Lung volume changes in response to altered breathing gas pressure during upright immersion

Summary Since elastic and flow-resistive respiratory work are volume dependent, changes in lung volume during immersion affect respiratory effort. This investigation examined changes in lung volume with air delivery pressure modifications during upright immersion. Static pressure-volume relaxation relationships and lung volumes were obtained from ten immersed subjects breathing air at four delivery pressures: mouth pressure, lung centroid pressure (P _LC), and 0.98 kPa above and belowP _LC. TheP _LC is the static lung pressure which returns the respiratory relaxation volume (V _R) to normal and was previously determined to be + 1.33 kPa relative to pressure at the sternal notch. Lung volume changes observed when breathing air at mouth pressure were reversed when air was supplied atP _LC. The expiratory reserve volume (ERV) and VR were reduced by 58% and 87%, respectively, during uncompensated immersion. These differences indicated an active defence of ERV and implied that additional static respiratory work was required to overcome transrespiratory pressure gradients.     

Non-invasive semi-quantitative measurements of tidal pressure-volume and flow relations of lung in COPD patients

Movement of the suprasternal fossa as detected by surface inductive plethysmography (SIP) has been utilized as a non-invasive means for estimation of intrapleural pressure in the calculation of lung compliance. The purpose of the present study was to ascertain whether pulmonary resistance and work of breathing could also be obtained with SIP. A new calibration procedure based upon substituting values for inspiratory total respiratory resistance measured by forced oscillations into an uncalibrated SIP deflection-flow loop was utilized to convert the SIP waveform to a pressure recording. This permitted estimation of lung compliance, expiratory pulmonary resistance and work of breathing which were then compared to simultaneously measured intraesophageal pressure derived values. Nine seated patients with varying degrees of obstructive airways disease were studied. No differences were found between the SIP and intraesophageal derived group mean values for any parameters, viz inspiratory and expiratory pulmonary resistance, lung compliance and work of breathing. The least variable measurement between the two methods was the work of breathing in which eight of the nine patients had values deviating less than 25% from unity. Values for lung compliance were slightly more divergent and expiratory pulmonary resistance showed large variation. The present investigation indicates that surface inductive plethysmographic detection of suprasternal fossa movement reflects intrapleural pressure swings in a semiquantitative manner; it serves as a non-invasive research technique for estimation of lung compliance, pulmonary resistance and work of breathing.     

Pulmonary adaptations to swim and inspiratory muscle training

Because the anomalous respiratory characteristics of competitive swimmers have been suggested to be due to inspiratory muscle work, the respiratory muscle and pulmonary function of 30 competitively trained swimmers was assessed at the beginning and end of an intensive 12-week swim training (ST) program. Swimmers (n = 10) combined ST with either inspiratory muscle training (IMT) set at 80% sustained maximal inspiratory pressure (SMIP) with progressively increased work-rest ratios until task failure for 3-days per week (ST + IMT) or ST with sham-IMT (ST + SHAM-IMT, n = 10), or acted as controls (ST only, ST, n = 10). Measures of respiratory and pulmonary function were assessed at the beginning and end of the 12 week study period. There were no significant differences (P > 0.05) in respiratory and pulmonary function between groups (ST + IMT, ST + SHAM-IMT and ST) at baseline and at the end of the 12 week study period. However, within all groups significant increases (P < 0.05) were observed in a number of respiratory and pulmonary function variables at the end of the 12 week study, such as maximal inspiratory and expiratory pressure, inspiratory power output, forced vital capacity, forced expiratory and inspiratory volume in 1-s, total lung capacity and diffusion capacity of the lung. This study has demonstrated that there are no appreciable differences in terms of respiratory changes between elite swimmers undergoing a competitive ST program and those undergoing respiratory muscle training using the flow-resistive IMT device employed in the present study; as yet, the causal mechanisms involved are undefined.     

