Respiratory sinus arrhythmia is associated with efficiency of pulmonary gas exchange in healthy humans

Respiratory sinus arrhythmia (RSA) may be associated with improved efficiency of pulmonary gas exchange by matching ventilation to perfusion within each respiratory cycle. Respiration rate, tidal volume, minute ventilation (.VE), exhaled carbon dioxide (.VCO(2)), oxygen consumption (.VO(2)), and heart rate were measured in 10 healthy human volunteers during paced breathing to test the hypothesis that RSA contributes to pulmonary gas exchange efficiency. Cross-spectral analysis of heart rate and respiration was computed to calculate RSA and the coherence and phase between these variables. Pulmonary gas exchange efficiency was measured as the average ventilatory equivalent of CO(2) (.VE/.VCO(2)) and O(2) (.VE/.VO(2)). Across subjects and paced breathing periods, RSA was significantly associated with CO(2) (partial r = -0.53, P = 0.002) and O(2) (partial r = -0.49, P = 0.005) exchange efficiency after controlling for the effects of age, respiration rate, tidal volume, and average heart rate. Phase between heart rate and respiration was significantly associated with CO(2) exchange efficiency (partial r = 0.40, P = 0.03). These results are consistent with previous studies and further support the theory that RSA may improve the efficiency of pulmonary gas exchange.     

Naloxone-induced enhancement of carbon dioxide stimulated respiration

In unanesthetized rats, naloxone (5 mg/kg, s.c.) produced an increase in both respiratory frequency and tidal volume as compared to saline administered animals. Maximal respiratory stimulation was observed within 5 minutes after naloxone injection and duration of the response was greater than 30 minutes. Exposure to different atmospheres of carbon dioxide potentiated the increase in ventilation in a step-wise manner as the carbon dioxide concentration was increased. Pretreatment with low doses of morphine sulfate (2 mg/kg daily for 2 days) or naloxone HCl (5 mg/kg daily for 5 days) enhanced respiratory stimulation induced by naloxone. It was concluded that naloxone increases the sensitivity of central ventilatory response to carbon dioxide as a result of displacement of endogenous endorphins from central opioid receptors.     

Long-term facilitation of ventilation and genioglossus muscle activity is evident in the presence of elevated levels of carbon dioxide in awake humans

We hypothesized that long-term facilitation (LTF) of minute ventilation and peak genioglossus muscle activity manifests itself in awake healthy humans when carbon dioxide is sustained at elevated levels. Eleven subjects completed two trials. During trial 1, baseline carbon dioxide levels were maintained during and after exposure to eight 4-min episodes of hypoxia. During trial 2, carbon dioxide was sustained 5 mmHg above baseline levels during exposure to episodic hypoxia. Seven subjects were exposed to sustained elevated levels of carbon dioxide in the absence of episodic hypoxia, which served as a control experiment. Minute ventilation was measured during trial 1, trial 2, and the control experiment. Peak genioglossus muscle activity was measured during trial 2. Minute ventilation during the recovery period of trial 1 was similar to baseline (9.3 +/- 0.5 vs. 9.2 +/- 0.7 l/min). Likewise, minute ventilation remained unchanged during the control experiment (beginning vs. end of control experiment, 14.4 +/- 1.7 vs. 14.7 +/- 1.4 l/min). In contrast, minute ventilation and peak genioglossus muscle activity during the recovery period of trial 2 was greater than baseline (minute ventilation: 28.4 +/- 1.7 vs. 19.6 +/- 1.0 l/min, P < 0.001; peak genioglossus activity: 1.6 +/- 0.3 vs. 1.0 fraction of baseline, P < 0.001). We conclude that exposure to episodic hypoxia is necessary to induce LTF of minute ventilation and peak genioglossus muscle activity and that LTF is only evident in awake humans in the presence of sustained elevated levels of carbon dioxide.     

