scholarly journals Nonlinearity of respiratory mechanics during bronchoconstriction in mice with airway inflammation

2002 ◽  
Vol 92 (5) ◽  
pp. 1802-1807 ◽  
Author(s):  
Scott Wagers ◽  
Lennart Lundblad ◽  
Henrique T. Moriya ◽  
Jason H. T. Bates ◽  
Charles G. Irvin
Keyword(s):  
Respiratory System ◽  
Lung Volume ◽  
Respiratory Mechanics ◽  
Equation Of Motion ◽  
Model Fit ◽  
Airway Closure ◽  
Lung Volumes ◽  
Mechanically Ventilated ◽  
Respiratory System Resistance ◽  
The Impact

Respiratory system resistance (R) and elastance (E) are commonly estimated by fitting the linear equation of motion P = EV + RV˙ + P0 ( Eq. 1 ) to measurements of respiratory pressure (P), lung volume (V), and flow (V˙). However, the respiratory system is unlikely to behave linearly under many circumstances. We determined the importance of respiratory system nonlinearities in two groups of mechanically ventilated Balb/c mice [controls and mice with allergically inflamed airways (ova/ova)], by assessing the impact of the addition of nonlinear terms (E2V2 and R2V˙‖V˙‖) on the goodness of model fit seen with Eq. 1 . Significant improvement in fit (51.85 ± 4.19%) was only seen in the ova/ova mice during bronchoconstriction when the E2V2alone was added. An improvement was also observed with addition of the E2V2 term in mice with both low and high lung volumes ventilated at baseline, suggesting a volume-dependent nonlinearity of E. We speculate that airway closure in the constricted ova/ova mice accentuated the volume-dependent nonlinearity by decreasing lung volume and overdistending the remaining lung.

Respiratory system reactance is an independent determinant of asthma control

2013 ◽  
Vol 115 (9) ◽  
pp. 1360-1369 ◽  
Author(s):  
Vanessa J. Kelly ◽  
Scott A. Sands ◽  
R. Scott Harris ◽  
Jose G. Venegas ◽  
Nathan J. Brown ◽  
...  
Keyword(s):  
Asthma Control ◽  
Respiratory System ◽  
Lung Volume ◽  
Strong Predictor ◽  
Closing Volume ◽  
Forced Oscillation Technique ◽  
Airway Closure ◽  
Lung Volumes ◽  
Ventilation Heterogeneity ◽  
Peripheral Airway

The mechanisms underlying not well-controlled (NWC) asthma remain poorly understood, but accumulating evidence points to peripheral airway dysfunction as a key contributor. The present study tests whether our recently described respiratory system reactance (Xrs) assessment of peripheral airway dysfunction reveals insight into poor asthma control. The aim of this study was to investigate the contribution of Xrs to asthma control. In 22 subjects with asthma, we measured Xrs (forced oscillation technique), spirometry, lung volumes, and ventilation heterogeneity (inert-gas washout), before and after bronchodilator administration. The relationship between Xrs and lung volume during a deflation maneuver yielded two parameters: the volume at which Xrs abruptly decreased (closing volume) and Xrs at this volume (Xrscrit). Lowered (more negative) Xrscrit reflects reduced apparent lung compliance at high lung volumes due, for example, to heterogeneous airway narrowing and unresolved airway closure or near closure above the critical lung volume. Asthma control was assessed via the 6-point Asthma Control Questionnaire (ACQ6). NWC asthma was defined as ACQ6 > 1.0. In 10 NWC and 12 well-controlled subjects, ACQ6 was strongly associated with postbronchodilator (post-BD) Xrscrit ( R2 = 0.43, P < 0.001), independent of all measured variables, and was a strong predictor of NWC asthma (receiver operator characteristic area = 0.94, P < 0.001). By contrast, Xrs measures at lower lung volumes were not associated with ACQ6. Xrscrit itself was significantly associated with measures of gas trapping and ventilation heterogeneity, thus confirming the link between Xrs and airway closure and heterogeneity. Residual airway dysfunction at high lung volumes assessed via Xrscrit is an independent contributor to asthma control.

scholarly journals High-frequency oscillatory ventilation in neonatal RDS: initial volume optimization and respiratory mechanics

1998 ◽  
Vol 84 (4) ◽  
pp. 1174-1177 ◽  
Author(s):  
Masendu Kalenga ◽  
Oreste Battisti ◽  
Anne François ◽  
Jean-Paul Langhendries ◽  
Dale R. Gerstmann ◽  
...  
Keyword(s):  
Respiratory System ◽  
Lung Volume ◽  
High Frequency ◽  
Distress Syndrome ◽  
Respiratory Mechanics ◽  
High Frequency Oscillatory Ventilation ◽  
Oscillatory Ventilation ◽  
Respiratory System Resistance ◽  
High Frequency Oscillatory ◽  
Good Oxygenation