Breathing pattern and occlusion pressure during moderate and heavy exercise

We studied changes in breathing pattern and mouth occlusion pressure (P0.1) in 11 healthy subjects performing graded steady-state exercise on a cycle ergometer up to the maximal load sustainable for 4 min. With increasing work intensity both the tidal volume (VT) and end-inspiratory volume relations to inspiratory (TI) and expiratory (TE) durations were linear in the moderate work load range; in the high load range VT and end-inspiratory volume tended to plateau with further decreases in TI and TE. The ratio of TI to total breath duration (TI/Ttot) increased with work intensity. Intraindividual coefficients of variation for VT, breathing frequency (f), mean inspiratory flow (VT/TI), and other respiratory variables decreased with increasing work intensity, indicating that breath-to-breath variations in breathing pattern became smaller as the level of ventilation increased. P0.1 rose with VT/TI as a power function with an exponent averaging 1.5 (range 1.3-1.9), indicating that the ratio P0.1/(VT/TI), an index of respiratory system impedance, increased with VT/TI and work intensity. We conclude that in moderate and heavy exercise the work of inspiration at a given ventilation is reduced because of the increase in TI/Ttot, the impedance of the respiratory system increases with work intensity because of both an increase in f and a flow-dependent rise in airway resistance, and the neuromuscular inspiratory activity is reflexly augmented because of internal flow-resistive loading.     

Respiratory mechanics during exercise in endurance-trained men and women

The purpose of this study was to compare the mechanics of breathing including the measurement of expiratory flow limitation, end-expiratory lung volume, end-inspiratory lung volume, and the work of breathing in endurance-trained men ( n = 8) and women ( n = 10) during cycle exercise. Expiratory flow limitation was assessed by applying a negative expiratory pressure at the mouth. End-expiratory lung volume and end-inspiratory lung volume were determined by having subjects perform inspiratory capacity manoeuvres. Transpulmonary pressure, taken as the difference between oesophageal and airway opening pressure, was plotted against volume and integrated to determine the work of breathing. Expiratory flow limitation occurred in nine females (90%) and three males (43%) during the final stage of exercise. Females had a higher relative end-expiratory lung volume (42 ± 8 versus 35 ± 5% forced vital capacity (FVC)) and end-inspiratory lung volume (88 ± 5 versus 82 ± 7% FVC) compared to males at maximal exercise ( P < 0.05). Women also had a higher work of breathing compared to men across a range of ventilations. On average, women had a work of breathing that was twice that of men at ventilations above 90 l min⁻¹. These data suggest that expiratory flow limitation may be more common in females and that they experience greater relative increases in end-expiratory lung volume and end-inspiratory lung volume at maximal exercise compared to males. The higher work of breathing in women is probably attributed to their smaller lung volumes and smaller diameter airways. Collectively, these findings suggest that women utilize a greater majority of their ventilatory reserve compared to men and this is associated with a higher cost of breathing.     

不同工种石棉肺患者CT肺功能成像指标的差异性研究

目的 采用多层螺旋CT肺功能成像技术评价不同工种石棉肺患者的肺功能指标改变及特点.方法 将30例石棉肺患者按工种分为压型组、梳纺组和原棉组,每组10例.分别于受试者深吸气末和深呼气末屏气行全肺扫描,测定肺容积指标(最大吸气与呼气末肺容积、肺容积差、肺容积比)、平均肺密度指标(吸气与呼气末平均肺密度、肺密度差、肺密度比)和小气道指标(吸气与呼气末壁厚直径比率、吸气末支气管壁面积百分比).结果 压型组、梳纺组和原棉组在性别、年龄、接触史、分期(Ⅰ期)方面差异均无统计学意义(均P＞0.05).肺容积、平均肺密度和小气道指标中,3组间呼气末平均肺密度、呼气末左肺平均肺密度、呼气末右肺平均肺密度、呼气末与吸气末平均肺密度比、吸气末壁厚直径比率、吸气末支气管壁面积百分比和呼气末壁厚直径比率差异均具有统计学意义(均P＜0.05);进一步两两比较发现,梳纺组的上述指标分别与原棉组和压型组比较,差异亦均具有统计学意义(均P＜0.05),而原棉组和压型组间差异均无统计学意义(均P＞0.05);3组间其余指标差异均无统计学意义(均P＞0.05).结论 与压型组和原棉组比较,梳纺组石棉肺患者的肺气肿及小气道壁和肺泡隔纤维性增厚更为明显,应加强对这部分人的保护.     