Evaluation of methodological and biological influences on the collection and composition of exhaled breath condensate

The purpose of this inter-species comparison (calves and pigs) was to identify methodological and biological influences on the collection and composition of exhaled breath condensate (EBC). A total of 352 EBC samples were collected, whilst variables of ventilation were registered in parallel. Partial pressure of carbon dioxide (pCO₂) and pH were analysed in non-degassed EBC samples. The concentration of total protein in EBC was measured colorimetrically. In both species, lung function was evaluated before and after EBC collection. Statistical analyses were performed to study the effect of EBC collection on lung function and to identify the influence of ventilatory variables on the collection and composition of EBC. Collection of EBC did not affect lung function. Despite the volume of EBC collected per unit time being primarily dependent on ventilation per unit time, species-specific conditions during the EBC collection process resulted in different dependences of EBC collection from other variables of ventilation (i.e. maximal airflow during expiration or expired tidal volume kg^-1 body weight). The concentration of protein ml^-1 EBC increased with the expired volume per min and with peak expiratory flow. Although the pCO₂ in fresh EBC was significantly negatively dependent on the duration of collection, comparable pHs (5.6 - 6.2) were measured in EBC of both calves and pigs. The obtained data may help one standardize EBC collection in different species.     

Effect of verapamil on ventilation and chemical control of breathing in anesthetized rats

The calcium channel blocker, verapamil (0.1-1.0 mg/kg, i.v.) was administered to anesthetized rats to determine its effects on ventilation and on ventilatory responses to hypoxia and CO2. Verapamil produced a dose-dependent increase in tidal volume (VT) and a decrease in respiration rate (f). The bradypnea due to verapamil was characterized by an increase in expiratory duration (TE) and no change of inspiratory duration (TI). Verapamil produced similar changes in VT and f in vagotomized rats. The increase in respiration rate and minute volume due to hypoxia were inhibited by verapamil (0.5 and 1.0 mg/kg) but the increase in tidal volume due to hypoxia was depressed only with the 1.0 mg/kg dose. On the other hand, the increase in VT due to breathing CO2 was not changed by verapamil (0.1-1.0 mg/kg), but depression of the respiratory frequency response to CO2 occurred with 1.0 mg/kg of verapamil. These results indicate that verapamil produced slow, deep breathing and these responses were not mediated by vagal mechanisms. Ventilatory responses to hypoxia were depressed by verapamil. However, since the calcium blocker demonstrated no effect on the VT-CO2 relationship, verapamil did not change ventilatory chemosensitivity to CO2. The data also suggest that mechanisms governing the control of respiratory frequency are more sensitive to verapamil than tidal volume responses.     

Effects of expiratory threshold loading during steady-state exercise.

Increases in functional residual capacity (FRC) decrease inspiratory muscle efficiency; the present experiments were designed to determine the effect of FRC change on the ventilatory response to exercise. Six well-trained adults were exposed to expiratory threshold loads (ETL) ranging from 5 to 40 cmH2O during steady-state exercise on a bicycle ergometer at 40-95% VO2max. Inspiratory capacity (IC) was measured and changes of IC interpreted as changes of FRC. ETL did not consistently limit exercise performance. At heavy work (greater than 92% VO2max) minute ventilation decreased with increasing ETL; at moderate work (less than 58% VO2max) it did not. Decreases in ventilation were due to decreases in respiratory frequency with prolongation of the duration of expiration being the most consistent change in breathing pattern. At moderate work levels, FRC increased with ETL; at maximum work it did not. Changes in FRC were dictated by constancy of tidal volume and a fixed maximum end-inspiratory volume of 80-90% of the inspiratory capacity. When tidal volume was such that end-inspiratory volume was less than this value, FRC increased with ETL. Mouth pressure measured during the first 0-1 s of inspiratory effort against an occluded airway (P0-1) was increased by ETL equals 30 cmH2O, in spite of the fact that ventilation was decreased. We concluded that changes in FRC due to ETL had no effect on the ventilatory response to exercise and that changes in P0-1 induced by ETL did not reflect changes of inspiratory drive so much as changes of the pattern of inspiration.     

Total work rate of breathing optimization in CO-2 inhalation and exercise.

