Carlo Gulotta

Mechanical effects of obesity on airway responsiveness in otherwise healthy humans.

We investigated whether obesity is associated with airway hyperresponsiveness in otherwise healthy humans and, if so, whether this correlates with a restrictive lung function pattern or a decreased number of sighs at rest and/or during walking. Lung function was studied before and after inhaling methacholine (MCh) in 41 healthy subjects with body mass index ranging from 20 to 56. Breathing pattern was assessed during a 60-min rest period and a 30-min walk. The dose of MCh that produced a 50% decrease in the maximum expiratory flow measured in a body plethysmograph (PD50MCh) was inversely correlated with body mass index (r2=0.32, P<0.001) and waist circumference (r2=0.25, P<0.001). Significant correlations with body mass index were also found with the maximum changes in respiratory resistance (r2=0.19, P<0.001) and reactance (r2=0.40, P<0.001) measured at 5 Hz. PD50MCh was also positively correlated with functional residual capacity (r2=0.56, P<0.001) and total lung capacity (r2=0.59, P<0.001) in men, but not in women. Neither PD50MCh nor body mass index correlated with number of sighs, average tidal volume, ventilation, or breathing frequency. In this study, airway hyperresponsiveness was significantly associated with obesity in otherwise healthy subjects. In obese men, but not in women, airway hyperresponsiveness was associated with the decreases in lung volumes.

Role of Alveolar β2-Adrenergic Receptors on Lung Fluid Clearance and Exercise Ventilation in Healthy Humans

Background In experimental conditions alveolar fluid clearance is controlled by alveolar β2-adrenergic receptors. We hypothesized that if this occurs in humans, then non-selective β-blockers should reduce the membrane diffusing capacity (DM), an index of lung interstitial fluid homeostasis. Moreover, we wondered whether this effect is potentiated by saline solution infusion, an intervention expected to cause interstitial lung edema. Since fluid retention within the lungs might trigger excessive ventilation during exercise, we also hypothesized that after the β2-blockade ventilation increased in excess to CO2 output and this was further enhanced by interstitial edema. Methods and Results 22 healthy males took part in the study. On day 1, spirometry, lung diffusion for carbon monoxide (DLCO) including its subcomponents DM and capillary volume (VCap), and cardiopulmonary exercise test were performed. On day 2, these tests were repeated after rapid 25 ml/kg saline infusion. Then, in random order 11 subjects were assigned to oral treatment with Carvedilol (CARV) and 11 to Bisoprolol (BISOPR). When heart rate fell at least by 10 beats·min−1, the tests were repeated before (day 3) and after saline infusion (day 4). CARV but not BISOPR, decreased DM (−13±7%, p = 0.001) and increased VCap (+20±22%, p = 0.016) and VE/VCO2 slope (+12±8%, p<0.01). These changes further increased after saline: −18±13% for DM (p<0.01), +44±28% for VCap (p<0.001), and +20±10% for VE/VCO2 slope (p<0.001). Conclusions These findings support the hypothesis that in humans in vivo the β2-alveolar receptors contribute to control alveolar fluid clearance and that interstitial lung fluid may trigger exercise hyperventilation.