Respiratory response to inspiratory resistive load changes in patients with obstructive sleep apnea syndrome

Patients with OSA have many episodes of increased airway resistance because of repeated collapses of upper airways during night. The aim of this work was to evaluate respiratory response during chemical stimulation without and with added inspiratory resistive load (10 cmH2O/L/sec). The studies were performed during quiet breathing with air and during hypercapnic and hypoxic rebreathing tests without and with inspiratory resistive loading in 23 obese (BMI = 34.4 +/- 4.3 kg/m2) patients with OSA and in 10 healthy subjects with similar weight (BMI = 32.4 +/- 4.3 kg/m2). The measurements of respiratory responses (ventilation, mouth occlusion pressure) were performed with the use of computerized equipment. During quiet breathing in response to added load an increase of P0.1 in controls and in OSA patients was observed. During hypercapnic stimulation the ventilatory response with additional load decreased in patients as well as in controls. The slope of mouth occlusion pressure response increased significantly in controls (from 4.40 to 6.83 cmH2O/kPa, p < 0.001) and slightly weaker in OSA patients (from 4.21 to 5.43 cmH2O/kPa, p < 0.05). Although the difference between the slopes was not significant, we found that the absolute increase of P0.1 measured at point 8 kPa of PEtCO2 during loaded breathing was significantly smaller in OSA patients in comparison to controls. (2.1 vs. 10.3 cm H2O; p < 0.001). During hypoxic stimulation occlusion pressure responses were similar in both examined groups. In conclusion we postulate that OSA patients have impaired respiratory compensation of additional inspiratory load, what was demonstrated during hypercapnic rebreathing test.     

Effect of compliant intermediate airways on total respiratory resistance and elastance in mechanical ventilation.

Total respiratory resistance and elastance were estimated off-line in a sample of 60 patients undergoing mechanical ventilation by means of two regression models in order to analyse and understand a possible physiological mechanism determining differences in inspiration and expiration. The first model considered a single value for resistance and elastance over a whole breathing cycle, whereas the second model considered separate values for inspiratory and expiratory resistance and a single value for elastance. Inspiratory resistance was found to be lower than expiratory resistance, and intermediate values were obtained for resistance estimated over the whole breathing cycle. Student's t-test showed a highly significant difference between these resistance estimates, and principal components analysis demonstrated a significant increase in information when both inspiratory and expiratory resistances were used. Minor differences were found between values of elastance calculated with the two approaches. In an attempt to interpret these experimental results, a lung model incorporating the non-linear viscoelastic properties of the intermediate airways was considered. This model suggested that changes in intermediate airway volume play a significant role in breathing mechanics during artificial ventilation and indicated that inspiratory and expiratory resistance could be useful parameters for locating airway obstruction.     

Inspiratory and expiratory lung pressure-volume curve in healthy males and females

Quasistatic lung inspiratory and expiratory pressure-volume curves were obtained in 58 healthy nonsmoking males (mean age +/- SD: 42.8 +/- 15.1 years; range 22.70) and 56 healthy nonsmoking females (mean age +/- SD: 41.4 +/- 15.6 years; range: 21-76). Inspiratory and expiratory lung recoil pressures were measured at fixed percentages of TLC (100, 95, 90, 80, 70, 60 and 50%). In both sexes, inspiratory as well as expiratory lung recoil pressures were found to decrease linearly with aging (p less than 0.01 for all r values). There was no significant difference between males and females. At and above the 70% TLC level, the slopes of the age-related decreases in lung recoil were similar for the inspiratory and expiratory curves. At the 60% TLC level, the decrease in expiratory lung recoil was significantly (p less than 0.01) faster than the decrease in inspiratory lung recoil, presumably reflecting the influence of airway opening on the inspiratory pressure in older subjects. The shape of the expiratory PV curve described by the K index of the exponential model was similar in both sexes and changed with aging, K increasing significantly (p less than 0.01). By contrast, the shape of the inspiratory limb of the PV curve did not vary with aging. Consequently, the shape of the inspiratory PV curve cannot be predicted from the expiratory one and has to be measured directly.     

Effects of breathing exercises on breathing patterns in obese and non-obese subjects.