The hypothesis that respiratory frequency and the relative durations of inspiration and expiration are regulated according to a total cycle work rate minimization criterion was explored. Effects of negative work performed by the respiratory muscles and dead space variation as a function of tidal volume were included in a formulation which yielded a theoretically predictable optimal frequency and relative duration of inspiration and expiration at all levels of ventilation. Predicted cycle characteristics based on measured mechanical parameters were compared with data taken during CO-2 inhalation (3 and 5%) and moderate exercise (MRR = 3 and 6) in three normal human subjects. No major difference in breathing pattern was observed between CO-2 inhalation and exercise. Results suggest that conditions for minimization of total cycle work rate are achieved asympototically as the level of ventilation rises above the resting level. At rest and at low levels of hyperpnea complete work rate optimization is not achieved.     

Evaluation of methodological and biological influences on the collection and composition of exhaled breath condensate

Abstract

The purpose of this inter-species comparison (calves and pigs) was to identify methodological and biological influences on the collection and composition of exhaled breath condensate (EBC). A total of 352 EBC samples were collected, whilst variables of ventilation were registered in parallel. Partial pressure of carbon dioxide (pCO₂) and pH were analysed in non-degassed EBC samples. The concentration of total protein in EBC was measured colorimetrically. In both species, lung function was evaluated before and after EBC collection. Statistical analyses were performed to study the effect of EBC collection on lung function and to identify the influence of ventilatory variables on the collection and composition of EBC. Collection of EBC did not affect lung function. Despite the volume of EBC collected per unit time being primarily dependent on ventilation per unit time, species-specific conditions during the EBC collection process resulted in different dependences of EBC collection from other variables of ventilation (i.e. maximal airflow during expiration or expired tidal volume kg^?1 body weight). The concentration of protein ml^?1 EBC increased with the expired volume per min and with peak expiratory flow. Although the pCO₂ in fresh EBC was significantly negatively dependent on the duration of collection, comparable pHs (5.6???6.2) were measured in EBC of both calves and pigs. The obtained data may help one standardize EBC collection in different species.     

Central effects of neuropeptides on ventilation in the rat

We have examined the effects of centrally applied neuropeptides on ventilation (respiratory rate, tidal volume, and minute ventilation) in urethane-anesthetized rats. TRH caused an increase in respiratory rate, a decrease in tidal volume, but an increase in net minute ventilation. One TRH metabolite, acid TRH, caused similar changes, but no effect was observed from the other TRH metabolite, cHis-Pro. Both bombesin and calcitonin caused increases in minute ventilation due to increases in respiratory rate and tidal volume. Additionally, bombesin induced periodic sighing respirations at rates up to 15/minute which was observed with no other neuropeptide. Substance P, somatostatin, and neurotensin had no effect upon ventilation variables.     

Pattern of breathing in the rat.

The basic ventilation values - tidal volume (VT), breathing frequency (f), minute ventilation (VE) and the duration of inspiration (TI) and expiration (TE) -- were determined in adult male rats. The range of these values is given and the pattern of breathing is defined as the relationship between VE and VT, which in the rat is linear throughout its entire range. The role of TI and TE in changing f in the rat were evaluated. The breathing pattern of the rat was compared with data for the rabbit and man, using percentual expression of the basic values. A shift of the breathing pattern to higher f values was observed in rats with experimental lung diseases. In these rats, the inhalation of 100% O2 shifted the pattern of breathing markedly to lower VE values, though not to values comparable with the controls. Bilateral cervical vagotomy was followed by a pronouced decrease in f, an increase in VT and T1 persisted even after vagotomy, however; it can be assumed that this relationship is effected either by means of receptors in the chest muscles, or by the direct action of CO2 which is used to stimulate breathing, on the bulbopontine pacemaker.     

