Filtering artefacts in measurements of forced oscillation respiratory impedance in young children.

Respiratory mechanical impedance measured at a single frequency is of great interest to describe change in airways dimensions with time in young children with asthma. Adequate filtering is mandatory in order to eliminate spurious values at rapid flow transient or during glottis closure. The aim of the study was to test a new filtering procedure.

Volume dependence of respiratory system resistance during artificial ventilation in rabbits.

The volume dependence of respiratory resistance (Rrs), usually observed during normal breathing, is expected to be accentuated during expiratory flow limitation (EFL). In order to quantify this dependence we studied the pressure, flow, and volume data obtained from eight New Zealand rabbits, artificially ventilated at different levels of applied expiratory pressure (0-10 hPa), before and during histamine i. v.

Evaluation of a method for assessing respiratory mechanics during noninvasive ventilation.

Noninvasive assessment of respiratory resistance (Rrs) and elastance (Ers), which is not easy with conventional methods, could be useful in the optimization of pressure support ventilation. The aim of this study was to evaluate a simple noninvasive method (Delta-inst) of measuring Rrs during nasal pressure support ventilation. Rrs and Ers (Delta-inst) were computed from inspiratory mask pressure, flow and volume recorded during pressure support ventilation.

Respiratory and upper airways impedance responses to methacholine inhalation in spontaneously breathing cats.

The upper airways may contribute to the increase in respiratory resistance induced by methacholine (Mch). The aim of this study was to simultaneously assess the Mch response of upper airways and lower respiratory resistances (Rua, Rrs,lo) and reactances (Xua, Xrs,lo), and to test whether the change of total respiratory resistance and reactance after Mch were affected by upper airways mechanisms. Seven cats breathing spontaneously were studied under chloralose, urethane anaesthesia.

A simplified method for monitoring respiratory impedance during continuous positive airway pressure.

The forced oscillation technique is useful in detecting changes in upper airway obstruction in patients with sleep apnoea undergoing continuous positive airway pressure (CPAP) ventilation. The aim of this study was to implement and evaluate a method for estimating respiratory impedance (Zrs) from the pressure and flow recorded at the inlet of the CPAP tubing. The method is based on correcting impedance measured at the inlet of the CPAP tubing (Zi) for the effect of the tubing and the exhalation port.

Methacholine-induced volume dependence of respiratory resistance in preschool children.

Enhanced negative volume dependence of airway resistance is associated with bronchoconstriction in tracheostomized paralysed open-chest animals. Significant upper airways responses may be associated with bronchoconstriction and could thereby alter the pattern of volume dependence in spontaneously breathing subjects. The aim of the study was to test whether volume dependence of respiratory resistance (Rrs) could be demonstrated in preschool children undergoing routine methacholine challenge.

Partitioning of respiratory mechanical impedance by absolute and differential body plethysmography.

We have recently demonstrated the feasibility of partitioning total respiratory impedance (Zrs) into its airway (Zaw) and tissular (Zti) components by measuring alveolar gas compression (Vpl) plethysmographically during pressure oscillations at the airway opening (Peslin et al.). The aim of this study was to comparatively evaluate an alternative approach: the measurement of Zrs and of the transfer function (FTF) between airway flow and body surface flow obtained by absolute body plethysmography.

Removal of thermal artifact in alveolar pressure measurement during forced oscillation.

Thoracic gas volume (TGV) may be measured and total respiratory impedance (Zrs) may be partitioned into its airway and tissue (Zti) components by combining forced oscillations and plethysmographic measurements of alveolar gas compression (Vpl) (Peslin, Duvivier, 1998, J. Appl. Physiol.

Forced oscillation total respiratory resistance and spontaneous breathing lung resistance in COPD patients.

Forced-oscillation total respiratory resistance (Rrs) has been shown to underestimate spontaneous breathing lung resistance (RL,sb) in patients with airway obstruction, probably owing to upper airway shunting. The present study reinvestigates that relationship in seven severely obstructed chronic obstructive pulmonary disease patients using a technique that minimizes that artefact. Rrs at 8 and 16 Hz was computed for each successive forced oscillation cycle.

Reliability of thoracic gas volume derived from mechanical impedance at different levels of the vital capacity.