Chest physiotherapy in connection with abdominal surgery includes different deep-breathing exercises to prevent post-operative pulmonary complications. The therapy is effective in preventing pulmonary complications, especially in high-risk patients such as obese persons. The mechanisms behind the effect is unclear, but part of the effect may be explained by the changes in breathing patterns. The aim of this study was therefore to describe and to analyse the breathing patterns in obese and non-obese subjects during three different breathing techniques frequently used in the treatment of post-operative patients. Twenty-one severely obese [body mass index (BMI) > 40] and 21 non-obese (BMI 19-25) subjects were studied. All persons denied having any lung disease and were non-smokers. The breathing techniques investigated were: deep breaths without any resistance (DB), positive expiratory pressure (PEP) with an airway resistance of approximately +15 cmH2O (1.5 kPa) during expiration, inspiratory resistance positive expiratory pressure (IR-PEP) with a pressure of approximately -10 cmH2O (-1.0 kPa) during inspiration. Expiratory resistance as for PEP. Volume against time was monitored while the subjects were sitting in a body plethysmograph. Variables for volume and flow during the breathing cycle were determined. Tidal volume and alveolar ventilation were highest during DB, and peak inspiratory volume was significantly higher than during PEP and IR-PEP in the group of obese subjects. The breathing cycles were prolonged in all techniques but were most prolonged in PEP and IR-PEP. The functional residual capacity (FRC) was significantly lower during DB than during PEP and IR-PEP in the group of obese subjects. FRC as determined within 2 min of finishing each breathing technique was identical to before the breathing manoeuvres.     

Increases in inspiratory neural drive in response to rapid oscillating airflow braking forces (vibration)

OBJECTIVE: To investigate whether 10 breaths against a vibration stimulus elicits increments of spontaneous and maximal inspiratory mouth pressure (maxMP) and tidal mean inspiratory flow (iV(T)/T(I)) upon stimulus removal. METHODS: Twelve healthy subjects (8 female, 4 male; 22-50 years old), recruited from the University student body, completed 3 maximal inspirations before (pre) and after (post) 10 inspirations against resistive loading with a vibration-type stimulus (VIB; youbreathe, Exoscience Ltd., London, UK), pressure-matched resistive loading (RES) or resting breathing (CON; no load). The trials were presented in a random order. maxMP and involuntary tidal breathing were compared pre and post conditioning. RESULTS: Inspiratory neural drive increased only after VIB as evidenced by increased tidal and maxMP and mean inspiratory flow (iV(T)/T(I); p < 0.05). There was no effect of either resistance or control breathing on maximal maxMP or tidal responses. CONCLUSIONS: Ten conditioning breaths of VIB lead to increased maximal inspiratory mouth pressure and spontaneous mouth pressure and mean inspiratory flow possibly through a common mechanism of increased descending respiratory drive.     

The influence on the breathing pattern in man of moderate levels of continuous positive and negative airway pressure and of positive end-expiratory pressure during air and CO2 inhalation

The purpose of this study was to determine in man the effect on the breathing pattern of continuous positive (CPAP), continuous negative (CNAP) and positive end-expiratory (PEEP) airway pressure during air breathing and CO₂ inhalation. Six subjects were exposed to CPAP, CNAP and PEEP 0.5 kPa, while five subjects were exposed to CPAP and CNAP 0.8 kPa. End-expiratory lung volume increased during CPAP 0.8 kPa and decreased during CNAP 0.8 kPa. CPAP induced more extensive changes in the ventilatory pattern, and the changes in each parameter were larger than observed during CNAP and PEEP at the same pressure level. In contrast to previous reports we found the effect of CO₂ inhalation combined with the effect of pressure breathing to be not stronger than additive. Even moderate CPAP induced alveolar hyperventilation with marked reduction in arterial PCO₂ (PaCO₂) when breathing air. With increasing fraction of CO₂ in the inspiratory gas, the difference in PaCO₂ between CPAP and no CPAP disappeared. PEEP also affected the breathing pattern in that it induced an increase in mean inspiratory flow and mean expiratory flow and a reduction in inspiratory duration. Occurrence of ventilatory pauses depended on whether mouthpiece or facemask was used. CPAP and CNAP did not influence the occurrence of pauses, while PEEP prolonged post-expiratory pauses. We conclude that CPAP, CNAP and PEEP induce active ventilatory responses in man and that strong mechanisms are involved during CPAP since PaCO₂ is markedly reduced.     

