Leukotriene C4 and histamine in early allergic reaction in the nose

We have examined the measurements of LTC4 and histamine in nasal lavage fluids and blown secretions as a possible model of the early mediator events during nasal allergy. A nasal challenge with grass pollen extract was undertaken on two separate occasions in 20 patients with a history of seasonal rhinitis and a positive immediate skin test to grass pollen. A 2 ml nasal lavage was performed before allergen challenge, and blown secretion collected separately 15 min after the provocation, followed by a final 2 ml nasal lavage. The dilution of nasal secretion by the lavage fluid was determined using 99mTc-labelled albumin as an exogenous marker added to the fluid. The amounts of admixture in the nasal lavages did not correlate to the concentrations of LTC4 and histamine, indicating that the variable amounts of nasal secretion in nasal lavage do not constitute a confounding variable for measurements of LTC4 and histamine. In the pre-challenge lavages, the median concentrations, of LTC4 and histamine were 1.7 and 52 nmol/l respectively. Following allergen challenge neither LTC4 nor histamine measured in nasal lavage showed any significant change from pre-challenge baseline values. However, measurements of both mediators in the blown secretion showed a significantly higher concentration than in the pre- or post-challenge lavage samples, compatible with transitory release during the acute allergic reaction. However, it seems doubtful whether measurements of LTC4 or histamine can be compared between blown secretion and nasal lavage fluid, even if the dilution factor is disregarded.(ABSTRACT TRUNCATED AT 250 WORDS)     

Allergen-induced nasal hyperreactivity appears unrelated to the size of the nasal and dermal immediate allergic reaction

It has been previously demonstrated in nasal challenge studies that there is an increased sensitivity to allergen following an initial allergen challenge. A similar feature has been demonstrated following natural allergen exposure in patients with seasonal allergic rhinitis. To further explore the characteristics of this "priming" phenomenon and its relationship to other expressions of their allergic airway disease, 28 hay fever patients with strictly seasonal disease were studied. Skin tests with the relevant pollen allergen and histamine were performed and the size of the immediate and late phase allergic reaction was determined. An initial nasal allergen challenge was followed by a rechallenge of the nose with allergen 24 h later using a lavage technique. Determinations of TAME-esterase activity, as a biochemical marker of the allergic reaction, were made in the returned lavage fluid. The number of sneezes was counted and nasal symptoms were also assessed using a scoring technique. 19 of 28 patients (67%), displayed an increased responsiveness at rechallenge with similar findings in terms of symptom scores and TAME-esterase measurements. The increase was statistically significant for the symptoms of nasal blockage, which increased from 0.7 +/- 0.1 (mean +/- SEM) to 1.1 +/- 0.2 (P less than 0.05), and nasal secretion which rose from 1.1 +/- 0.2 to 1.7 +/- 0.2 (P less than 0.01). A composite nasal symptom score which also took account of the number of sneezes, increased from 2.9 +/- 0.4 to 4.0 +/- 0.3 (P less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of fluticasone propionate aqueous nasal spray on allergen-induced inflammatory changes in the nasal airways of allergic rhinitics following exposure to nitrogen dioxide

