Heterogeneous Airway Versus Tissue Mechanics and Their Relation to Gas Exchange Function During Mechanical Ventilation

We have advanced a commercially available ventilator (NPB840, Puritan Bennett/Tyco Healthcare, Pleasanton, CA) to deliver an Enhanced Ventilation Waveform (EVW). This EVW delivers a broadband waveform that contains discrete frequencies blended to provide a tidal breath, followed by passive exhalation. The EVW allows breath-by-breath estimates of frequency dependence of lung and total respiratory resistance (R) and elastance (E) from 0.2 to 8 Hz. We hypothesized that the EVW approach could provide continuous ventilation simultaneously with an advanced evaluation of mechanical heterogeneities under heterogeneous airway and tissue disease conditions. We applied the EVW in five sheep before and after a bronchial challenge and an oleic acid (OA) acute lung injury model. In all sheep, the EVW maintained gas exchange during and after bronchoconstriction, as well as during OA injury. Data revealed a range of disease conditions from mild to severe with heterogeneities and airway closures. Correlations were found between the arterial partial pressure of oxygen (P_aO2) and the levels and frequency-dependent features of R and E that are indicative of mechanical heterogeneity and tissue disease. Lumped parameter models provided additional insight on heterogeneous airway and tissue disease. In summary, information obtained from EVW analysis can provide enhanced guidance on the efficiency of ventilator settings and on patient status during mechanical ventilation.     

Effects of periodic obstructive apnoeas on superior and inferior venous return in dogs

Obstructive apnoeas could cause flow limitation to venous return, resulting in a decrease in cardiac output and a change in the distribution of flow from the upper and lower body. In 14 anaesthetized dogs, we studied the effects of obstructive apnoeas on inferior and superior vena caval flows under baseline conditions and with intra-abdominal pressure increased by ≈5 torr by binding the abdomen. During obstructive apnoeas in the two groups, respiratory rate decreased by 30% (P < 0.02) and inspiratory airway pressure decreased by ≈15 torr (P < 0.01). At baseline, the ratio of inferior to superior vena caval flow was 2.4:1 and did not change with abdominal binding or apnoeas. During apnoeas there was no change in cardiac output or in the ratio of inferior to superior vena cava flow either with baseline or abdominal binding conditions. Preservation of total inferior vena caval flow during apnoeas and cardiac output occurred, even though inspiratory flow limitation was found with the abdomen bound. We conclude: (1) there was no change in either cardiac output or the distribution of venous return during apnoeas; (2) there was substantial inspiratory/expiratory variation in venous return during obstructive apnoeas. The large inspiratory increase in venous return may have implications for the development of pulmonary hypertension during obstructive apnoeas.     

Assessment of upper airway mechanics during sleep

Obstructive sleep apnea, which is the most prevalent sleep breathing disorder, is characterized by recurrent episodes of upper airway collapse and reopening. However, the mechanical properties of the upper airway are not directly measured in routine polysomnography because only qualitative sensors (thermistors for flow and thoraco-abdominal bands for pressure) are used. This review focuses on two techniques that quantify upper airway obstruction during sleep. A Starling model of collapsible conduit allows us to interpret the mechanics of the upper airway by means of two parameters: the critical pressure (P_crit) and the upstream resistance (R_up). A simple technique to measure P_crit and R_up involves the application of different levels of continuous positive airway pressure (CPAP) during sleep. The forced oscillation technique is another non-invasive procedure for quantifying upper airway impedance during the breathing cycle in sleep studies. The latest developments in these two methods allow them to be easily applied on a routine basis in order to more fully characterize upper airway mechanics in patients with sleep breathing disorders.     

