Cerebrovascular response to arousal from NREM and REM sleep.

STUDY OBJECTIVE: To determine the effect of arousal from sleep on cerebral blood flow velocity (CBFV) in relation to associated ventilatory and systemic hemodynamic changes. PARTICIPANTS: Eleven healthy individuals (6 men, 5 women). MEASUREMENTS: Pulsed Doppler ultrasonography was used to measure CBFV in the middle cerebral artery with simultaneous measurements of sleep state (EEG, EOG, and EMG), ventilation (inductance plethysmography), heart rate (ECG), and arterial pressure (finger plethysmography). Arousals were induced by auditory tones (range: 40-80 dB; duration: 0.5 sec). Cardiovascular responses were examined beat-by-beat for 30 sec before and 30 sec after auditory tones. RESULTS: During NREM sleep, CBFV declined following arousals (-15% +/- 2%; group mean +/- SEM) with a nadir at 9 sec after the auditory tone, followed by a gradual return to baseline. Mean arterial pressure (MAP; +20% +/- 1%) and heart rate (HR; +17% +/- 2%) increased with peaks at 5 and 3 sec after the auditory tone, respectively. Minute ventilation (VE) was increased (+35% +/- 10%) for 2 breaths after the auditory tone. In contrast, during REM sleep, CBFV increased following arousals (+15% +/- 3%) with a peak at 3 sec. MAP (+17% +/- 2%) and HR (+15% +/- 2%) increased during arousals from REM sleep with peaks at 5 and 3 sec post tone. VE increased (+16% +/- 7%) in a smaller, more sustained manner during arousals from REM sleep. CONCLUSIONS: Arousals from NREM sleep transiently reduce CBFV, whereas arousals from REM sleep transiently increase CBFV, despite qualitatively and quantitatively similar increases in MAP, HR, and VE in the two sleep states.

Mechanisms of the cerebrovascular response to apnoea in humans.

We measured ventilation, arterial O2 saturation, end-tidal CO2 (PET,CO2), blood pressure (intra-arterial catheter or photoelectric plethysmograph), and flow velocity in the middle cerebral artery (CFV) (pulsed Doppler ultrasound) in 17 healthy awake subjects while they performed 20 s breath holds under control conditions and during ganglionic blockade (intravenous trimethaphan, 4.4 +/- 1.1 mg min-1 (mean +/- S.D.)). Under control conditions, breath holding caused increases in PET,CO2 (7 +/- 1 mmHg) and in mean arterial pressure (MAP) (15 +/- 2 mmHg). A transient hyperventilation (PET,CO2 -7 +/- 1 mmHg vs. baseline) occurred post-apnoea. CFV increased during apnoeas (by 42 +/- 3 %) and decreased below baseline (by 20 +/- 2 %) during post-apnoea hyperventilation. In the post-apnoea recovery period, CFV returned to baseline in 45 +/- 4 s. The post-apnoea decrease in CFV did not occur when hyperventilation was prevented. During ganglionic blockade, which abolished the increase in MAP, apnoea-induced increases in CFV were partially attenuated (by 26 +/- 2 %). Increases in PET,CO2 and decreases in oxyhaemoglobin saturation (Sa,O2) (by 2 +/- 1 %) during breath holds were identical in the intact and blocked conditions. Ganglionic blockade had no effect on the slope of the CFV response to hypocapnia but it reduced the CFV response to hypercapnia (by 17 +/- 5 %). We attribute this effect to abolition of the hypercapnia-induced increase in MAP. Peak increases in CFV during 20 s Mueller manoeuvres (40 +/- 3 %) were the same as control breath holds, despite a 15 mmHg initial, transient decrease in MAP. Hyperoxia also had no effect on the apnoea-induced increase in CFV (40 +/- 4 %). We conclude that apnoea-induced fluctuations in CFV were caused primarily by increases and decreases in arterial partial pressure of CO2 (Pa,CO2) and that sympathetic nervous system activity was not required for either the initiation or the maintenance of the cerebrovascular response to hyper- and hypocapnia. Increased MAP or other unknown influences of autonomic activation on the cerebral circulation played a smaller but significant role in the apnoea-induced increase in CFV; however, negative intrathoracic pressure and the small amount of oxyhaemoglobin desaturation caused by 20 s apnoea did not affect CFV.