BACKGROUND: The authors have recently demonstrated that prior exposure for 6 h to 400 p.p.b. nitrogen dioxide significantly enhances the early phase response of eosinophils in the nasal airways of allergic rhinitics to subsequent allergen provocation. OBJECTIVE: To investigate whether treatment with fluticasone propionate aqueous nasal spray (FP) can alter the inflammatory response in the nasal airways under these conditions. METHODS: Sixteen allergic, rhinitic patients were recruited for this double-blind, randomized, cross-over study and received either topical FP 200 microg once daily or matched placebo for 4 weeks. At the end of treatment, all underwent nasal lavage followed by a 6 h exposure to 400 p.p.b. NO2. Following exposure to NO2, nasal allergen challenge was performed and nasal lavage repeated. After a 4 week washout period, patients were given alternate treatment and tested as above. RESULTS: Analysis of eosinophil cationic protein (ECP) in lavage samples from patients treated with placebo, demonstrated that this was significantly increased from a median value of 2.3 ng/mL (range: 1.0-7.1) to 15.1 ng/mL (range: 1.5-40.0; P = 0.001) following exposure to NO2 and allergen challenge. However, in patients treated with FP, ECP concentrations only increased from 3.3 ng/mL (range: 0.2-9.2) to 5.1 ng/mL (range: 0.3-20.0; P = 0.034) following exposure to NO2 and allergen challenge. The difference of the changes in ECP concentration between the placebo and the FP-treated group was significant (P = 0.003). Similarly, there was a significant increase in the number of eosinophils in nasal lavage after exposure to NO2 and allergen challenge in the placebo group, and this increase was inhibited in FP group (P = 0.002). CONCLUSION: These results suggest that FP influences NO2- and allergen-induced changes in eosinophil function, as well as eosinophil number in the nasal airway of allergic rhinitics.     

The time course of the bilateral release of cytokines and mediators after unilateral nasal allergen challenge

BACKGROUND: Late phase reactions after allergen challenge can be understood as a correlate of the inflammatory reaction in allergic rhinitis. METHODS: To investigate which cytokines are involved in it and to dissect direct and indirect effects of nasal allergen challenge, we performed unilateral nasal allergen provocation with the disc method in 12 seasonal allergic volunteers. Symptom scores, nasal secretions and nasal airflow were quantified. In the secretions that were collected in the early phase and for 8 h after provocation, we measured histamine, and the cytokines interleukin (IL)-1beta, IL-8, IL-4, and the natural antagonist of IL-1beta, IL-1 receptor type 1 (IL-1Ra) using enzyme-linked immunosorbent (ELISA)-assays. Control challenges with diluent instead of allergen were performed in all subjects. RESULTS: We demonstrated a bilateral increase in nasal secretion weights in the early and late phase. Histamine was significantly increased in the early and late phase in nasal secretions from both nostrils. IL-1beta increased in the late phase only, where it was also found on the unchallenged, contralateral side. Its antagonist IL-1Ra was found in very high quantities (1000-fold higher than IL-1beta) but demonstrated only marginal changes after provocation. IL-8 was increased in both nostrils early and late after challenge, whereas IL-4 was significantly elevated in the late phase. CONCLUSIONS: We described the time course of mediator and cytokine release into nasal secretions after allergen challenge. We hypothesize that the observed indirect effects on the unchallenged, contralateral side can be at least partially attributed to neuronal reflexes.     

Antiallergic actions of high topical doses of terbutaline in human nasal airways

It is debatable whether β₂-receptor agonists produce antiallergic effects in human airways. This question has been addressed in the present study by examination of both mast-cell indices and the physiologic response to allergen challenge in human nasal airways. Twelve asymptomatic patients with seasonal allergic rhinitis were investigated outside the pollen season. Intranasal allergen provocation was carried out with diluent and three increasing doses of allergen. Topical terbutaline sulfate (1.0 mg) was given 5 min prior to each allergen challenge and nasal lavage was carried out 10 min after each challenge. The study design was double-blind, placebo-controlled, crossover, and randomized. The allergen challenge-induced mast-cell activation and the ensuing physiologic response of the airway tissue were investigated by measuring a mast-cell-derived mediator (tryptase) and plasma proteins (albumin and α₂ macroglobulin), respectively, in the lavage fluids. Allergen provocation produced dose-dependent increments of nasal symptoms and lavage fluid levels of tryptase, albumin and α₂-macroglobulin. Both nasal symptoms ( p ≤0.05) and lavage fluid levels of tryptase ( p ≤0.05), albumin ( p ≤0.05), and α₂-macroglobulin ( p ≤0.01) were reduced by pretreatment with topical terbutaline sulfate. We conclude that high doses of topical terbutaline may produce significant antiallergic effects in human airways by equally reducing both tryptase release and plasma exudation in the acute allergic reaction in human airways. Further studies are now warranted to determine whether microvascular antipermeability effects of (β₂-receptor stimulation contribute to the present observations.     

