In asthma, bronchoconstriction causes topographically heterogeneous airway narrowing, as measured by three-dimensional ventilation imaging. Computation modeling suggests that peripheral airway dysfunction is a potential determinant of acute airway narrowing measured by imaging. We hypothesized that the development of low-ventilation regions measured topographically by three-dimensional imaging after bronchoconstriction is predicted by peripheral airway function. Fourteen asthmatic subjects underwent ventilation single-photon-emission computed tomography/computed tomography scan imaging before and after methacholine challenge. One-liter breaths of Technegas were inhaled from functional residual capacity in upright posture before supine scanning. The lung regions with the lowest ventilation (Vent) were calculated using a thresholding method and expressed as a percentage of total ventilation (Vent). Multiple-breath nitrogen washout was used to measure diffusion-dependent and convection-dependent ventilation heterogeneity (Sacin and Scond, respectively) and lung clearance index (LCI), before and after challenge. Forced expiratory volume in 1 s (FEV) was 87.6 ± 15.8% predicted, and seven subjects had airway hyperresponsiveness. Ventat baseline was unrelated to spirometry or multiple-breath nitrogen washout indices. Methacholine challenge decreased FEVby 23 ± 5% of baseline while Ventincreased from 21.5 ± 2.3%Ventto 26.3 ± 6.7%Vent(= 0.03). The change in Ventwas predicted by baseline Sacin ( = 0.60,= 0.03) and by LCI ( = 0.70,= 0.006) but not by Scond ( = 0.30,= 0.30). The development of low-ventilation lung units in three-dimensional ventilation imaging is predicted by ventilation heterogeneity in diffusion-dependent airways. This relationship suggests that acinar ventilation heterogeneity in asthma may be of mechanistic importance in terms of bronchoconstriction and airway narrowing.Using ventilation SPECT/CT imaging in asthmatics, we show induced bronchoconstriction leads to the development of areas of low ventilation. Furthermore, the relative volume of the low-ventilation regions was predicted by ventilation heterogeneity in diffusion-dependent acinar airways. This suggests that the pattern of regional airway narrowing in asthma is determined by acinar airway function.
BT - J Appl Physiol (1985) C1 - https://www.ncbi.nlm.nih.gov/pubmed/28798203?dopt=Abstract DO - 10.1152/japplphysiol.00640.2016 IS - 5 J2 - J. Appl. Physiol. LA - eng N2 -In asthma, bronchoconstriction causes topographically heterogeneous airway narrowing, as measured by three-dimensional ventilation imaging. Computation modeling suggests that peripheral airway dysfunction is a potential determinant of acute airway narrowing measured by imaging. We hypothesized that the development of low-ventilation regions measured topographically by three-dimensional imaging after bronchoconstriction is predicted by peripheral airway function. Fourteen asthmatic subjects underwent ventilation single-photon-emission computed tomography/computed tomography scan imaging before and after methacholine challenge. One-liter breaths of Technegas were inhaled from functional residual capacity in upright posture before supine scanning. The lung regions with the lowest ventilation (Vent) were calculated using a thresholding method and expressed as a percentage of total ventilation (Vent). Multiple-breath nitrogen washout was used to measure diffusion-dependent and convection-dependent ventilation heterogeneity (Sacin and Scond, respectively) and lung clearance index (LCI), before and after challenge. Forced expiratory volume in 1 s (FEV) was 87.6 ± 15.8% predicted, and seven subjects had airway hyperresponsiveness. Ventat baseline was unrelated to spirometry or multiple-breath nitrogen washout indices. Methacholine challenge decreased FEVby 23 ± 5% of baseline while Ventincreased from 21.5 ± 2.3%Ventto 26.3 ± 6.7%Vent(= 0.03). The change in Ventwas predicted by baseline Sacin ( = 0.60,= 0.03) and by LCI ( = 0.70,= 0.006) but not by Scond ( = 0.30,= 0.30). The development of low-ventilation lung units in three-dimensional ventilation imaging is predicted by ventilation heterogeneity in diffusion-dependent airways. This relationship suggests that acinar ventilation heterogeneity in asthma may be of mechanistic importance in terms of bronchoconstriction and airway narrowing.Using ventilation SPECT/CT imaging in asthmatics, we show induced bronchoconstriction leads to the development of areas of low ventilation. Furthermore, the relative volume of the low-ventilation regions was predicted by ventilation heterogeneity in diffusion-dependent acinar airways. This suggests that the pattern of regional airway narrowing in asthma is determined by acinar airway function.
PY - 2017 SP - 1188 EP - 1194 T2 - J Appl Physiol (1985) TI - Peripheral ventilation heterogeneity determines the extent of bronchoconstriction in asthma. VL - 123 SN - 1522-1601 ER -