To determine whether initial lung volume optimization influences respiratory mechanics, which could indicate the achievement of optimal volume, we studied 17 premature infants with respiratory distress syndrome (RDS) assisted by high-frequency oscillatory ventilation. The continuous distending pressure (CDP) was increased stepwise from 6–8 cmH2O up to optimal CDP (OCDP), i.e., that allowing good oxygenation with the lowest inspired O2 fraction. Respiratory system compliance (Crs) and resistance were concomitantly measured. Mean OCDP was 16.5 ± 1.2 cmH2O. Inspired O2 fraction could be reduced from an initial level of 0.73 ± 0.17 to 0.33 ± 0.07. However, Crs (0.45 ± 0.14 ml ⋅ cmH2O−1 ⋅ kg−1at starting CDP point) remained unchanged through lung volume optimization but appeared inversely related to OCDP. Similarly, respiratory system resistance was not affected. We conclude that there is a marked dissociation between oxygenation improvement and Crs profile during the initial phase of lung recruitment by early high-frequency oscillatory ventilation in infants with RDS. Thus optimal lung volume cannot be defined by serial Crs measurement. At the most, low initial Crs suggests that higher CDP will be needed.

scholarly journals Effect of Bronchoscopic Lung Volume Reduction in Advanced Emphysema on Energy Balance Regulation

Respiration ◽  
2021 ◽  
pp. 1-8
Author(s):  
Karin Sanders ◽  
Karin Klooster ◽  
Lowie E.G.W. Vanfleteren ◽  
Guy Plasqui ◽  
Anne-Marie Dingemans ◽  
...  
Keyword(s):  
Energy Balance ◽  
Lung Volume ◽  
Respiratory Mechanics ◽  
Volume Reduction ◽  
Fat Free Mass ◽  
Whole Body ◽  
Energy Requirements ◽  
Lung Volume Reduction ◽  
Clinical Trial Registry ◽  
The Impact

<b><i>Background:</i></b> Hypermetabolism and muscle wasting frequently occur in patients with severe emphysema. Improving respiratory mechanics by bronchoscopic lung volume reduction (BLVR) might contribute to muscle maintenance by decreasing energy requirements and alleviating eating-related dyspnoea. <b><i>Objective:</i></b> The goal was to assess the impact of BLVR on energy balance regulation. <b><i>Design:</i></b> Twenty emphysematous subjects participated in a controlled clinical experiment before and 6 months after BLVR. Energy requirements were assessed: basal metabolic rate (BMR) by ventilated hood, total daily energy expenditure (TDEE) by doubly labelled water, whole body fat-free mass (FFM) by deuterium dilution, and physical activity by accelerometry. Oxygen saturation, breathing rate, and heart rate were monitored before, during, and after a standardized meal via pulse oximetry and dyspnoea was rated. <b><i>Results:</i></b> Sixteen patients completed follow-up, and among those, 10 patients exceeded the minimal clinically important difference of residual volume (RV) reduction. RV was reduced with median (range) 1,285 mL (−2,430, −540). Before BLVR, 90% of patients was FFM-depleted despite a normal BMI (24.3 ± 4.3 kg/m<sup>2</sup>). BMR was elevated by 130%. TDEE/BMR was 1.4 ± 0.2 despite a very low median (range) daily step count of 2,188 (739, 7,110). Following BLVR, the components of energy metabolism did not change significantly after intervention compared to before intervention, but BLVR treatment decreased meal-related dyspnoea (4.1 vs. 1.7, <i>p</i> = 0.019). <b><i>Conclusions:</i></b> Impaired respiratory mechanics in hyperinflated emphysematous patients did not explain hypermetabolism. <b><i>Clinical Trial Registry Number:</i></b> NCT02500004 at www.clinicaltrial.gov.

scholarly journals Obesity alters the topographical distribution of ventilation and the regional response to bronchoconstriction

2020 ◽  
Vol 128 (1) ◽  
pp. 168-177 ◽  
Author(s):  
S. Rutting ◽  
S. Mahadev ◽  
K. O. Tonga ◽  
D. L. Bailey ◽  
J. R. Dame Carroll ◽  
...  
Keyword(s):  
Computed Tomography ◽  
Body Mass Index ◽  
Body Mass ◽  
Respiratory System ◽  
Healthy Subjects ◽  
Airway Closure ◽  
Ventilation Distribution ◽  
Lung Volumes ◽  
Topographical Distribution ◽  
Lung Zone