Airway distensibility and volume recruitment with lung inflation in COPD

The effects of full lung inflation on respiratory conductance (Grs) and reactance (Xrs) were measured in 15 subjects with moderate to severe chronic obstructive pulmonary disease (COPD) and 11 matched healthy control subjects. Airway distensibility was estimated from the ratio of the difference of Grs between functional residual capacity and total lung capacity to the relevant changes in lung volume (ΔGrs/ΔVl) or transpulmonary pressure (ΔGrs/ΔPtp). Similar analysis was applied to Xrs to estimate lung volume recruitment (ΔXrs/ΔVl or ΔXrs/ΔPtp). The extent of emphysema in COPD subjects was estimated from the percentage of low attenuation area (LAA) at high-resolution computed tomography. At baseline, ΔGrs/ΔVl and ΔXrs/ΔVl were significantly less in COPD than control subjects, indicating less distensibility and volume recruitment in the former. In COPD, ΔGrs/ΔPtp and ΔXrs/ΔPtp were uncorrelated with LAA but correlated with 1-s forced expiratory volume and with each other. After albuterol, both ΔGrs/ΔPtp and ΔGrs/ΔVl became significantly and negatively correlated with LAA, while ΔXrs/ΔPtp and ΔXrs/ΔVl decreased significantly independently of LAA. Moreover, ΔGrs/ΔPtp and ΔXrs/ΔPtp with lung inflation were no longer correlated with each other, suggesting that airway distensibility and volume recruitment were affected differently by airway smooth muscle tone. Assuming that Grs mainly reflects airway caliber and Xrs the number of ventilated lung units, we conclude that airway smooth muscle contributes to airway stiffness and ventilation inhomogeneities in COPD subjects with prevailing bronchitis but only to the latter in those with more emphysema. We suggest that changes of airway distensibility and volume recruitment with a bronchodilator may be useful for disease phenotyping.

Ventilation heterogeneity in obesity

Obesity is associated with important decrements in lung volumes. Despite this, ventilation remains normally or near normally distributed at least for moderate decrements in functional residual capacity (FRC). We tested the hypothesis that this is because maximum flow increases presumably as a result of an increased lung elastic recoil. Forced expiratory flows corrected for thoracic gas compression volume, lung volumes, and forced oscillation technique at 5-11-19 Hz were measured in 133 healthy subjects with a body mass index (BMI) ranging from 18 to 50 kg/m(2). Short-term temporal variability of ventilation heterogeneity was estimated from the interquartile range of the frequency distribution of the difference in inspiratory resistance between 5 and 19 Hz (R5-19_IQR). FRC % predicted negatively correlated with BMI (r = -0.72, P < 0.001) and with an increase in slope of either maximal (r = -0.34, P < 0.01) or partial flow-volume curves (r = -0.30, P < 0.01). Together with a slight decrease in residual volume, this suggests an increased lung elastic recoil. Regression analysis of R5-19_IQR against FRC % predicted and expiratory reserve volume (ERV) yielded significantly higher correlation coefficients by nonlinear than linear fitting models (r(2) = 0.40 vs. 0.30 for FRC % predicted and r(2) = 0.28 vs. 0.19 for ERV). In conclusion, temporal variability of ventilation heterogeneities increases in obesity only when FRC falls approximately below 65% of predicted or ERV below 0.6 liters. Above these thresholds distribution is quite well preserved presumably as a result of an increase in lung recoil.

Short-term variability in respiratory impedance and effect of deep breath in asthmatic and healthy subjects with airway smooth muscle activation and unloading

Inspiratory resistance (RINSP) and reactance (XINSP) were measured for 7 min at 5 Hz in 10 subjects with mild asymptomatic asthma and 9 healthy subjects to assess the effects of airway smooth muscle (ASM) activation by methacholine (MCh) and unloading by chest wall strapping (CWS) on the variability of lung function and the effects of deep inspiration (DI). Subjects were studied at control conditions, after MCh, with CWS, and after MCh with CWS. In all experimental conditions XINSP was significantly more negative in subjects with asthma than in healthy subjects, suggesting greater inhomogeneity in the former. However, the variability in both RINSP and XINSP was increased by either ASM activation or CWS, without significant difference between groups. DI significantly reversed MCh-induced changes in RINSP both in subjects with asthma and healthy subjects, but XINSP in the former only. This effect was impaired by CWS more in subjects with asthma than in healthy subjects. The velocity of RINSP and XINSP recovery after DI was faster in subjects with asthma than healthy subjects. In conclusion, these results support the opinion that the short-term variability in respiratory impedance is related to ASM tone or operating length, rather than to the disease. Nevertheless, ASM in individuals with asthma differs from that in healthy individuals in an increased velocity of shortening and a reduced sensitivity to mechanical stress when strain is reduced.