Increased vasoconstriction predisposes to hyperpnea and postural faint

Our prior studies indicated that postural fainting relates to splanchnic hypervolemia and thoracic hypovolemia during orthostasis. We hypothesized that thoracic hypovolemia causes excessive sympathetic activation, increased respiratory tidal volume, and fainting involving the pulmonary stretch reflex. We studied 18 patients 13-21 yr old, 11 who fainted within 10 min of upright tilt (fainters) and 7 healthy control subjects. We measured continuous blood pressure and heart rate, respiration by inductance plethysmography, end-tidal carbon dioxide (ET(CO(2))) by capnography, and regional blood flows and blood volumes using impedance plethysmography, and we calculated arterial resistance with patients supine and during 70 degrees upright tilt. Splanchnic resistance decreased until faint in fainters (44 +/- 8 to 21 +/- 2 mmHg.l(-1).min(-1)) but increased in control subjects (47 +/- 5 to 53 +/- 4 mmHg.l(-1).min(-1)). Percent change in splanchnic blood volume increased (7.5 +/- 1.0 vs. 3.0 +/- 11.5%, P < 0.05) after the onset of tilt. Upright tilt initially significantly increased thoracic, pelvic, and leg resistance in fainters, which subsequently decreased until faint. In fainters but not control subjects, normalized tidal volume (1 +/- 0.1 to 2.6 +/- 0.2, P < 0.05) and normalized minute ventilation increased throughout tilt (1 +/- 0.2 to 2.1 +/- 0.5, P < 0.05), whereas respiratory rate decreased (19 +/- 1 to 15 +/- 1 breaths/min, P < 0.05). Maximum tidal volume occurred just before fainting. The increase in minute ventilation was inversely proportionate to the decrease in ET(CO(2)). Our data suggest that excessive splanchnic pooling and thoracic hypovolemia result in increased peripheral resistance and hyperpnea in simple postural faint. Hyperpnea and pulmonary stretch may contribute to the sympathoinhibition that occurs at the time of faint.     

电刺激兔大脑皮层对呼吸频率和幅度的影响

本工作用家兔３８只,麻醉并切断双侧迷走神经和三叉神经上颌支,观察连续刺激大脑皮层不同区域对呼吸的影响。结果：１．适度的电刺激：（１）对肢体运动区（Ｌ）,使吸气加强,呼吸频率（ＲＦ）和潮气量（ＴＶ）均显著增加;（２）对颜面运动区（Ｆ）,使ＲＦ显著增加,但呼气和吸气均被抑制,ＴＶ显著降低;（３）对咀嚼运动区（Ｍ）,出现间歇性吸气或呼气加强,ＲＦ和ＴＶ均明显增加;（４）对眶后区（ＰＯ）,使ＲＦ和ＴＶ均显     

High tidal volume ventilation induces NOS2 and impairs cAMP- dependent air space fluid clearance

Tidal volume reduction during mechanical ventilation reduces mortality in patients with acute lung injury and the acute respiratory distress syndrome. To determine the mechanisms underlying the protective effect of low tidal volume ventilation, we studied the time course and reversibility of ventilator-induced changes in permeability and distal air space edema fluid clearance in a rat model of ventilator-induced lung injury. Anesthetized rats were ventilated with a high tidal volume (30 ml/kg) or with a high tidal volume followed by ventilation with a low tidal volume of 6 ml/kg. Endothelial and epithelial protein permeability were significantly increased after high tidal volume ventilation but returned to baseline levels when tidal volume was reduced. The basal distal air space fluid clearance (AFC) rate decreased by 43% (P < 0.05) after 1 h of high tidal volume but returned to the preventilation rate 2 h after tidal volume was reduced. Not all of the effects of high tidal volume ventilation were reversible. The cAMP-dependent AFC rate after 1 h of 30 ml/kg ventilation was significantly reduced and was not restored when tidal volume was reduced. High tidal volume ventilation also increased lung inducible nitric oxide synthase (NOS2) expression and air space total nitrite at 3 h. Inhibition of NOS2 activity preserved cAMP-dependent AFC. Because air space edema fluid inactivates surfactant and reduces ventilated lung volume, the reduction of cAMP-dependent AFC by reactive nitrogen species may be an important mechanism of clinical ventilator-associated lung injury.     

Inflation reflex in the rat.