Background: Thoracic gas volume (TGV) may be estimated during spontaneous breathing by measuring simultaneously respiratory impedance (Zrs) and alveolar gas compression (Vpl) at several oscillation frequencies [Peslin and Duvivier: J Appl Physiol 1998;84:862-867].

Objective: The aim of the study was to test the validity of that approach at different levels of the vital capacity (VC).

Methods: We measured Zrs and Vpl at frequencies ranging from 6 to 29 Hz in 10 healthy subjects rebreathing BTPS gas in a constant volume body plethysmograph.

Assessment of bronchial reactivity by forced oscillation admittance avoids the upper airway artefact.

The forced oscillation technique (FOT) allows easy assessment of bronchial reactivity. The use of a standard FOT generator (SG) results in changes in respiratory system resistance (delta Rrs,SG) which are affected by an artefact caused by the extrathoracic upper airway (EUA). The aim was to improve the FOT assessment of bronchial reactivity with the SG by computing the change in FOT admittance (delta Ars,SG), which is theoretically unaffected by this artefact.

Dose-response slope of forced oscillation and forced expiratory parameters in bronchial challenge testing.

In population studies, the provocative dose (PD) of bronchoconstrictor causing a significant decrement in lung function cannot be calculated for most subjects. Dose-response curves for carbachol were examined to determine whether this relationship can be summarized by means of a continuous index likely to be calculable for all subjects, namely the two-point dose response slope (DRS) of mean resistance (Rm) and resistance at 10 Hz (R10) measured by the forced oscillation technique (FOT). Five doses of carbachol (320 microg each) were inhaled by 71 patients referred for investigation of asthma (n=16), chronic cough (n=15), nasal polyposis (n=8), chronic rhinitis (n=8), dyspnoea (n=8), urticaria (n=5), post-anaphylactic shock (n=4) and miscellaneous conditions (n=7).

Variations in airways impedance during respiratory cycle derived from combined measurements of input and transfer impedances.

Simultaneous measurement of input (Zin) and transfer impedances (Ztr) allows separation of airway and tissue properties at a single frequency, without making assumptions concerning the structure of the two compartments. This approach offers the possibility of studying the variation in airway impedance (Zaw) during the respiratory cycle. Zin and Ztr were measured at frequencies of 10, 20, 30 and 40 Hz in eight healthy subjects to study the variations in Zaw according to a modification of the Rohrer's equation: X=K1+K2(V'ao)-K3V, where V is volume and V'ao the flow at the airway opening.

Flow-dependent positive airway pressure to maintain airway patency in sleep apnea-hypopnea syndrome.

Airway obstruction in patients with sleep apnea-hypopnea syndrome (SAHS) is due to increased critical pressure (Pcrit) of the upper airway. The ideal nasal pressure (Pn) to maintain airway patency should consist of the constant term to account for Pcrit and a term (Rn . V) proportional to flow (V) to account for the dynamic pressure drop through nasal resistance (R n).

Reproducibility of lung volume measurements.

Test reproducibility is an important consideration when interpreting results and should be set as a goal during data collection. Reproducibility criteria may need to be different for different subject groups and are instrument and procedure-dependent. Ideally, the within-subject variability for each lung volume and measurement technique used should be established for each laboratory.

Evaluation of a forced oscillation method to measure thoracic gas volume.

The purpose of this study was to test a plethysmographic method of measuring thoracic gas volume (TGV) that, contrary to the usual panting method, would not require any active cooperation from the subject. It is based on the assumption that the out-of-phase component of airway impedance varies linearly with frequency. By using that assumption, TGV may be computed by combining measurements of total respiratory impedance (Zrs) and of the relationship between the plethysmographic signal (Vpl) and airway flow (V) during forced oscillations at several frequencies.

Partitioning of airway and respiratory tissue mechanical impedances by body plethysmography.

We have tested the feasibility of separating the airway (Zaw) and tissue (Zti) components of total respiratory input impedance (Zrs,in) in healthy subjects by measuring alveolar gas compression by body plethysmography (Vpl) during pressure oscillations at the airway opening. The forced oscillation set up was placed inside a body plethysmograph, and the subjects rebreathed BTPS gas. Zrs,in and the relationship between Vpl and airway flow (Hpl) were measured from 4 to 29 Hz.