Severity grading of chronic obstructive pulmonary disease: the confounding effect of phenotype and thoracic gas compression

Current guidelines recommend severity of chronic obstructive pulmonary disease be graded by using forced expiratory volume in 1 s (FEV1). But this measurement is biased by thoracic gas compression depending on lung volume and airflow resistance. The aim of this study was to test the hypothesis that the effect of thoracic gas compression on FEV1 is greater in emphysema than chronic bronchitis because of larger lung volumes, and this influences severity classification and prognosis. FEV1 was simultaneously measured by spirometry and body plethysmography (FEV1-pl) in 47 subjects with dominant emphysema and 51 with dominant chronic bronchitis. Subjects with dominant emphysema had larger lung volumes, lower diffusion capacity, and lower FEV1 than those with dominant chronic bronchitis. However, FEV1-pl, patient-centered variables (dyspnea, quality of life, exercise tolerance, exacerbation frequency), arterial blood gases, and respiratory impedance were not significantly different between groups. Using FEV1-pl instead of FEV1 shifted severity distribution toward less severe classes in dominant emphysema more than chronic bronchitis. The body mass, obstruction, dyspnea, and exercise (BODE) index was significantly higher in dominant emphysema than chronic bronchitis, but this difference significantly decreased when FEV1-pl was substituted for FEV1. In conclusion, the FEV1 is biased by thoracic gas compression more in subjects with dominant emphysema than in those with chronic bronchitis. This variably and significantly affects the severity grading systems currently recommended.

Contribution of β-adrenergic receptors to exercise-induced bronchodilatation in healthy humans

Exercise in healthy subjects is usually associated with progressive bronchodilatation. Though the decrease in vagal tone is deemed to be the main underlying mechanism, activation of bronchial β(2)-receptors may constitute an additional cause. To examine the contribution of β(2)-adrenergic receptors to bronchodilatation during exercise in healthy humans, we studied 15 healthy male volunteers during maximum exercise test at control conditions and after a non-selective β-adrenergic blocker (carvedilol 12.5mg twice a day until heart rate decreased at least by 10beats/min) and inhaled β(2)-agonist (albuterol 400μg). Airway caliber was estimated from the partial flow at 40% of control forced vital capacity (V˙(part40)) and its changes during exercise from the slope of linear regression analysis of V˙(part40) values against the corresponding minute ventilation during maximal exercise until exhaustion. At control, V˙(part40) increased progressively and significantly with exercise. After albuterol, resting V˙(part40) was significantly larger than at control increased but did not further increase during exercise. After carvedilol, V˙(part40) was similar to control but its increase with exercise was significantly attenuated. These findings suggest that β(2)-adrenergic system plays a major role in exercise-induced bronchodilation in healthy subjects.