The Breuer-Hering inflation reflex [BHIR] was elicited in conscious and anaesthetized rats by inflating the lungs with constant pressures of 5--20 cm H2O. The reflex was elicited well in conscious animals, but even with the maximum stimulus [inflation of 20 cm H2O, corresponding to about 4.5-fold the tidal volume] the duration of apnoea did not exceed 4 control respiration cycles. In anaesthetized animals, the same stimulus let to apnoea lasting 180--400 control respiration cycles on the average, according to the type and depth of general anaesthesia. The duration of apnoea in occlusion of the air passages in the expiratory position increased with the depth of anaesthesia, while in occlusion of the air passages at the peak of inspiration it was shortened. Stimulation of chemoreceptors [inhalation of a mixture 4% CO2 in O2 or of 8% O2 in N2] did not influence the elicitability or duration of the BHIR, nor did cooling the rats to 28 degrees C or heating them to 38 degrees C. The mean respiration frequency was 98 c/min in unanaesthetized rats, 96 c/min in urethane anaesthesis and 79--48 c/min in halothane anaesthesia, according to the depth of anaesthesia. Bilateral cervical vagotomy reduced mean respiration frequency to 35.6 c/min in conscious rats and to 31 c/min in urethane-anaesthetized animals. The results indicate the existence of species-related differences between basic regulatory mechanisms in the rat and certain other mammals.     

The effect of carbon dioxide inhalation on phase characteristics of breathing movements in healthy newborn infants

Chest wall distortion (inward motion of the rib cage on inspiration) has been found recently to reduce the tidal volume during active sleep in the neonatal period. To determine some of the factors that relate to the chest wall distortion and the decreased tidal volume seen in active sleep, a quantification of the phase differences between the movements of the chest wall and those of the abdominal wall, and of the relation of their phase differences to tidal volume was performed on data obtained before and during carbon dioxide stimulation in 15 newborn infants sleeping in the prone position. In quiet sleep, the breathing movements were congruent and regular, and the tidal volume and the mean inspiratory flow increased during carbon dioxide stimulation. In active sleep during exposure to carbon dioxide, the chest wall distortion decreased, the breathing movements were incongruent and the degree of the chest wall distortion was negatively correlated with the tidal volume, while the tidal volume and the mean inspiratory flow was increased. Chest wall distortion did not appear in quiet sleep and was decreased in active sleep in spite of increased ventilation during CO2 stimulation. This study favours the idea that chest wall distortion is caused by a well regulated change in neuromuscular activity and not by the strength of diaphragmatic movements overcoming the mechanical stability of the rib cage.     

Ventilatory response to adjuvant arthritis in the rat

This study examined ventilation in rats with arthritis induced by Mycobacterium butyricum. It was found that, 19 days after inoculation, the minute ventilation of arthritic rats breathing air was about two-fold higher than that of control animals. This increase resulted from an increase both in respiratory frequency and in tidal volume. Air-CO2 mixtures continued to stimulate ventilation in arthritic rats, and the minute ventilation of these animals on breathing 5 or 7% CO2 exceeded that of controls. The results are consistent with the hypothesis that arthritic rats hyperventilate and contribute to the validation of adjuvant arthritis as an animal model of chronic pain.     

Effect of lipine, a new antihypoxic agent on some respiratory indices in newborn infants after asphyxia]

Lipine, a new antihypoxic drug, has been studied for its effect on respiration and pulmonary gaseous exchange in 47 newborn children, health and with respiratory distress syndrome stresses (SRD) after perinatal asphyxia. It is shown that lipine inhalations cause a considerable increase in duration of respiratory cycle, decrease of respiration frequency, ratio of ispiration di time, to expiration time, increase of alveolar ventilation volume and decrease of respiratory dead space ventilation volume in all lung ventilation volume in newborns with SRD, to a larger degree pronounced in premature children. A conclusion is made on the positive effect of lipine on the state of respiration function and gaseous exchange in lungs in newborn children with symptoms of SRD.     