Optimisation of grass pollen nasal allergen challenge for assessment of clinical and immunological outcomes

Nasal allergen challenge can be used to assess the clinical and immunological aspects of rhinitis due to inhalant allergens. We aimed to develop a reproducible technique for grass pollen nasal allergen challenge and to study biomarkers within nasal secretions. 20 Grass pollen allergic individuals underwent nasal challenges with purified Timothy grass allergen. An initial dose-titration challenge was used to determine dose-response characteristics. Subsequently, volunteers underwent 3 further challenges using individualised threshold doses. Symptom scores, visual analogue scores, and peak nasal inspiratory flow (PNIF) were recorded at baseline and up to 6h after challenge. Nasal secretions were collected at each time point using synthetic filter papers or absorptive polyurethane sponges and analysed for IL-4, -5, -10, -13, IFN-γ, Tryptase and Eosinophil Cationic Protein (ECP). Challenges gave reproducible symptom scores and decreased PNIF. Tryptase levels in nasal fluid peaked at 5min after challenge and returned to baseline levels at 1h. ECP, IL-5, IL-13 and IL-4 levels were increased from 2-3h and showed progressive increases to 5-6h. Sponges proved the superior nasal fluid sampling technique. We have developed a reproducible nasal allergen challenge technique. This may be used as a surrogate clinical endpoint in trials assessing the efficacy of treatments for allergic rhinitis. Tryptase in local nasal secretions is a potential biomarker of the early phase response; ECP and the Th2 cytokines IL-5, -13 and -4 markers of late phase allergic responses. Our model allows correlation between clinical responses and local biomarkers following nasal allergen challenge.     

Nasal response to a single antigen challenge in patients with allergic rhinitis — inflammatory cell recruitment persists up to 48 hours

BACKGROUND: Allergen challenge in some patients with respiratory allergy is followed by an early and a late reaction. OBJECTIVE: To evaluate the duration of mediator release and inflammatory cell recruitment during the late antigen-induced nasal response. METHODS: Eight patients with seasonal allergic rhinitis due to grass pollen underwent local challenge with the relevant allergen, a non-relevant allergen (Parietaria judaica), and nebulized saline solution. Nasal lavages were performed at baseline and 6, 24, 48, 72 h after challenge. Eosinophil cationic protein (ECP), leukotriene C4 (LTC4), leukotriene B4 (LTB4) myeloperoxidase (MPO) and prostaglandin D2 (PGD2) levels were radioimmunoassayed and histamine concentration was measured by an automated fluorometric method. RESULTS: Nasal challenge with the relevant antigen induced a response 6 h after stimulation, which subsided within 24 h. Eosinophilia, observed in the nasal lavages collected from 6 to 24 h after this challenge, was accompanied by ECP release. Neutrophilia were found in the nasal lavages collected from 6 to 24 h after challenge. The increase in neutrophil number correlated with MPO levels and LTB4 concentrations, but not with the intensity of nasal obstruction. Antigen challenge also induced significant recruitment of mononuclear cells 48 h after provocation. The challenge significantly raised histamine, but not PGD2, levels in the nasal lavages collected 6 h after provocation. A trend towards an increase in LTC4 levels in the nasal lavages collected 6 h after specific antigen challenge was also found. Nasal challenge with a non-relevant allergen or with saline solution did not cause either inflammatory cell recruitment or mediator release. CONCLUSION: Nasal challenge with the relevant antigen can induce a late response characterized by local accumulation of eosinophils, neutrophils and mononuclear cells persisting for 48 h and accompanied by release of ECP, MPO, LTB4 and histamine. These results indicate that a single antigen challenge in patients with allergic rhinitis causes prolonged inflammatory alterations which may contribute to the development of airway hyperreactivity.     