Effect of medroxyprogesterone on inspiratory flow shapes during sleep in postmenopausal women

We previously showed that medroxyprogesterone acetate (MPA) effectively decreases the arterial CO(2) levels in postmenopausal women with partial upper airway obstruction. The aim of the present study was to analyze the effects of MPA on the inspiratory flow shapes during sleep. Eight postmenopausal women with hypoxemia and partial upper airway obstruction during sleep (patients) received MPA 60 mg daily for 14 days. Four matched postmenopausal women without MPA treatment served as controls. Sleep and nasal pressure were recorded on each visit. Each breath was analyzed for duration, volume and inspiratory flow shape class. MPA shortened inspiration and prolonged expiration. The inspiratory volumes increased consistently in all flow shape classes. The inspiratory shapes with single late peak were transformed to those with double peak. MPA also decreased shapes with mid-peak or mid-plateau. MPA did not have an effect on sleep. Sleep modified the flow shape distribution only in patients but in a similar fashion in stages S2, SWS and REM. The results suggest that postmenopausal women present with a significant proportion breaths with poor initial inspiratory flow, which is reversed with MPA-induced respiratory stimulation.     

Acute and chronic responses of the upper airway to inspiratory loading in healthy awake humans: an MRI study

We assessed upper airway responses to acute and chronic inspiratory loading. In Experiment I, 11 healthy subjects underwent T(2)-weighted magnetic resonance imaging (MRI) of upper airway dilator muscles (genioglossus and geniohyoid) before and up to 10 min after a single bout of pressure threshold inspiratory muscle training (IMT) at 60% maximal inspiratory mouth pressure (MIP). T(2) values for genioglossus and geniohyoid were increased versus control (p<0.001), suggesting that these airway dilator muscles are activated in response to acute IMT. In Experiment II, nine subjects underwent 2D-Flash sequence MRI of the upper airway during quiet breathing and while performing single inspirations against resistive loads (10%, 30% and 50% MIP); this procedure was repeated after 6 weeks of IMT. Lateral narrowing of the upper airway occurred at all loads, whilst anteroposterior narrowing occurred at the level of the laryngopharynx at loads > or =30% MIP. Changes in upper airway morphology and narrowing after IMT were undetectable using MRI.     

Effect of specific inspiratory muscle warm-up on intense intermittent run to exhaustion

The effects of inspiratory muscle (IM) warm-up on the maximum dynamic IM function and the maximum repetitions of 20-m shuttle run (Ex) in the Yo-Yo intermittent recovery test were examined. Ten men were recruited to perform identical IM function test and exercise test in three different trials randomly. The control trial was without IM warm-up while the placebo and experimental trials were with IM warm-up by performing two sets of 30 breaths with inspiratory pressure-threshold load equivalent to 15% (IMW_P) and 40% (IMW) maximum inspiratory mouth pressure, respectively. In IMW, maximum dynamic IM functions including the maximal inspiratory pressure at zero flow (P ₀) and maximal rate of P ₀ development (MRPD) were increased compared with control values (P<0.05). The Ex was also augmented [mean (SD)] [19.5% (12.6)] while the slope of the linear relationship of the increase in rating of perceived breathlessness for every 4th exercise interval (RPB/4i) was reduced (P<0.05). In IMW_P, although increase in Ex and reduction in RPB/4i were occurred concomitantly in some subjects, the differences in Ex, RPB/4i and dynamic IM functions between control and IMW_P trials were not statistically significant. For the changes (Δ) in parameters in IMW and IMW_P (n=20), negative correlations were found between Δ RPB/4i and Δ Ex (r=−0.92), ΔP ₀ and Δ RPB/4i (r=−0.48), and Δ MRPD and Δ RPB/4i (r=−0.54). Such findings suggested that the specific IM warm-up in IMW may entail reduction in breathlessness sensation, partly attributable to the enhancement of dynamic IM functions, in subsequent exhaustive intermittent run and, in turn, improve the exercise tolerance.     