Respiratory oscillation mechanics in infants with bronchiolitis during mechanical ventilation.

The aim of the study was to describe the pattern of respiratory oscillation mechanics and responses to positive end-expiratory pressure (PEEP) in bronchiolitis. Six infants were studied during the course of mechanical ventilation. A 20 Hz sinusoidal pressure variation was applied at the endotracheal tube where flow was measured with a pneumotachograph.

Vasodilators, aortic elasticity, and ventricular end-systolic stress in nonanesthetized unrestrained rats.

We evaluated the effect of different vasodilators on ventricular end-systolic stress by investigating the impact of sodium nitroprusside, nifedipine, and hydralazine on blood pressure, aortic stiffness, and wave reflection during drug-induced hypotension (to 80 mm Hg mean blood pressure) in normotensive (central aortic mean blood pressure, 116 to 119 mm Hg; systolic pressure, 133 to 137 mm Hg), nonanesthetized, unrestrained rats. Aortic stiffness was evaluated from the slope of the linear regression relating pulse wave velocity (PWV) to central aortic mean or pulse pressure. The fall in central aortic systolic blood pressure was less than the fall in mean pressure, especially after hydralazine (122+/-4 mm Hg; sodium nitroprusside, 107+/-2; and nifedipine, 112+/-3 mm Hg; P<.

Effect of the inhibitor of NO synthase, NG-nitro-L-arginine methyl ester, on histamine-induced bronchospasm in the rabbit.

New Zealand male rabbits were anaesthetized with thiopental, tracheotomized, curarized by vecuronium bromide and mechanically ventilated. Six rabbits received L-NAME 10 mg kg-1 i.v.

Influence of external loading and assisted ventilation on chest wall mechanical properties.

Instantaneous respiratory effective elastance (Eteff) and tissue resistance (Rt) may be measured by studying the relationship between flow at the airway opening and at the chest during forced oscillations; using that method it has been shown that Rt varies little during breathing while Eteff presents much larger phasic variations than can be explained by the curvature of the static pressure-volume curve (Tomalak et a1., 1997). The aim of this study was to test the hypothesis that the large variations of Eteff were related to the activity of respiratory muscles.

Respiratory tissue properties derived from flow transfer function in healthy humans.

Assuming homogeneity of alveolar pressure, the relationship between airway flow and flow at the chest during forced oscillation at the airway opening [flow transfer function (FTF)] is related to lung and chest wall tissue impedance (Zti): FTF = 1 + Zti/Zg, where Zg is alveolar gas impedance, which is inversely proportional to thoracic gas volume. By using a flow-type body plethysmograph to obtain flow rate at body surface, FTF has been measured at oscillation frequencies (f(os)) of 10, 20, 30 and 40 Hz in eight healthy subjects during both quiet and deep breathing. The data were corrected for the flow shunted through upper airway walls and analyzed in terms of tissue resistance (Rti) and effective elastance (Eti,eff) by using plethysmographically measured thoracic gas volume values.

Calcification of medial elastic fibers and aortic elasticity.

We tested the hypothesis that a simple change in wall composition (medial calcium overload of elastic fibers) can decrease aortic elasticity. Calcium overload was produced by hypervitaminosis D plus nicotine (VDN) in the young rat. Two months later, measurement of central aortic mean blood pressure in the unanesthetized, unrestrained rat showed that the VDN rat suffered from isolated systolic hypertension but that mean blood pressure was normal.

Inspiratory dynamic obstruction detected by forced oscillation during CPAP. A model study.

Assessment of upper airway mechanics in patients with obstructive sleep apnea/hypopnea (OSA) can be carried out qualitatively from indirect signals (flow pattern, snoring, strain gauges, inductance plethysmography) or quantitatively by means of invasive estimation of esophageal pressure. The forced oscillation technique (FOT) is a noninvasive method of potential interest for quantitatively assessing airway obstruction in the sleeping patient. The aim of this work was to ascertain in a model study whether FOT could provide an index of airway obstruction when applied at the conditions of total and partial occlusions similar to the ones found in patients with OSA.