Usefulness of nasal provocation tests in occupational rhinitis.

OBJECTIVE: The aim of the study was to determine whether Nasal Provocation Tests (NPT) could help in the diagnosis of occupational rhinitis (OR). METHODS: Changes in nasal airway resistance (NAR), measured by posterior rhinomanometry during specific nasal challenge associated with per and post test clinical scores, were compared to a prior probability, based on the patient's history, determined by occupational physicians, in 41 hairdressers and 33 bakers referred for suspected OR. RESULTS: A DeltaNAR >or= 150% defined the positivity of the NPT. DeltaNAR demonstrated 50% sensitivity and a 86% specificity in hairdressers and a 95% sensitivity with 100 % specificity in bakers. DeltaNAR presented significant positive correlations with both per (p = 0.0003, r = 0.48) and post test clinical scores (p < 0.005, r = 0.39). The addition of clinical scores increased the sensitivity to 100% in hairdressers with 81% specificity. CONCLUSIONS: The NPT constitutes a safe procedure of nasal reactivity with good levels of sensitivity and specificity in both hairdressers and bakers when nasal resistance and clinical scores are taken into account.

Nasal wall compliance in vasomotor rhinitis.

Nasal compliance is a measure related to the blood volume in the nasal mucosa. The objective of this study was to better understand the vascular response in vasomotor rhinitis by measuring nasal cross-sectional area and nasal compliance before and after mucosal decongestion in 10 patients with vasomotor rhinitis compared with 10 healthy subjects. Nasal compliance was inferred by measuring nasal area by acoustic rhinometry at pressures ranging from atmospheric pressure to a negative pressure of -10 cmH2O. Mucosal decongestion was obtained with one puff per nostril of 0.05% oxymetazoline. At atmospheric pressure, nasal cross-sectional areas were similar in the vasomotor rhinitis group and the healthy subject group. Mucosal decongestion did not induce any decrease of nasal compliance in patients with vasomotor rhinitis in contrast with healthy subjects. Our results support the hypothesis, already proposed, of an autonomic dysfunction based on a paradoxical response of the nasal mucosa in vasomotor rhinitis. Moreover, the clearly different behavior between healthy subjects and vasomotor rhinitis subjects suggests that nasal compliance measurement may therefore represent a potential line of research to develop a diagnostic tool for vasomotor rhinitis, which remains a diagnosis of exclusion.

Alveolar nitric oxide and effect of deep inspiration during methacholine challenge.

STUDY OBJECTIVES: To assess whether the dual anatomic origin of exhaled nitric oxide (NO), namely alveolar and bronchial, could explain the link between exhaled NO and airway responsiveness, and could participate in the bronchodilatory effect of deep inspiration (DI) that may be evidenced during methacholine challenge. DESIGN AND SETTING: Prospective study in a laboratory performing pulmonary function tests of an academic hospital. PATIENTS AND INTERVENTIONS: Patients underwent multiple flow analysis of exhaled NO, allowing calculation of total maximum airway NO flux (J'awno) and NO concentration of expansible compartment (CAno), and received a cumulative methacholine dose of 2,000 microg. DI effect was assessed by continuous measurement of the resistance of respiratory system using the forced oscillation technique before and after DI. RESULTS: In a first phase involving 23 patients, a positive correlation between log values of J'awno and CAno was demonstrated with the degree of airway responsiveness (percentage of FEV(1) decrease). In a second phase involving 38 patients, only log CAno was correlated with responsiveness, and no significant relationship was demonstrated between J'awno or CAno and the effect of DI. Patients with smaller airways and/or distal airflow limitation exhibited a constrictive response to DI. CONCLUSION: Airway responsiveness is mainly associated with an increase in distal origin of NO output, and no relationship between exhaled NO and the effect of DI was evidenced.

Inspiratory flow in the nose: a model coupling flow and vasoerectile tissue distensibility.

We have developed a discrete multisegmental model describing the coupling between inspiratory flow and nasal wall distensibility. This model is composed of 14 individualized compliant elements, each with its own relationship between cross-sectional area and transmural pressure. Conceptually, this model is based on flow limitation induced by the narrowing of duct due to collapsing pressure. For a given inspiratory pressure and for a given compliance distribution, this model predicts the area profile and inspiratory flow. Acoustic rhinometry and posterior rhinomanometry were used to determine the initial geometric area and mechanical characteristics of each element. The proposed model, used under steady-state conditions, is able to simulate the pressure-flow relationship observed in vivo under normal conditions (4 subjects) and under pathological conditions (4 vasomotor rhinitis and 3 valve syndrome subjects). Our results suggest that nasal wall compliance is an essential parameter to understand the nasal inspiratory flow limitation phenomenon and the associated increase of resistance that is well known to physiologists. By predicting the functional pressure-flow relationship, this model could be a useful tool for the clinician to evaluate the potential effects of treatments.