Relation Between Structure,Function, and Imaging in a Three-Dimensional Model of the Lung

Previous studies have reported morphometric models to predict function relations in the lung. These models, however, are not anatomically explicit. We have advanced a three-dimensional airway tree model to relate dynamic lung function to alterations in structure, particularly when constriction patterns are imposed heterogeneously in specific anatomic locations. First, we predicted the sensitivity of dynamic lung resistance and elastance R _L and E _L ) to explicit forms of potential constriction patterns. Simulations show that severe and heterogeneous peripheral airway constriction confined to a single region in the lung (apex, mid, or base) will not produce substantial alterations in whole lung properties as measured from the airway opening. Conversely, when measured R _L and E _L are abnormal, it is likely that significant (but not necessarily homogeneous) constriction has occurred throughout the entire airway tree. We also introduce the concept of image-assisted modeling. Here positron emission tomographic imaging data sensitive to ventilation heterogeneity is synthesized with R _L and E _L data to help identify which airway constriction conditions could be consistent with both data sets. An ultimate goal would be personalized predictions. © 2003 Biomedical Engineering Society. PAC2003: 8719Uv, 8710+e, 8758Fg     

Breath-by-breath determinations of airway occlusion pressure in the developing lamb

The ventilatory effects of breath-by-breath measurements of airway occlusion pressure, i.e., airway pressure determined 100 ms after initiation of inspiration (P _{0. 1}) were evaluated in seven lambs studied sequentially between 7 and 28 days after birth. P _0.1 was determined by computer-aided, on-line regression analysis of the inspiratory pressure versus time (dP/dt) by means of a pneumatic occlusion valve that allowed occlusion times to vary in proportion to respiratory rate. No significant changes were found in minute ventilation, tidal volume, respiratory rate or end-tidal CO₂ concentration when the valve was operating as a one-way valve (opening pressure 0.02 kPa or 0.2 cm H₂0) compared to when in occlusion mode [opening pressure 0.18–0.2 kPa or 1.8–2.0 cmH₂0, mean occlusion time 44 (25) ms]. The calculated P _0.1 values correlated well with those obtained from manual occlusions (r = 0.87, P < 0.0001). This new technique, which detects and discards irregular or non-linear (r < 0.95) inspiratory pressure profiles, enables breath-by-breath determinations of inspiratory drive in rapidly breathing lambs with minimal impact on respiratory pattern and ventilation.These results were presented in part at the annual meetings of the American Pediatric Society and the Society for Pediatric Research 1992     

Dynamic lung mechanics in late-stage emphysema before and after lung volume reduction surgery

This study evaluated the effects of lung volume reduction surgery (LVRS) on the heterogeneity of lung function in awake, late-stage emphysema patients with measurements taken before and after full recovery from LVRS. We assessed standard clinical measures of lung function and functional heterogeneity in six awake, late-stage emphysema patients before and 6 months after LVRS. Functional heterogeneity was quantified by measuring dynamic inspiratory resistance (R(L)(insp)) and elastance (E(L)(insp)) over a frequency range that included normal breathing ( approximately 0.33-8 Hz). Since LVRS involves targeted resection of emphysematous regions of the lung, we hypothesized that emphysema patients would be functionally more homogeneous post-LVRS. We also compared our measures of functional heterogeneity with indices of anatomic heterogeneity and severity using high-resolution computed tomography (HRCT). After LVRS, 6 min walk distance increased by 22% (940+/-91 versus 1158+/-299, p=0.031) and recoil pressure at TLC increased (9.0+/-2.0 versus 14+/-5, p=0.031), but changes in R(L)(insp) and E(L)(insp) varied greatly between subjects. A measure of anatomic severity quantified using HRCT positively correlated with airway resistance (r(s)=0.89, p=0.048). These results suggest that subjects with more severe disease as assessed by HRCT criteria had reduced overall effective airway caliber consequent to active airway constriction, reduced parenchymal tethering, and/or loss of parallel lung units. Furthermore, LVRS may not necessarily improve lung function via a substantial reduction in mechanical heterogeneity.     