Hyperventilation with He-O2 breathing is not decreased by superimposed external resistance

The purpose of this study was to determine the effect of imposed external resistance on the ventilatory response to He-O(2) breathing during peak exercise. To accomplish this purpose, separate inspiratory and expiratory external resistances were applied to offset for the decrease in intrapulmonary airway resistance with He-O(2) breathing. Seven men and three women (69+/-3 years, mean+/-S.D.) with normal pulmonary function performed graded cycle ergometry to exhaustion breathing room air, He-O(2) (79% He, 21% O(2)), He-O(2) with imposed expiratory resistance, and He-O(2) with imposed inspiratory resistance. Ventilation (VE), lung mechanics, and PET(CO(2)) were measured during each 1 min increment in work rate and were analyzed by one-way ANOVA for repeated measures at rest, ventilatory threshold (VTh), and peak exercise. In response, VE was increased and PET(CO(2)) was decreased at VTh (P<0.01) and peak exercise (P<0.01) whenever breathing He-O(2). Thus, VE was increased during exercise above VTh with He-O(2) breathing regardless of increases in inspiratory or expiratory external resistance. In conclusion, these data suggest that inspiratory resistive unloading is no more important than expiratory resistive unloading to the increase in VE with He-O(2) breathing during heavy and peak exercise.     

Effects of naloxone on the control of breathing in children with chronic obstructive pulmonary disease

The effect of naloxone on occlusion pressure (P0.1), the pattern of breathing and the expiratory flows during spontaneous ventilation was studied in 16 children with chronic obstructive pulmonary disease under control conditions, after isotonic saline injection and 5 (N5) and 25 (N25) min after i.v. injection of naloxone (2 micrograms X kg-1). At N5, no change was observed in tidal volume normalized for body weight (VTBW), inspiratory time (TI), respiratory frequency (f), mean inspiratory flow (VTBW/TI) and the ratio of TI and total duration of the respiratory cycle (TI/TT). P0.1 decreased significantly (p less than 0.001) at N5 and returned to control values at N25. The decrease in P0.1 without any change in the breathing pattern suggests that naloxone has an effect on respiratory mechanics. Indeed, at N5, the expiratory flows generated at 25% of VT, measured on the flow-volume curves during spontaneous ventilation, increased significantly when compared to control values. Moreover, the decrease of P0.1 after naloxone was found to be correlated to the reduction of dynamic lung compliance (CLdyn) (p less than 0.02). It is speculated that peripheral airway obstruction, as reflected by the decrease in CLdyn, might be a triggering factor for the release of endorphins. The bronchodilation observed after naloxone could then be due to naloxone's antagonistic effect on endorphin-induced bronchoconstriction.     

CT肺功能指标判断评价石棉肺患者呼吸功能的研究

目的 采用多层螺旋CT肺功能成像技术评价石棉肺患者的呼吸功能障碍程度和肺功能指标的改变及特点.方法 61例石棉肺患者与30名健康者根据用力肺活量和第1秒用力肺活量分为肺呼吸功能正常组、轻度损伤组、中重度损伤组.对每个受检者分别在深吸气末和深呼气末屏住气行全肺扫描,对肺容积、肺密度、小气道指标进行测定.结果 肺呼吸功能正常组、轻度损伤组、中重度损伤组的各项肺容积指标(吸气与呼气末肺容积、容积差、容积比)差异具有统计学意义(均P＜0.05);各项平均肺密度指标(吸气与呼气末平均肺密度、肺密度差、肺密度比)差异具有统计学意义(均P＜0.05);各项小气道指标(吸气与呼气末壁厚直径比率、支气管壁面积率)差异具有统计学意义(均P＜0.05).结论 CT肺功能成像技术可以用来评价石棉肺患者的呼吸功能障碍程度.随着石棉肺患者肺呼吸功能障碍的发展,其肺总量降低,双肺的残气量逐渐增多,肺气肿逐渐加重,小气道壁和肺泡隔纤维性肥厚逐渐增厚.     

Anatomical model of the human trunk for analysis of respiratory muscles mechanics

A realistic two-dimensional (2D) model of the human trunk was developed for quantitative analysis of the relative contribution to breathing mechanics of seven groups of respiratory muscles. Along with noninvasive measurements of electromyography (EMG) signals from respiratory muscles near the skin surface, it provides predictions for the forces generated by inner respiratory muscles as well as the instantaneous work of each muscle. The results revealed that inspiratory muscles reach their maximal force towards the end of inspiration, while expiratory muscles reach their maximal force at mid-expiration. Inspiratory muscles contributed to the work of breathing even at low efforts, while that of the expiratory muscles was observed only at relatively high efforts. The study clearly showed that the diaphragm muscle generates forces, which are of the same order as those generated by other inspiratory muscles, but performed 60-80% of the inspiratory work. The contribution of the external intercostal muscle to inspiration was not negligible, especially at high breathing efforts.     