Role of kinins in seasonal allergic rhinitis: icatibant, a bradykinin B2 receptor antagonist, abolishes the hyperresponsiveness and nasal eosinophilia induced by antigen

BACKGROUND: Icatibant, a bradykinin B(2) receptor antagonist, inhibits the reduction in nasal patency after challenge with house dust mite antigen in sensitive subjects and abolishes the nasal hyperresponsiveness induced by platelet-activating factor in nonatopic subjects. OBJECTIVE: We sought to investigate the effect of icatibant on the response to nasal antigen challenge in subjects with seasonal allergic rhinitis. METHODS: Patients allergic to grass pollen antigen (n = 9-13) were included in a double-blind, randomized-block, placebo-controlled, crossover study outside the pollen season. Subjects first received an intranasal spray of icatibant (200 microg per nostril) or a saline control. Subjects were then challenged with antigen or diluent (control), and their responses were monitored by using acoustic rhinometry. Six hours later, nasal lavage fluid was collected and quantified for inflammatory cells and various inflammatory mediators (kinin, eosinophil cationic protein, IL-5, and IL-8). At 24 hours, the response of the nasal airways to 200 microg of histamine was assessed, and a further nasal lavage was carried out. RESULTS: Antigen challenge caused a significant increase in nasal obstruction and albumin extravasation, which was not affected by icatibant. Nasal hyperresponsiveness to histamine was present 24 hours after antigen and was abolished by pretreatment with icatibant. Icatibant also reduced the antigen-induced increase in eosinophils, eosinophil cationic protein, kinin, and IL-8 in nasal lavage fluid. CONCLUSION: Pretreatment with icatibant does not affect the acute inflammatory response in seasonal allergic rhinitis. However, our results imply the involvement of kinins and the bradykinin B(2) receptor in the development of antigen-induced hyperresponsiveness and the associated eosinophilia in the human nasal airway.     

Immunoglobulins in nasal secretion with special reference to IgE. I. Methodological studies.

Different ways of collecting relatively large volumes of nasal secretion with as physiological a composition as possible were studied. Nasal secretion was collected by the so-called nasal spray washing method from 5 patients with allergic rhinitis due to pollen and 5 healthy persons during a pollen-free season. The collection was performed without any provocation and following nasal provocation with histamine or allergen solution. With the radioimmunosorbent test, in which the lower limit of measurement was 0.1 units/ml, IgE could be quantified in 52 of 60 analysed secretions. IgA, IgG and albumin were demonstrated in all secretions. In the allergic patients, following histamine and allergen provocation, a relative increase in the concentration of IgE and albumin and a significant decrease of the IgA/albumin ratio in nasal secretion was found. In the healthy subjects, such changes in the secretion were observed only after histamine provocation. Calculations also suggested some local production of IgE, but not at all of the same order of magnitude as of IgA.     

Allergen-induced hyperreactivity is not a feature of dermal immediate allergic reactions—in contrast to reactions of airways mucosa

Allergen challenges of airway mucosa are commonly followed by an increased sensitivity to rechallenge with allergen. In the lower airways this phenomenon has been associated with the late phase of allergic airway reactions, which in turn has been suggested as a link between anaphylaxis and continuous allergic airway disease. The aim of the present investigation was to explore further the phenomenon of allergen-induced hyperreactivity and to see whether it was possible to induce such a reaction in the skin. Twenty-six patients with seasonal allergic rhinitis due to birch and/or grass pollens were studied in the pollen-free winter months. Nine of these patients had previously demonstrated an increased reactivity following allergen challenge in the nose, and nine of the patients had cutaneous allergen-induced late-phase reactions to the allergen tested. Skin-prick tests were performed with pollen allergen, histamine, and a negative control. The areas of the weal-and-flare reactions were measured 15 min after the tests were set. Any late-phase reactions were recorded 6 hr after the skin challenge. The subjects were re-tested with allergen and histamine 24 hr after the initial prick test within the area of the corresponding weal from the previous day. In contrast to previous challenges of human airway mucosa. where the same time interval was used, we found no increased responsiveness to rechallenge as compared with the initial allergen challenge. This was true, even if only the subgroups with previously demonstrated nasal allergen-induced hyperreactivity. or cutaneous late-phase reaction were evaluated. It is. therefore, suggested that allergen-induced hyperreactivity as a feature of allergic airway mucosa may be related to changes in the epithelial barrier function.     