PAP treatment in patients with OSA does not induce long‐term nasal obstruction

We hypothesized that positive airway pressure treatment would induce nasal obstruction and decrease nasal cavity due to mucosal swelling. We further hypothesized that subjective and objective nasal obstruction at baseline would negatively affect positive airway pressure adherence. A total of 728 patients with sleep apnea were investigated in the Icelandic Sleep Apnea Cohort at baseline and 2 years after starting positive airway pressure. Patients underwent home sleep apnea testing at baseline. Questionnaires were answered and acoustic rhinometry was completed at baseline and follow‐up. The proportion of patients reporting subjective nocturnal nasal obstruction was reduced (baseline: 35% versus follow‐up: 24%; p < 0.001). Small interior nasal dimensions increased (p < 0.001) independent of adherence to treatment. Small nasal volume at baseline was a determinant for becoming a non‐user of positive airway pressure treatment (odds ratio 2.22, confidence interval 95% 1.35–3.67, p = 0.002). Subjective nasal obstruction decreased 2 years after initiating positive airway treatment in sleep apnea, and objectively small nasal dimensions increased. Small nasal volume at baseline was a negative predictor for positive airway pressure treatment adherence. Maybe most importantly, positive airway pressure treatment did not cause long‐term objective or subjective nasal obstruction.     

Task failure from inspiratory resistive loaded breathing: a role for inspiratory muscle fatigue?

The use of non-invasive resistive breathing to task failure to assess inspiratory muscle performance remains a matter of debate. CO₂ retention rather than diaphragmatic fatigue was suggested to limit endurance during inspiratory resistive breathing. Cervical magnetic stimulation (CMS) allows discrimination between diaphragmatic and rib cage muscle fatigue. We tested a new protocol with respect to the extent and the partitioning of inspiratory muscle fatigue at task failure. Nine healthy subjects performed two runs of inspiratory resistive breathing at 67 (12)% of their maximal inspiratory mouth pressure, respiratory rate ( f_R), paced at 18 min^–1, with a 15-min pause between runs. Diaphragm and rib cage muscle contractility were assessed from CMS-induced esophageal (P_es,tw), gastric (P_ga,tw), and transdiaphragmatic (P_di,tw) twitch pressures. Average endurance times of the first and second runs were similar [9.1 (6.7) and 8.4 (3.5) min]. P_di,tw significantly decreased from 33.1 to 25.9 cmH₂O in the first run, partially recovered (27.6 cmH₂O), and decreased further in the second run (23.4 cmH₂O). P_es,tw also decreased significantly (–5.1 and –2.4 cmH₂O), while P_ga,tw did not change significantly (–2.0 and –1.9 cmH₂O), indicating more pronounced rib cage rather than diaphragmatic fatigue. End-tidal partial pressure of CO₂ (P_ETCO₂) rose from 37.2 to 44.0 and 45.3 mmHg, and arterial oxygen saturation (S_aO₂) decreased in both runs from 98% to 94%. Thus, task failure in mouth-pressure-targeted, inspiratory resistive breathing is associated with both diaphragmatic and rib cage muscle fatigue. Similar endurance times despite different degrees of muscle fatigue at the start of the runs indicate that other factors, e.g. increases in P_ETCO₂, and/or decreases in S_aO₂, probably contributed to task-failure.     

Assessment of time-domain analyses for estimation of low-frequency respiratory mechanical properties and impedance spectra

Time-domain estimation has been invoked for tracking of respiratory mechanical properties using primarily a simple single-compartment model containing a series resistance (R _rs) and elastance (E _rs). However, owing to the viscoelastic properties of respiratory tissues,R _rs andE _rs exhibit frequency dependence below 2 Hz. The goal of this study was to investigate the bias and statistical accuracy of various time-domain approaches with respect to model properties, as well as the estimated impedance spectra. Particular emphasis was placed on establishing the tracking capability using a standard step ventilation. A simulation study compared continuous-timeversus discrete-time approaches for both the single-compartment and two-compartment models. Data were acquired in four healthy humans and two dogs before and after induced severe pulmonary edema while applying sinusoidal and standard ventilator forcing.R _rs andE _rs were estimated either by the standard Fast Fourier Transform (FFT) approach or by a time-domain least square estimation. Results show that the continuous-time model form produced the least bias and smallest parameter uncertainty for a single-compartment analysis and is quite amenable for reliable on-line tracking. The discrete-time approach exhibits large uncertainty and bias, particularly with increasing noise in the flow data. In humans, the time-domain approach produced smooth estimates ofR _rs andE _rs spectra, but they were statistically unreliable at the lower frequencies. In dogs, both the FFT and time-domain analysis produced reliable and stable estimates forR _rs orE _rs spectra for frequencies out to 2 Hz in all conditions. Nevertheless, obtaining stable on-line parameter estimates for the two-compartment viscoelastic models remained difficult. We conclude that time-domain analysis of respiratory mechanics should invoke a continuous-time model form.     