Obesity is associated with reduced operating lung volumes that may contribute to increased airway closure during tidal breathing and abnormalities in ventilation distribution. We investigated the effect of obesity on the topographical distribution of ventilation before and after methacholine-induced bronchoconstriction using single-photon emission computed tomography (SPECT)-computed tomography (CT) in healthy subjects. Subjects with obesity ( n = 9) and subjects without obesity ( n = 10) underwent baseline and postbronchoprovocation SPECT-CT imaging, in which Technegas was inhaled upright and followed by supine scanning. Lung regions that were nonventilated (Ventnon), low ventilated (Ventlow), or well ventilated (Ventwell) were calculated using an adaptive threshold method and were expressed as a percentage of total lung volume. To determine regional ventilation, lungs were divided into upper, middle, and lower thirds of axial length, derived from CT. At baseline, Ventnon and Ventlow for the entire lung were similar in subjects with and without obesity. However, in the upper lung zone, Ventnon (17.5 ± 10.6% vs. 34.7 ± 7.8%, P < 0.001) and Ventlow (25.7 ± 6.3% vs. 33.6 ± 5.1%, P < 0.05) were decreased in subjects with obesity, with a consequent increase in Ventwell (56.8 ± 9.2% vs. 31.7 ± 10.1%, P < 0.001). The greater diversion of ventilation to the upper zone was correlated with body mass index ( rs = 0.74, P < 0.001), respiratory system resistance ( rs = 0.72, P < 0.001), and respiratory system reactance ( rs = −0.64, P = 0.003) but not with lung volumes or basal airway closure. Following bronchoprovocation, overall Ventnon increased similarly in both groups; however, in subjects without obesity, Ventnon only increased in the lower zone, whereas in subjects with obesity, Ventnon increased more evenly across all lung zones. In conclusion, obesity is associated with altered ventilation distribution during baseline and following bronchoprovocation, independent of reduced lung volumes. NEW & NOTEWORTHY Using ventilation SPECT-computed tomography imaging in healthy subjects, we demonstrate that ventilation in obesity is diverted to the upper lung zone and that this is strongly correlated with body mass index but is independent of operating lung volumes and of airway closure. Furthermore, methacholine-induced bronchoconstriction only occurred in the lower lung zone in individuals who were not obese, whereas in subjects who were obese, it occurred more evenly across all lung zones. These findings show that obesity-associated factors alter the topographical distribution of ventilation.

scholarly journals Airway Closure during Surgical Pneumoperitoneum in Obese Patients

2019 ◽  
Vol 131 (1) ◽  
pp. 58-73 ◽  
Author(s):  
Domenico Luca Grieco ◽  
Gian Marco Anzellotti ◽  
Andrea Russo ◽  
Filippo Bongiovanni ◽  
Barbara Costantini ◽  
...  
Keyword(s):  
Lung Volume ◽  
Respiratory Mechanics ◽  
Lung Mechanics ◽  
Control Group ◽  
Obese Patients ◽  
Airway Closure ◽  
Alveolar Pressure ◽  
Opening Pressure ◽  
Airway Opening ◽  
Pressure Controlled

AbstractEditor’s PerspectiveWhat We Already Know about This TopicWhat This Article Tells Us That Is NewBackgroundAirway closure causes lack of communication between proximal airways and alveoli, making tidal inflation start only after a critical airway opening pressure is overcome. The authors conducted a matched cohort study to report the existence of this phenomenon among obese patients undergoing general anesthesia.MethodsWithin the procedures of a clinical trial during gynecological surgery, obese patients underwent respiratory/lung mechanics and lung volume assessment both before and after pneumoperitoneum, in the supine and Trendelenburg positions, respectively. Among patients included in this study, those exhibiting airway closure were compared to a control group of subjects enrolled in the same trial and matched in 1:1 ratio according to body mass index.ResultsEleven of 50 patients (22%) showed airway closure after intubation, with a median (interquartile range) airway opening pressure of 9 cm H2O (6 to 12). With pneumoperitoneum, airway opening pressure increased up to 21 cm H2O (19 to 28) and end-expiratory lung volume remained unchanged (1,294 ml [1,154 to 1,363] vs. 1,160 ml [1,118 to 1,256], P = 0.155), because end-expiratory alveolar pressure increased consistently with airway opening pressure and counterbalanced pneumoperitoneum-induced increases in end-expiratory esophageal pressure (16 cm H2O [15 to 19] vs. 27 cm H2O [23 to 30], P = 0.005). Conversely, matched control subjects experienced a statistically significant greater reduction in end-expiratory lung volume due to pneumoperitoneum (1,113 ml [1,040 to 1,577] vs. 1,000 ml [821 to 1,061], P = 0.006). With airway closure, static/dynamic mechanics failed to measure actual lung/respiratory mechanics. When patients with airway closure underwent pressure-controlled ventilation, no tidal volume was inflated until inspiratory pressure overcame airway opening pressure.ConclusionsIn obese patients, complete airway closure is frequent during anesthesia and is worsened by Trendelenburg pneumoperitoneum, which increases airway opening pressure and alveolar pressure: besides preventing alveolar derecruitment, this yields misinterpretation of respiratory mechanics and generates a pressure threshold to inflate the lung that can reach high values, spreading concerns on the safety of pressure-controlled modes in this setting.