Relationship between nasal hyperreactivity, mediators and eosinophils in patients with perennial allergic rhinitis and controls

Background In perennial allergic rhinitis, patients are almost daily exposed to aeroallergens. This ongoing allergic reaction results in increased sensitivity to allergens and non-specific stimuli. It is generally known that inflammatory cells and mediators are involved in the pathogenesis of the allergic reaction. Objectives To study the relationship between nasal hyperreactivity and nasal inflammation during natural allergen exposure. Methods In 48 patients with perennial allergic rhinitis and in 11 volunteers a nasal brush, a nasal lavage and a histamine challenge were performed. Nasal inflammation was estimated by the number of eosinophils, levels of albumin, tryptase, prostaglandin D₂ (PGD₂), eosinophil cationic protein (ECP) and leukotriene C₄/D₄/E₄ (LTC₄/D₄/E₄). Results In contrast to PGD₂ and tryptase, eosinophils (1.9 vs 0%, P = 0.0023), LTC₄/ D₄/E₄ (17.51 vs 1.43pg/mL, P= 0.0001) and albumin (8.61 vs 2.37mg/mL, P= 0.0008) were significantly increased in rhinitis patients as compared with controls. Patients also showed increased responses to nasal histamine challenge assessed using a composite symptom score (21.5 vs 4 points, P=0.0001). The nasal response to histamine was weakly correlated with the total number of eosinophils in the cytospin (correlation coefficient r=0.38, P= 0.009). Conclusion Nasal hyperreactivity is correlated with the percentage of eosinophils in patients with perennial rhinitis. The patients' mediator profiles suggest that eosinophils are important in the ongoing allergic reaction and nasal hyperreactivity.     

Selective recruitment of eosinophils by substance P after repeated allergen exposure in allergic rhinitis

We have investigated the nasal response to substance P after pollen exposure in seasonal allergic rhinitic patients. Seven patients with strictly seasonal allergic rhinitis were studied during the pollen season, 24 h after nasal challenge with pollen. They received increasing doses of nebulized substance P (0 to 80 nmol) in each nostril. Responses were assessed by measurement of nasal airway resistance by posterior rhinomanometry and quantification of albumin, histamine, and inflammatory cells in the nasal lavage fluid. Nasal airway resistance increased in a dose-dependent manner after substance P challenge. Protein and albumin in nasal lavage fluids increased after administration of substance P: from 2.6 ± 0.3 to 6.8 ± 1.1 mg for protein (P≤0.01) and from 0.2 ± 0.1 to 3.1 ± 0.6 mg for albumin (P≤0.02). Expressed as a percentage of total protein, albumin increased from 10.5 ± 3.6% to 39.9 ± 3.5% (P≤0.02), suggesting occurrence of plasma leakage. No histamine release was observed after challenge with substance P. Total cell counts significantly increased from 11.4 ± 2.4 to 41.8 ± 17.3 × 10³ cells/ml after substance P (P≤0.05). Eosinophils were already numerous before substance P challenge (2.1 ± 0.7 × 10³ cells/ml), and the number of eosinophils markedly increased in all patients after substance P (for the whole group, 25.8 ± 13.3 cells/ml, P≤0.05). In contrast, the number of neutrophils only slightly increased in five patients, and changes did not reach significance for the group as a whole. Our results show that substance P induces nasal obstruction and albumin extrusion in allergic rhinitic patients after repeated pollen exposure. These vascular phenomena are associated with recruitment of eosinophils. Since substance P is known to be released after nasal allergen challenge, our data suggest a role for substance P in the chronic eosinophilic inflammation of the nasal mucosa observed in symptomatic allergic rhinitis.     