Attenuated inspiratory muscle metaboreflex in endurance-trained individuals

The inspiratory metaboreflex is activated during loaded breathing to task failure and induces sympathetic activation and peripheral vasoconstriction that may limit exercise performance. Inspiratory muscle training appears to attenuate the inspiratory metaboreflex in healthy subjects. Since whole body aerobic exercise training improves breathing endurance and inspiratory muscle strength, we hypothesized that endurance-trained individuals would demonstrate a blunted inspiratory muscle metaboreflex in comparison to sedentary individuals. We studied 9 runners (23±0.7 years; maximal oxygen uptake [VO2 max] = 53 ± 4 ml kg(-1) min(-1)) and 9 sedentary healthy volunteers (24±0.7 years; VO2 max = 37 ±2 ml kg(-1) min(-1)). The inspiratory muscle metaboreflex was induced by breathing against an inspiratory load of 60% of maximal inspiratory pressure (MIP), with prolonged duty cycle. Arterial pressure, popliteal blood flow, and heart rate were measured throughout the protocol. Loaded breathing to task failure increased mean arterial pressure in both sedentary and endurance-trained individuals (96±3 to 100±4 mmHg and 101±3 to 110±5 mmHg). Popliteal blood flow decreased in sedentary but not in trained individuals (0.179±0.01 to 0.141±0.01 cm/s, and 0.211±0.02 to 0.214±0.02 cm/s). Similarly, popliteal vascular resistance increased in sedentary but not in trained individuals (559±35 to 757±56 mmHg s/cm, and 528±69 to 558±64 mmHg s/cm). These data demonstrate that endurance-trained individuals have an attenuated inspiratory muscle metaboreflex.     

Respiratory muscle performance with stretch‐shortening cycle manoeuvres: maximal inspiratory pressure–flow curves

Aim: To test the hypothesis that the maximal inspiratory muscle (IM) performance, as assessed by the maximal IM pressure–flow relationship, is enhanced with the stretch‐shortening cycle (SSC). Methods: Maximal inspiratory flow–pressure curves were measured in 12 healthy volunteers (35 ± 6 years) during maximal single efforts through a range of graded resistors (4‐, 6‐, and 8‐mm diameter orifices), against an occluded airway, and with a minimal load (wide‐open resistor). Maximal inspiratory efforts were initiated at a volume near residual lung volume (RV). The subjects exhaled to RV using slow (S) or fast (F) manoeuvres. With the S manoeuvre, they exhaled slowly to RV and held the breath at RV for about 4 s prior to maximal inspiration. With the F manoeuvre, they exhaled rapidly to RV and immediately inhaled maximally without a post‐expiratory hold; a strategy designed to enhance inspiratory pressure via the SSC. Results: The maximal inspiratory pressure–flow relationship was linear with the S and F manoeuvres (r² = 0.88 for S and r² = 0.88 for F manoeuvre, P < 0.0005 in all subjects). With the F manoeuvre, the pressure–flow relationship shifted to the right in a parallel fashion and the calculated maximal power increased by approximately 10% (P < 0.05) over that calculated with the S manoeuvre. Conclusion: The maximal inspiratory pressure–flow capacity can be enhanced with SSC manoeuvres in a manner analogous to increases in the force–velocity relationship with SSC reported for skeletal muscles.     