Rationale for the Turin Conference/Congress 2012

In 1987 the first International Conference on the Management of Chronic Respiratory Failure was held in Veruno (Italy). Twenty five years and six Conferences later much has changed, not only in regard to the organization of the Conference itself (e.g., now it is held every three years instead of five as originally), but also the problems arising from chronic respiratory diseases (CRDs) have changed. Today, according to World Health Organisation’s (WHO) estimates, some 300 million people worldwide suffer from asthma and 80 million people are affected by moderate to severe COPD. These diseases are among the most important causes of death in our society and their burden is constantly increasing. Over the last 20 years effective technical and pharmacological aids have been added to the tool-box of the chest physician, improving the life of patients both in terms of expectancy and quality. Obviously, this development of chest medicine has also had important repercussions on health resources consumption and currently there is a widespread debate on how to cope with the growing burden. The International Conference on “Management and Rehabilitation of Chronic Respiratory Failure” - now in its 7th edition - is recognized as a key international scientific event in this specific field. The 2012 “Pulmonary Advances”, which will be held in Turin, will deal with new developments in respiratory medicine as well as with their cost-effectiveness and the best way to deliver them, with particular focus on the possibilities of integration between specialists and primary care medicine. Two major scientific events will run in parallel: the 7th International Conference and the 3rd National Congress of AIMAR (Interdisciplinary Scientific Association for Research in Lung Disease). The novel idea underpinning AIMAR is that management of respiratory diseases should not be solely in the hands of the pneumologists but should be multidisciplinary. This approach goes beyond the purely ‘organ specialist’ outlook prevalent in clinical practice, integrating the diverse professional figures (including non-medical health professionals) to promote, through continuing professional education, the development of joint clinical controlled studies, epidemiological surveillance and public health education in order to lay the foundations for an optimal management of respiratory diseases. The Conference/Congress of Turin 2012 will thus have a clear interdisciplinary character, offering the maximum in terms of quality, up-to-date information in the fight against and prevention of CRDs. This is in harmony with the scope of GARD (Global Alliance against Chronic Respiratory Diseases), a WHO-based voluntary alliance of national and international organizations aimed at improving the respiratory health of the general population by fighting the current problem of underdiagnosis and undertreatment of CRDs. The benefit of this is very evident to professionals, health planners and decision makers, but what benefit is there for the patient and general public? There is nothing but to gain from a greater flow of information between the various specialists and a more integrated mode of clinical practice. Patient management will no longer be - as it is often today - the fruit of improvised collaboration, but it will be based on a global, comprehensive model of care that coordinates the up-to-date expertise of diverse specialists. Moreover, assuring patients a homogeneous protocol of diagnosis and treatment irrespective of what specialist branch they consult for a respiratory problem will give them the added security of knowing they are cared for by professionals who have a united vision of their case. In short, AIMAR represents a great alliance between physicians, health professionals and patients for the lungs, which means a great alliance for the benefit of all citizens. Our wish is that the commitment manifested by the Scientific Committees and Organizing Committee - in their respective areas of competence - combined with the work of the almost 200 speakers and a fruitful exchange of opinions among participants will enable us to realize that particular “mix” that will make this a unique scientific event.

Dependence of bronchoconstrictor and bronchodilator responses on thoracic gas compression volume

During forced expiration, alveolar pressure (PALV) increases and intrathoracic gas is compressed. Thus, 1‐s forced expiratory volume measured by spirometry (FEV1‐sp) is smaller than 1‐s forced expiratory volume measured by plethysmography (FEV1‐pl). Thoracic gas compression volume (TGCV) depends on the amount of gas within the lung when expiratory flow limitation occurs in the airways. We therefore tested the hypothesis that bronchoconstrictor and bronchodilator responses using FEV1‐sp are biased by height and gender, which are major determinants of lung volume.

Mechanical correlates of dyspnea in bronchial asthma

We hypothesized that dyspnea and its descriptors, that is, chest tightness, inspiratory effort, unrewarded inspiration, and expiratory difficulty in asthma reflect different mechanisms of airflow obstruction and their perception varies with the severity of bronchoconstriction. Eighty‐three asthmatics were studied before and after inhalation of methacholine doses decreasing the 1‐sec forced expiratory volume by ~15% (mild bronchoconstriction) and ~25% (moderate bronchoconstriction). Symptoms were examined as a function of changes in lung mechanics. Dyspnea increased with the severity of obstruction, mostly because of inspiratory effort and chest tightness. At mild bronchoconstriction, multivariate analysis showed that dyspnea was related to the increase in inspiratory resistance at 5 Hz (R5) (r2 = 0.10, P = 0.004), chest tightness to the decrease in maximal flow at 40% of control forced vital capacity, and the increase in R5 at full lung inflation (r2 = 0.15, P = 0.006), inspiratory effort to the temporal variability in R5‐19 (r2 = 0.13, P = 0.003), and unrewarded inspiration to the recovery of R5 after deep breath (r2 = 0.07, P = 0.01). At moderate bronchoconstriction, multivariate analysis showed that dyspnea and inspiratory effort were related to the increase in temporal variability in inspiratory reactance at 5 Hz (X5) (r2 = 0.12, P = 0.04 and r2 = 0.18, P < 0.001, respectively), and unrewarded inspiration to the decrease in X5 at maximum lung inflation (r2 = 0.07, P = 0.04). We conclude that symptom perception is partly explained by indexes of airway narrowing and loss of bronchodilatation with deep breath at low levels of bronchoconstriction, but by markers of ventilation heterogeneity and lung volume recruitment when bronchoconstriction becomes more severe.