Immediate and late phase allergic cutaneous reactions are not inducers of unspecific or specific local hyperreactivity

The present study evaluates the possibility of allergen-induced unspecific and specific dermal hyperreactivity with special reference to the presence of late cutaneous reactions and allergen-induced nasal hyperreactivity. Twenty-six patients with strictly seasonal allergic rhinitis participated. All had a positive skin prick test for birch (Betula verrucosa) and/or timothy (Phleum pratense). Ten patients had previously displayed an allergen-induced nasal hyperreactivity and six patients a late cutaneous reaction. An initial skin prick test with a relevant pollen allergen was done in triplicate. The immediate skin reactions were recorded after 15 min and any late-phase reaction after 6 h. Twenty-four hours later the patients were retested. The same pollen allergen was sited in the first flare reaction from the previous day. A histamine prick test was sited in the weal as well as in the third reaction from day 1. A histamine control was also performed in a previously unaffected area. The allergen-induced weal reactions decreased significantly at rechallenge compared with the results from the previous day (P less than 0.05). The histamine tests resulted in similar skin reactions regardless of whether or not they were done on a previous allergen test site. This was true for both specific and unspecific reactions when the subgroups of patients with previously demonstrated allergen-induced nasal hyperreactivity or late-phase skin reactions were evaluated separately. These results indicate that allergen-induced hyperreactivity is not a general feature of allergic inflammation but is a phenomenon restricted to specific sites, such as the airway mucosa.     

Demonstration of mast-cell chemotactic activity in nasal lavage fluid: characterization of one chemotaxin as c-kit ligand, stem cell factor

Mast cells are known to accumulate in tissue during allergic inflammation. However, the chemotaxins responsible are undefined. Using a modified Boyden chamber and Ihe human mast-cell line HMC-1, we first identified mast-cell chemotactic activity in nasal lavage fluid collected before the pollen season after allergen provocation of allergic patients (N=29) (mean migratory response compared to medium control was 121%, range 85-198%). Mast-cell chemotactic activity was also detected in lavage fluid collected after allergen provocation at the end of a Swedish birch-pollen season from three different treatment groups: topical steroid treatment with budesonide; the topical antihistamine, levocabastine; and placebo. There was no significant difference in mast-cell chemotactic activity between nasal lavage fluid collected from the placebo group (mean = 102%), the budesonide-treated group (mean = 1l4%), or the levocabastine group (mean = 125%). Stem cell factor (SCF), a known mast-cell chemotaxin, was present in the nasal lavage fluids from all three groups, and correlated with the mast-cell chemotactic activity (r = 0.67, P < 0.0l). TTie mast-eell chemotactic activity was inhibited (range 5-tOO%) in some, but not all, nasal lavage fluids by a polyclonal antibody directed against SCF. This report describes the presence of mast-cell chemotactic activity in nasal lavage fluid during an allergic reaction. These findings show that SCF may play a pivotal role in the recruitment of mast cells in allergic rhinitis.     

Effect of intranasal fluticasone proprionate on the immediate and late allergic reaction and nasal hyperreactivity in patients with a house dust mite allergy

Background Patients with perennial allergic rhinitis develop nasal symptoms not only after allergen exposure, but generally also after non-specific stimuli. Objective To evaluate the effect of 2 week's treatment with fluticasone propionate aqueous nasal spray (FPANS) on the nasal clinical response, inflammatory mediators and nasal hyperreactivity. Methods Twenty-four rhinitis patients allergic to house dust mite (HDM). participated in a douhle-blind. placebo-controlled crossover study. After 2 week's treatment with placebo or 200 μg FPANS twice daily, patients were challenged with HDM extract. Symptoms were recorded and nasal lavages were collected for up to 9.5 h after challenge. Nasal hyperreaclivity was determined by histamine challenge 24 h later. Results Because of a carry-over effect for the immediate symptom score, for this variable only the data from the first treatment period were used. FPANS treatment resulted in a significant decrease of nasal symptoms with 70%. 69% and 63% after 100. 1000 and 10000 Biological Units (BU)/mL of HDM extract respectively. Active treatment resulted in a 76% decrease of the late-phase symptoms. FPANS treatment significantly reduced albumin influx after HDM 1000 BU/mL with 62% and tended to reduce tryptase release after HDM 1000 BU ml. (P 0.0629). During the late phase FPANS treatment reduced albumin influx with 67% and eosinophil cationic protein (ECP) release with 83%. No effect of FPANS was seen on histamine levels. FPANS significantly decreased histamine-induced symptom score with 34%, secretion with 32%, and sneezes with 41%. Conclusion FPANS significantly inhibits the immediate and late allergic response, and nasal hyperreactivity, probably by suppressing mast cells and eosinophils in the nasal mucosa.     