Collapsible upper airway segment to study the obstructive sleep apnea/hypopnea syndrome in rats

Animal models have been used to study the pathophysiology of the obstructive sleep apnea/hypopnea syndrome (SAHS). Nevertheless, in none of the models described to date have the animals been subjected to the different patterns of upper airway obstructive events (apneas, hypopneas, and inspiratory flow limitation) characterizing SAHS. Our aim was to devise and test a computer-controlled collapsible upper airway segment applicable to rats and able to realistically mimic obstructive SAHS events. The collapsible segment (total volume <2 cm(3) and a dead space of approximately 0.25 cm(3)) consisted of a Starling resistor based on a latex membrane subjected to an external pressure applied by a computer-controlled pressure source. The collapsible segment was tested in eight anaesthetized and tracheostomized rats. The upper airway segment allowed us to induce obstructive apneas and hypopneas with flow and inspiratory effort waveforms similar to the ones observed in patients with SAHS. This collapsible upper airway segment may be a useful tool to implement a rat model of SAHS.     

Acute effects of inspiratory pressure threshold loading upon airway resistance in people with asthma

Large inspiratory pressures may impart stretch to airway smooth muscle and modify the response to deep inspiration (DI) in asthmatics. Respiratory system resistance (Rrs) was assessed in response to 5 inspiratory manoeuvres using the forced oscillation technique: (a) single unloaded DI; (b) single DI at 25 cmH₂O; (c) single DI at 50% maximum inspiratory mouth pressure [MIP]; (d) 30 DIs at 50% MIP; and (e) 30 DIs at 50% MIP with maintenance of normocapnia. Rrs increased after the unloaded DI and the DI at 25 cmH₂O but not after a DI at 50% MIP (3.6 ± 1.6 hPa L s⁻¹ vs. 3.6 ± 1.5 hPa L s⁻¹; p = 0.95), 30 DIs at 50% MIP (3.9 ± 1.5 hPa L s⁻¹ vs. 4.2 ± 2.0 hPa L s⁻¹; p = 0.16) or 30 DIs at 50% MIP under normocapnic conditions (3.9 ± 1.5 hPa L s⁻¹ vs. 3.9 ± 1.5 hPa L s⁻¹; p = 0.55). Increases in Rrs in response to DI were attenuated after single and multiple loaded breaths at 50% MIP.     

慢性阻塞性肺疾病患者深吸气量与运动能力的关系

目的: 探讨慢性阻塞性肺疾病(COPD)患者深吸气量与运动能力的关系。方法: 采用呼气负压技术(NEP)检测42例缓解期COPD患者平静呼吸时呼气气流受限(EFL)情况。将COPD患者分为EFL组和无EFL组,并进行常规肺功能和症状限制递增功率心肺运动测试。结果: 42例COPD患者中29例在平静呼吸时检测到EFL,13例未检测到EFL。与无EFL组相比,EFL组深吸气量占预计值百分比(IC%pred)(P＜0.01)、第1 s用力呼气容积占预计值百分比(FEV₁%pred)(P＜0.01)、第1 s用力呼气容积占用力肺活量百分比(FEV₁/FVC%)(P＜0.01)、比弥散量占预计值百分比(DLCO/V_A%pred)(P＜0.05)和最大摄氧量占预计值百分比(VO₂max%pred)(P＜0.01)均显著下降。多元逐步回归分析结果表明,IC%pred和FEV₁%pred对VO₂max%pred有显著预测意义。在EFL组,IC%pred与VO₂max%pred的相关性最好(r=0.787,P＜0.01);在无EFL组,FEV₁%pred与VO₂max%pred的相关性最好(r=0.625,P＜0.01)。结论: 在平静呼吸时出现EFL的COPD患者,肺过度充气可能是运动能力下降的主要原因;在平静呼吸时无EFL的COPD患者,气流阻塞可能是运动能力下降的主要原因。     