Hyperoxic exposure affects the ventilatory response to hypoxia in awake rats

We tested whether hyperbaric O2 (HBO) has an adverse effect on the hypoxic ventilatory drive. Four groups of rats were exposed for 550 min to O2 at 1.67, 1.90, and 2.15 ATA and to air at 1.90 ATA, respectively. Ventilatory parameters (frequency, tidal volume, and minute ventilation) were measured using whole-body plethysmography, before the hyperbaric exposure, immediately after the exposure, and up to 20 days after the exposure. Resting ventilation was not affected after exposure at 1.90 ATA to air or at 1.67 ATA to O2. HBO at 1.90 and 2.15 ATA caused a reduction of frequency and an elevation of tidal volume at different inspired gases: air, 5% CO2 balance O2, 80% O2, and 4.5% O2. However, minute ventilation on the day after the hyperoxic exposure was not different from the control at either air, 5% CO2, or 80% O2 but was markedly attenuated on the first three breaths at 4.5% O2. The hypoxic ventilation decreased to 48 +/- 13 (SD) and 32 + 11% after 1.90 and 2.15 ATA, respectively. The ventilatory parameters recovered in the days after HBO. We conclude that HBO reversibly depresses the hypoxic ventilatory drive, most probably by a direct effect on the carotid O2 chemoreceptors.     

Heliox Allows for Lower Minute Volume Ventilation in an Animal Model of Ventilator-Induced Lung Injury

Background

Helium is a noble gas with a low density, allowing for lower driving pressures and increased carbon dioxide (CO₂) diffusion. Since application of protective ventilation can be limited by the development of hypoxemia or acidosis, we hypothesized that therefore heliox facilitates ventilation in an animal model of ventilator–induced lung injury.

Methods

Sprague-Dawley rats (N=8 per group) were mechanically ventilated with heliox (50% oxygen; 50% helium). Controls received a standard gas mixture (50% oxygen; 50% air). VILI was induced by application of tidal volumes of 15 mL kg^-1; lung protective ventilated animals were ventilated with 6 mL kg^-1. Respiratory parameters were monitored with a pneumotach system. Respiratory rate was adjusted to maintain arterial pCO₂ within 4.5-5.5 kPa, according to hourly drawn arterial blood gases. After 4 hours, bronchoalveolar lavage fluid (BALF) was obtained. Data are mean (SD).

Results

VILI resulted in an increase in BALF protein compared to low tidal ventilation (629 (324) vs. 290 (181) μg mL^-1; p<0.05) and IL-6 levels (640 (8.7) vs. 206 (8.7) pg mL^-1; p<0.05), whereas cell counts did not differ between groups after this short course of mechanical ventilation. Ventilation with heliox resulted in a decrease in mean respiratory minute volume ventilation compared to control (123±0.6 vs. 146±8.9 mL min^-1, P<0.001), due to a decrease in respiratory rate (22 (0.4) vs. 25 (2.1) breaths per minute; p<0.05), while pCO₂ levels and tidal volumes remained unchanged, according to protocol. There was no effect of heliox on inspiratory pressure, while compliance was reduced. In this mild lung injury model, heliox did not exert anti-inflammatory effects.

Conclusions

Heliox allowed for a reduction in respiratory rate and respiratory minute volume during VILI, while maintaining normal acid-base balance. Use of heliox may be a useful approach when protective tidal volume ventilation is limited by the development of severe acidosis.     

Depressed ventilatory reflexes after capsaicin challenge in streptozotocin-treated rats

Diabetic sensory neuropathy is an affliction that decreases sensory perception in a number of organ systems. Although little is known of its pulmonary effects certain diabetic patients have reduced airway reactivity to cold air and elevated cough threshold to irritant inhalation, reflexes reported to be mediated by pulmonary C-fibers. Therefore we studied the effects the selective C-fiber activator capsaicin (0.01% aerosol, 30 s) on variables of ventilation using a whole-body plethysmograph in age-matched rats treated with streptozotocin (STZ) or its vehicle at 6 and 12 weeks after treatment. Body weight increased and plasma glucose and glycosylated hemoglobin were stable in vehicle-treated rats. In STZ-treated rats body weight decreased and plasma glucose and glycosylated hemoglobin increased. Capsaicin challenge decreased tidal volume, respiratory rate and therefore minute ventilation in non-treated and vehicle-treated rats. However capsaicin challenge increased tidal volume thereby altering minute ventilation in STZ-treated rats. Specific airway resistance increased in both groups after capsaicin challenge. Changes in ventilation in response to capsaicin challenge in STZ-treated rats may involve C-fiber sensory neuropathy.