Tryptase in nasal lavage fluid after local allergen challenge: Relationship to histamine levels and TAME-esterase activity

The activation of mast cells is generally considered to be an important trigger mechanism in the immediate allergic response. This study focused on the determination of three markers of mast cell activation after an allergen challenge. Nasal allergen challenges were performed in 25 subjects with seasonal allergic rhinitis using three allergen doses increasing in 10-fold steps in a standardised nasal lavage model for the subsequent recovery of the markers of mast cell activation. The levels of histamine and tryptase in the nasal lavage fluid were determined using radioimmunoassays, while the TAME-esterase activity was determined using a radiochemical technique. The nasal symptoms obtained on challenge were assessed using a scoring technique. The allergen challenge resulted in significant increases in the levels of all three markers, tryptase, histamine and TAME-esterase. In the individual measurements after the challenges there was a highly significant correlation between the TAME-esterase levels and the tryptase levels (r = 0.71; P less than 0.001), while the generation of histamine and tryptase was not significantly correlated. When comparing the cumulative generation of the three markers, significant correlations were found between all three. Allergen challenges in six non-allergic controls using the same technique did not result in any increase in tryptase levels. The findings suggest that the determination of tryptase in nasal lavage fluid may be a valuable indicator of mast cell activation in the upper airways.     

Basophil and eosinophil accumulation and mast cell degranulation in the nasal mucosa of patients with hay fever after local allergen provocation

BACKGROUND: Basophils and mast cells have certain similarities and are believed to be important in upper and lower respiratory allergy. OBJECTIVE: We sought to apply immunohistology to investigate the distribution and numbers of mast cells and basophils in the nasal mucosa after allergen provocation. METHODS: Allergen challenge with grass pollen was performed in 9 patients with seasonal allergic rhinitis out of the hay fever season. Nasal biopsy specimens were taken before and approximately 1 hour, 24 hours, and 1 week after intranasal allergen provocation. We determined relative numbers and their phenotypic characteristics by using mAbs specific for tryptase, chymase, IgE, eosinophils (BMK-13), and a new mAb against basophils (BB1) by using immunohistochemistry in frozen sections. RESULTS: In the nasal mucosa at baseline, practically no basophils were found in the epithelium. A significant increase in numbers was found in the epithelium and lamina propria of the nasal mucosa in the early phase as early as 1 hour after allergen provocation. At 24 hours and 1 week after allergen provocation, a significant increase in basophil numbers was found in the lamina propria only. The proportion of mast cells staining for chymase in the lamina propria decreased from a median of 38% (range, 0%-82%) to 14% (range, 0%-78%) within 1 hour of allergen provocation. The proportion of mast cells staining for chymase increased from 1% (range, 0%-86%) at baseline to 21% (range, 3%-85%) within 1 hour of allergen provocation. One week after provocation, mast cells returned to baseline numbers. A definite tissue eosinophilia was observed after allergen provocation. CONCLUSION: Basophil numbers are increased in the epithelium and lamina propria of the nasal mucosa of subjects with rhinitis after allergen challenge, with influx already apparent at 1 hour. Moreover, changes in mast cell percentages and numbers were observed within 1 hour of allergen provocation.     