The effect of flow limitation on the cardiorespiratory response to arousal from sleep under controlled conditions of chemostimulation in healthy older adults

The influence of flow limitation on the magnitude of the cardiorespiratory response to arousal from sleep is of interest in older people, because they experience considerable flow limitation and frequent arousals from sleep. We studied older flow‐limiting subjects, testing the hypothesis that the cardiorespiratory activation response would be larger when arousal occurred during flow limitation, compared to no flow limitation, and chemical stimuli were controlled. In 11 older adults [mean ± standard deviation (SD) age: 68 ± 5 years] ventilation was stabilized using continuous positive airway pressure, and flow limitation was induced by dialling down the pressure. Partial pressure of end‐tidal carbon dioxide (PetCO₂) was maintained by titration of the inspired CO₂ and hyperoxia was maintained using 40% O₂ balanced with nitrogen. Flow limitation at the time of arousal did not augment cardiovascular activation response (heart rate P = 0.7; systolic blood pressure P = 0.6; diastolic blood pressure P = 0.3), whereas ventilation was greater following arousals during flow limitation compared to no flow limitation (P < 0.001). The pre–post‐arousal differences in ventilation reflected significant pre‐arousal suppression (due to flow limitation) plus post‐arousal activation. In summary, the cardiovascular response to arousal from sleep is not influenced by flow limitation at the time of arousal, when chemical stimuli are controlled in older adults. This finding may contribute to the decreased cardiovascular burden associated with sleep‐disordered breathing reported in older adults, although our data do not exclude the possibility that flow limitation in the presence of mild hypoxic hypercapnia could increase the cardiovascular response to arousal.     

Upper airway calibre and impedance in patients with Steinert's myotonic dystrophy

Myotonic dystrophy (MD) can be responsible for increased inspiratory muscle loading, the origin of which is debated, with some authors incriminating distal lesions and others central abnormalities. Using a recent non-invasive method based on single transient pressure-wave reflection analysis, we measured central airway calibre from the mouth to the carina and respiratory impedance in a group of adults with MD, a group of patients with sleep apnoea syndrome (SAS) but no neuromuscular disease, and a group of normal controls. All participants were awake during the measurements. We found no reduction in central airway calibre in the patients with the adult form of MD, as compared to the normal controls. These data suggest that MD may be associated with peripheral airway obstruction related to alterations in the elastic properties of the lung.     

Role of the mechanical impairment on the ventilatory response to CO2 in chronic airway obstruction

The purpose of this study was to assess the relationship between the breathing pattern response to CO2 and the severity of mechanical impairment in twenty patients with COLD. The CO2 response was compared to that of a control group of twelve normal subjects. All patients had airway obstruction (FEV1 = 40 +/- 14% of predicted; means +/- SD) and hyperinflation (FRC = 154 +/- 23% of predicted). Tidal volume (VT), inspiratory and total cycle duration (TI, TT), occlusion pressure (P0.1) and endtidal PCO2 were measured at rest and during hyperoxic CO2 rebreathing. On the same day, in all patients, arterial blood gas analysis, spirometric and plethysmographic measurements were made. The slope (S) of the P0.1 response (SP 0.1) to increasing endtidal PCO2 was negatively correlated with airway resistance (r = -0.59; p less than 0.01). Although the flow response, S(VT/TI), was positively and closely correlated with SP 0.1 (r = 0.88; p less than 0.001), it also appeared to be independently influenced by obstruction (p less than 0.01). The tidal volume response, SVT, was principally correlated with inspiratory capacity (r = 0.90; p less than 0.001) and also, independently, with Vmax50 (p less than 0.01). SVT was diminished in seventeen patients, ten of whom only had a decreased S(VT/TI). The shortening in TI during hypercapnia was most marked in patients with the greatest S(P0.1), who did not have arterial hypercapnia at rest. These results suggest: that the poor VT response to CO2 in COLD patients is principally caused by a limitation in inspiratory volume expansion.(ABSTRACT TRUNCATED AT 250 WORDS)