Impaired exercise ventilatory mechanics with the self-contained breathing apparatus are improved with heliox

The effect of the self-contained breathing apparatus (SCBA) with compressed air (BA-A) on ventilatory mechanics, work of breathing (WOB), pulmonary function, and respiratory muscle fatigue, was compared with that of a low resistance breathing valve (LRV). Further, the effect of unloading the respiratory muscles with heliox with the SCBA (BA-H) was compared with BA-A and LRV. Twelve men completed three randomized exercise trials on separate days, each consisting of three 10 min bouts of stepping exercise (Bouts 1, 2, and 3) separated by a 5 min recovery. Subjects wore firefighter protective equipment including the SCBA. At rest, FEV₁ and peak expiratory flow rates were lower with BA-A than with LRV, but were higher with BA-H than either with BA-A or LRV. After Bout 3, expiratory reserve volume, expiratory resistive WOB, and inspiratory elastic WOB were increased in BA-A compared to LRV but these were lower with BA-H compared to BA-A. After Bout 3, maximal inspiratory and expiratory pressures were reduced with BA-A, but not with LRV or BA-H. In summary, we found that the SCBA reduced resting pulmonary function, and increased expiratory reserve volume, work of breathing, and respiratory muscle fatigue during stepping exercise, and these changes can be reduced with the use of heliox.     

Occlusion pressure and breathing pattern in children with chronic obstructive pulmonary disease

The control of breathing at rest was studied in 30 children (3 to 17 years old) with chronic obstructive pulmonary disease (COPD). Five of them were tested several times during the follow-up of the COPD. Breathing pattern was evaluated and mouth occlusion pressure (PO.1) was measured. Results in COPD children were compared to previously reported values in healthy controls. PO.1 was significantly increased. In 11 children breathing O2, PO.1 decreased but remained at higher levels than predicted. However, the decrease in PO.1 in COPD was not significantly greater than in healthy children. These results may be explained by the relative mild hypoxemia in those children. The increase in PO.1 was significantly correlated with the increase in lung resistance (p less than 0.02) and with the decrease in dynamic lung compliance (p less than 0.01). Most of the COPD children were normocapnic. However, modifications in the breathing pattern were observed. The inspiratory time (TI) was significantly shortened, the expiratory time was prolonged and the TI over the total duration of the respiratory cycle was lowered. The respiratory frequency was unchanged. The tidal volume, normalized for body weight (VTBW), was increased. The mean inspiratory flow (VTBW/TI) was significantly augmented, but not as much as PO.1: in consequence, the effective inspiratory impedance was higher than predicted. Thus, as adults, COPD children had a greater inspiratory neural drive. In contrast to normocapnic COPD adults, they had a modified respiratory timing.     

Differences in mouth occlusion pressure and breathing pattern between arm and leg incremental exercise

The aim of the study was to compare breathing pattern, mouth occlusion pressure, mean inspiratory flow and the ratio of mouth occlusion pressure to mean inspiratory flow at the same power output and carbon dioxide output during arm and leg incremental exercise. Mouth occlusion pressure was used as an index of inspiratory neuromuscular activity and its ratio to mean inspiratory flow as an index of the ‘effective’ impedance of the respiratory system. Eight normal subjects performed two incremental exercise tests, one with arms, the other with legs, on different weeks and in randomized order, and on two identical cycle ergometers. The power output was increased by steps of 25 W for arms and 50 W for legs every 4 min until exhaustion. At the same power output, oxygen consumption, carbon dioxide output, ventilation, mean inspiratory flow, mouth occlusion pressure, ‘effective’ impedance (P<0.001) and respiratory frequency (P<0.01) were higher during arm exercise than during leg exercise, whereas inspiratory time (P<0.05) and expiratory time (P<0.01) were lower. At the same carbon dioxide output, mouth occlusion pressure, ventilation, ‘effective’ impedance (P<0.001) and respiratory frequency (P<0.01) were higher and expiratory time (P<0.05) was lower during arm exercise. In conclusion, the higher inspiratory neuromuscular activity and impedance of the respiratory system during arm exercise and the differences observed in ventilation and breathing pattern at equal carbon dioxide output seem related to the differences in exercising muscle afferents and the presence of an increased load due to contraction of rib cage muscles to stabilize posture.