Comparison of AutoSet TM and polysomnography for the detection of apnea-hypopnea events

The use of the flow vs time relationship obtained with the nasal prongs of the AutoSet TM (AS) system (diagnosis mode) has been proposed to detect apneas and hypopneas in patients with reasonable nasal patency. Our aim was to compare the accuracy of AS to that of a computerized polysomnographic (PSG) system. The study was conducted on 56 individuals (45 men) with clinical characteristics of obstructive sleep apnea (OSA). Their mean (+/- SD) age was 44.6 +/- 12 years and their body mass index was 31.3 +/- 7 kg/m2. Data were submitted to parametric analysis to determine the agreement between methods and the intraclass correlation coefficient was calculated. The Student t-test and Bland and Altman plots were also used. Twelve patients had an apnea-hypopnea index (AHI) < 10 in bed and 20 had values > 40. The mean (+/- SD) AHI PSG index of 37.6 (28.8) was significantly lower (P = 0.0003) than AHI AS (41.8 (25.3)), but there was a high intraclass correlation coefficient (0.93), with 0.016 variance. For a threshold of AHI of 20, AS showed 73.0 percent accuracy, 97 percent sensitivity and 60 percent specificity, with positive and negative predictive values of 78 percent and 93 percent, respectively. Sensitivity, specificity and negative predictive values increased in parallel to the increase in AHI threshold for detecting OSA. However, when the differences of AHI PSG-AS were plotted against their means, the limits of agreement between the methods (95 percent of the differences) were +13 and -22, showing the discrepancy between the AHI values obtained with PSG and AS. Finally, cubic regression analysis was used to better predict the result of AHI PSG as a function of the method proposed, i.e., AHI AS. We conclude that, despite these differences, AHI measured by AutoSetä can be useful for the assessment of patients with high pre-test clinical probability of OSA, for whom standard PSG is not possible as an initial step in diagnosis.

Assessment of ventilatory neuromuscular drive in patients with obstructive sleep apnea

The presence of abnormalities of the respiratory center in obstructive sleep apnea (OSA) patients and their correlation with polysomnographic data are still a matter of controversy. Moderately obese, sleep-deprived OSA patients presenting daytime hypersomnolence, with normocapnia and no clinical or spirometric evidence of pulmonary disease, were selected. We assessed the ventilatory control and correlated it with polysomnographic data. Ventilatory neuromuscular drive was evaluated in these patients by measuring the ventilatory response (VE) the inspiratory occlusion pressure (P.1) and the ventilatory pattern (VT/TI, TI/TTOT) at rest and during submaximal exercise, breathing room air. These analyses were also performed after inhalation of a hypercapnic mixture of CO2 (deltaP.11/deltaPETCO2, deltaVE/deltaPETCO2). Average rest and exercise ventilatory response (VE: 12.2 and 32.61/min, respectively), inspiratory occlusion pressure (P.1: 1.5 and 4.7 cmH2O, respectively), and ventilatory pattern (VT/TI: 0.42 and 1.09 1/s; TI/TTOT: 0.47 and 0.46 1/s, respectively) were within the normal range. In response to hypercapnia, the values of ventilatory response (deltaVE/deltaPETCO2: 1.51 lmin(-1) mmHg(-1)) and inspiratory occlusion pressure (deltaP.1/deltaPETCO2: 0.22 cmH2O) were normal or slightly reduced in the normocapnic OSA patients. No association or correlation between ventilatory neuromuscular drive and ventilatory pattern, hypersomnolence score and polymnographic data was found; however a significant positive correlation was observed between P.1 and weight. Our results indicate the existence of a group of normocapnic OSA patients who have a normal awake neuromuscular ventilatory drive at rest or during exercise that is partially influenced by obesity.

Mechanisms of hypercapnia in patients with chronic obstructive pulmonary disease (COPD)

A higher ventilatory drive evaluated by the inspiratory occlusion pressure (Poc) and a respiratory pattern characterized by smaller tidal volume (VT) and higher breathing frequency (f) was detected in patients with chronic obstructive pulmonary disease (COPD), in relation to normals. The purpose of this study was to identify the possible mechanisms involved in the development of hypercapnia in those patients, at rest and during exercise. We have studied 11 normocapnic (PaCO2 ( 45 mmHg) and 9 hypercapnic (PaCO2 > 45 mmHg) COPD patients. As expected, no difference in the ventilatory response and neural drive was detected between the two groups. However, the hypercapnic patients have higher values of serum HCO-3 and lower values of PaO2 at rest and values of the ratio dead volume to tidal volume (VD/VT) significantly higher at rest (0.67 vs. 0.55) and during exercise (0.54 vs. 0.38) in relation to normocapnic individuals. There was also a significant positive correlation at rest (r = 0.66*) and during exercise (r = 0.65*; *p < 0.05), between PaCO2 and VD/VT, identifying a decreased alveolar ventilatory efficiency, important in the development of hypercapnia in those patients. when the COPD patients were divided into two distinct groups (PaCO2 ( 40 and ( 50 mmHg), a respiratory pattern characterized by higher f and smaller VT was detected in the hypercapnic group during exercise. In conclusion, a higher VD/VT linked to alterations of the respiratory pattern (lower VT) and to inequalities of ventilation/perfusion (high V/Q areas), seems to explain the hypercapnia of our COPD patients, since the ventilatory response and neural drive were similar in normo and hypercapnic patients.