Respiratory Mechanics

2017 ◽  
Author(s):  
John W. Kreit
Keyword(s):  
Mechanical Ventilation ◽  
Respiratory System ◽  
Respiratory Mechanics ◽  
Pressure Change ◽  
Equation Of Motion ◽  
Positive End Expiratory Pressure ◽  
Elastic Recoil ◽  
Viscous Forces ◽  
Equilibrium Volume ◽  
Complex Process

Ventilation can occur only when the respiratory system expands above and then returns to its resting or equilibrium volume. This is just another way of saying that ventilation depends on our ability to breathe. Although breathing requires very little effort and even less thought, it’s nevertheless a fairly complex process. Respiratory Mechanics reviews the interaction between applied and opposing forces during spontaneous and mechanical ventilation. It discusses elastic recoil, viscous forces, compliance, resistance, and the equation of motion and the time constant of the respiratory system. It also describes how and why pleural, alveolar, lung transmural, intra-abdominal, and airway pressure change during spontaneous and mechanical ventilation, and the effect of applied positive end-expiratory pressure (PEEP).

Airway closure and closing volume

1979 ◽  
Vol 46 (1) ◽  
pp. 24-30 ◽  
Author(s):  
L. Forkert ◽  
S. Dhingra ◽  
N. R. Anthonisen
Keyword(s):  
Blood Flow ◽  
Lung Volume ◽  
Regional Perfusion ◽  
Phase Iii ◽  
Breath Hold ◽  
Closing Volume ◽  
Residual Volume ◽  
Airway Closure ◽  
Lung Volumes ◽  
Phase Iv

Using boluses of radioactive Xe we compared regional N2O uptake with regional perfusion distribution during open glottis breath hold in five seated men. Measurements were made near residual volume, at closing volume (CV), above CV and when possible, between CV and residual volume (RV). At low lung volumes basal N2O uptake was small whereas basal blood flow was not. This discrepancy was interpreted as evidence of airway closure and was quantitated. All subjects showed extensive basal closure near RV. At closing volume four of five subjects demonstrated closure and some closure was evident in these subjects at volumes in excess of CV. The increase in airway closure with decreasing lung volume was much greater below CV than above it. Conventional CV tracings were obtained using helium boluses; the height of phase IV was positively correlated with the change in airway closure between CV and RV as assessed by the N2O technique. The slope of phase III did not correlate with the amount of airway closure measured at CV. We concluded that the conventionally measured CV is not the volume at which airway closure begins but that the onset of phase IV reflects an increase in basal airway closure and the height of phase IV reflects the amount of basal closure between CV and RV.

Problems with plethysmographic estimation of lung volume in infants and young children

1982 ◽  
Vol 53 (3) ◽  
pp. 698-702 ◽  
Author(s):  
P. Helms
Keyword(s):  
Young Children ◽  
Lung Volume ◽  
Airway Resistance ◽  
Pressure Change ◽  
Airway Closure ◽  
Lung Volumes ◽  
Mouth Pressure ◽  
Residual Capacity ◽  
Young Subjects ◽  
Intraesophageal Pressure

In 57 infants and very young children, less than 2 yr of age and with a variety of cardiopulmonary illnesses, problems were encountered in the estimation of lung volume with the plethysmographic technique. In 19 subjects calculated thoracic gas volume (TGV) was found to be consistently larger when airway occlusions were performed at low lung volumes than when performed at higher lung volumes. In 13 infants, changes in intraesophageal pressure (Pes) during airway occlusions were found to be larger than simultaneous changes in mouth pressure. In 25 subjects in whom none of the above changes were observed, total pulmonary resistance (TPR) and airway resistance (Raw) did not differ significantly [mean TPR, 50.1 +/- 27.5 cmH2O X l-1; mean Raw, 48.1 +/- 26.5 (P greater than 0.5)]. In the 13 subjects in whom the delta Pes-to-delta Pm occlusion ratio exceeded 1.05, closest agreement with specific resistance (sRaw) and TPR derived lung volume was found when TGV was calculated with delta Pes rather than mouth pressure change (delta Pm). A similar close agreement with the sRaw TPR derived volume was obtained when TGV was calculated during airway occlusions at the higher lung volume. Two separate lung models are proposed to explain these observations, one with a segmental airway closure and the other with more a generalized airway closure. If plethysmographic techniques are to be used in these young subjects for the estimation of lung volume and airway resistance, possible errors may be reduced by performing airway occlusions at lung volumes above functional residual capacity and noting the delta Pes-to-delta Pm ratio obtained during the occlusion.

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