Pilot evaluation of the nasal nitric oxide response to humming as an index of osteomeatal patency.

BACKGROUND: Paranasal sinuses are reservoirs for nitric oxide (NO), and humming facilitates nasal diffusion of NO. The nasal NO response to humming has previously been shown to be blunted with chronic sinusitis and nasal polyposis. We hypothesized that the nasal NO response to humming will be proportional to radiographic osteomeatal patency when comparing allergic rhinitis (AR) patients (without chronic sinusitis) with normal controls. METHODS: Nonsmoking subjects completed questionnaires and skin-prick testing. Subjects underwent sinus CT scanning, followed by exhaled (oral) and nasal NO sampling (with and without humming). Humming-to-quiet (H/Q) nasal NO ratios were calculated. Three-dimensional reconstructions were used to trace the osteomeatal complex (OMC) and measure minimum cross-sectional area. Lund-Mackay scores were also documented. RESULTS: A total of 33 subjects (22 women; mean age, 35.5 years) completed the study. Seventeen AR patients (5 IAR and 12 PAR) participated, as did 16 nonallergic controls. Among controls, quiet nasal NO levels--corrected for fractional exhaled NO--rose significantly with OMC area and fell significantly with Lund-Mackay scores (p < 0.05). However, we observed no proportionality between H/Q ratio and radiographic OMC patency. CONCLUSION: Analysis of nasal NO samples taken under quiet conditions from normal controls was consistent with the paranasal sinuses acting as a reservoir of nasal NO and with OMC patency acting as a significant factor in NO diffusion. However, our results did not support a relationship between the nasal NO response to humming and radiographic OMC patency in a sample excluding subjects with severe rhinosinusitis.

Hyperplasia of smooth muscle in mild to moderate asthma without changes in cell size or gene expression.

Bronchial hyperresponsiveness in mild to moderate asthma may result from airway smooth muscle cell proliferation or acquisition of a hypercontractile phenotype. Because these cells have not been well characterized in mild to moderate asthma, we examined the morphometric and gene expression characteristics of smooth muscle cells in this subgroup of patients with asthma. Using bronchial biopsies from 14 subjects with mild to moderate asthma and 15 control subjects, we quantified smooth muscle cell morphology by stereology and the expression of a panel of genes related to a hypercontractile phenotype of airway smooth muscle, using laser microdissection and two-step real-time polymerase chain reaction. We found that airway smooth muscle cell size was similar in both groups, but cell number was nearly twofold higher in subjects with asthma (p = 0.03), and the amount of smooth muscle in the submucosa was increased 50-83% (p < 0.005). Gene expression profiling in smooth muscle cells showed no difference in the expression of genes encoding phenotypic markers in cells from healthy subjects and subjects with asthma (all p > 0.1). We conclude that airway smooth muscle proliferation is a pathologic characteristic of subjects with mild to moderate asthma. However, smooth muscle cells in mild to moderate asthma do not show hypertrophy or gene expression changes of a hypercontractile phenotype observed in vitro.