Comparison of the effects of terfenadine with fexofenadine on nasal provocation tests with allergen

BACKGROUND: Fexofenadine, the hydrochloride salt of terfenadine active metabolite, is a nonsedative, noncardiotoxic antihistamine derivative for the treatment of allergic rhinitis. OBJECTIVE: We sought to compare the effects of terfenadine and fexofenadine on nasal provocation tests with allergen. METHODS: A preliminary provocation test (screening phase) was performed in 25 patients with a history of seasonal allergic rhinitis to grass pollen to determine the combined nasal reaction threshold, which was defined as 2 of the 3 following criteria: (1) at least a 40% decrease in peak nasal inspiratory flow and/or a 30% decrease in minimal cross-sectional area as measured by acoustic rhinometry, nasal secretions of 0.5 g, and 5 to 10 sneezes per minute. Patients were then included into a double-blind, randomized, 2-way crossover study to receive terfenadine or fexofenadine 120 mg 2 hours before provocation. Rhinorrhea, sneezing, peak nasal flow, and minimal nasal cross-sectional area, as well as symptom scores for nasal congestion and itchiness, were recorded at each allergen concentration up to the reaction threshold. The whole study was performed out of allergy season. RESULTS: Fexofenadine was as potent as terfenadine in limiting pruritus and nasal congestion. Rhinorrhea and sneezing were better controlled by fexofenadine than by terfenadine. Overall, the allergen concentration necessary to reach the combined reaction threshold was increased after treatment with both drugs. Comparison between screening and each treatment phase indicated that the shift in allergen concentration to reach the reaction threshold was significantly greater after fexofenadine than after terfenadine (P =. 033). CONCLUSION: After oral administration, fexofenadine provided better protection than terfenadine against the immediate allergic reaction.     

Sinus CT scans and mediator release in nasal secretions after nasal challenge with cypress pollens

BACKGROUND: Involvement of paranasal sinuses has been suggested in allergic rhinitis but not clearly demonstrated. AIMS: To investigate the relationship between intermittent allergic rhinitis and computerized tomography (CT). METHODS: Twenty patients with intermittent rhinitis and sensitized to cypress pollens underwent unilateral nasal provocation tests (NPTs) using increasing concentrations of cypress pollens out of the pollen season. Sinus CT-scans were carried out just before a NPT and 24 h later. Nasal lavage was carried out just before a NPT, 30 min after a positive challenge and again 24 h later. Leucotriene C4/D4, intracellular adhesion molecule-1 and eosinophil cationic protein were measured in nasal secretions. RESULTS: Thirteen patients (65%) showed an alteration in their CT-scans after allergen challenge. Ten of them showed sinus changes controlateral to their allergenic provocation. Radiological changes mainly affected the osteomeatal complex and the ethmoid sinuses. Pre-existing abnormalities (13 of 20 cases) mainly concerned the maxillary sinuses. There was no correlation between CT-scan abnormalities and levels of mediators released in nasal secretions. CONCLUSIONS: We have shown that nasal allergen challenge can produce radiological changes in the paranasal sinuses. This mainly concerned the ethmoid sinuses.     

Increase of albumin, eosinophil cationic protein, histamine, leukotrienes and mast cell tryptase in nasal lavage fluid after challenge with inhalant allergen extract

Allergic rhinitis patients underwent nasal challenge with allergen extract. Before and up to 10 h after nasal provocation, nasal lavage was performed every hour. In about one-third of the patients a biphasic influx of albumin was observed: an initial increase of albumin within 30 min after provocation and a 2nd peak 6–8 h after provocation. Allergen-induced changes in histamine levels were less pronounced than those of albumin, but with some patients biphasic responses were also seen. Increased leukotriene formation mainly occurred within one hour after allergen provocation.From nasal washings of some patients, mast cell tryptase and eosinophil cationic protein (ECP) were estimated. Whereas tryptase was released within one hour after nasal provocation, significant ECP release started 3 h later.