthma released significant amounts of bronchoconstrictive mediators, such as histamine and thromboxane B2 into the lavage fluid, whereas subjects with rhinitis alone did not. There was also a significant increase in prostaglandin E2 in the subjects with asthma after antigen challenge. Nonimmunologic bronchoconstriction with methacholine inhalation challenge in six other subjects with asthma did not demonstrate an increase in any of the lavage fluid mediator levels that were measured. A positive correlation was found between methacholine provocative concentration causing a 20% drop in FEV1 and the concentration of prostaglandin E2 in the lavage fluid before challenge. The significance of this observation has yet to be determined. The results suggest that subjects with allergic asthma differ from subjects with rhinitis alone in their capacity to release more mediators into the airways on antigen challenge. It is not known whether this increase in mediators is due to increase in the number of mast cells in the airways or due to increase in mediator releasability from the mast cells of subjects with asthma.     

Comparison of plasma histamine and cyclic nucleotides after antigen and methacholine inhalation in man

Serial determinations of plasma histamine and cyclic nucleotides (adenosine monophosphate [AMP] and guanosine monophosphate [GMP]) were performed after inhalation of antigen and methacholine in four groups of subjects. In the first group, consisting of six antigen-sensitive subjects exhibiting bronchospasm after inhalation of ragweed or grass antigen, plasma histamine was elevated within 2 min and persisted for 30 min after inhalation of antigen. Peak histamine levels were between 18 to 80 ng/ml. In the second group, consisting of four nonatopic subjects, neither bronchospasm nor histamine was observed, despite inhalation of the same or 10-fold increased concentrations of antigen. In the third group, consisting of six subjects (three atopic and three nonatopic) exhibiting bronchospasm after inhalation of 2.5 to 10 mg of methacholine, sustained increases of histamine began at 1 min and persisted for 60 min after inhalation of methacholine. In the fourth group, seven subjects (two atopic, five nonatopic) without demonstrable bronchospasm despite inhalation of 2.5- to 10-fold increased doses of methacholine, no histamine was detected in the plasma at any time after inhalation of methacholine. Serial measurements of cyclic nucleotides showed no consistent changes in serum levels of cyclic AMP or cyclic GMP following inhalation challenge. We conclude that serum levels of histamine but not cyclic nucleotides change during bronchospasm induced by either antigen or methacholine.     

Array-based diagnostic gene-expression score for atopy and asthma

Whether gene expression is useful in discriminating different atopic phenotypes is unclear. The aim of the study was to evaluate a gene-expression score for the diagnosis of atopy and asthma and to assess disease activity as a guide for therapeutic decisions. Purified mRNA from PBMCs of 18 atopic asthmatic subjects, 8 atopic nonasthmatic subjects, and 14 healthy control subjects was hybridized to cDNA membranes. A composite atopy gene expression (CAGE) score was determined by using 10 genes dysregulated in atopic individuals according to a specific algorithm. The CAGE score was better than total IgE in differentiating atopic from nonatopic subjects (sensitivity, 96%; specificity, 92%). Correlation between the CAGE score and total IgE (P <.001) was found, and there was a trend for correlation with asthma severity (P =.051). The CAGE score was able to quantify phenotype-specific alteration in gene expression of atopic individuals. The CAGE score might be used as a diagnostic tool or to monitor the effects and side effects of therapy.     

Exhaled nitric oxide levels and airway responsiveness to adenosine 5'-monophosphate in subjects with nasal polyposis

BACKGROUND:It is widely appreciated that asthma is an inflammatory disease of the airways associated with airway hyperresponsiveness, and that nasal polyposis and asthma are related diseases. The objective of this study was to determine differences in exhaled nitric oxide (ENO) levels and airway responsiveness to adenosine 5'-monophosphate (AMP) between nonasthmatic patients with nasal polyposis and healthy controls. METHODS: Twenty patients without asthma with nasal polyposis and 16 healthy control subjects were enrolled in the study. Participants were challenged with increasing concentrations of AMP and methacholine. ENO was measured with the single-exhalation method. RESULTS: Bronchoconstriction in response to AMP was detected in 7 (35%) subjects with nasal polyposis. The geometric mean (95% CI) of ENO for subjects with nasal polyposis was 33.1 parts per billion (ppb) (24.0-45.7 ppb) compared with 12.3 ppb (8.5-18.2 ppb) for the healthy controls (p = 0.0002). ENO values were significantly higher in atopic than in nonatopic subjects with nasal polyposis [51.3 ppb (32.3-83.2 ppb) vs. 24.5 ppb (16.2-37.1 ppb), p = 0.02]. Nonatopic subjects with nasal polyposis also had higher concentrations of ENO than healthy control subjects (p = 0.016). CONCLUSIONS: Inhaled AMP causes airway narrowing in a significantly higher proportion of nonasthmatic subjects with nasal polyposis than in healthy controls. Furthermore, increased concentrations of ENO are detected in atopic and nonatopic subjects with nasal polyposis. These results suggest that bronchial inflammation is present in nonasthmatic subjects with nasal polyposis.