Barbosa Eduardo, García-Manso Juan M, Martín-González Juan M, Sarmiento Samuel, Calderón Francisco J, Da Silva-Grigoletto Marzo E
Universidad de Las Palmas de Gran Canaria, 35017 Las Palmas de Gran Canaria, Spain.
Mil Med. 2010 Jan;175(1):61-4. doi: 10.7205/milmed-d-02-00808.
This study sought to determine the effects of hyperbaric pressure on heart rate modulation, by analyzing potential changes in heart rate variability (HRV). Ten divers were exposed to pressures of 1, 2, 3, and 4 atmospheres absolute (ATA). The test was performed in a hyperbaric chamber. Heart rate (HR) was recorded in supine subjects for 10 minutes per atmosphere. HRV was analyzed in the frequency mode (fast-Fourier transform and continuous wavelet transform). Results confirmed bradycardia as pressure increased. The drop in HR attained statistical significance after 2, 3, and 4 ATA. Signal energy (normalized TP values) rose progressively, becoming significant at 2 ATA. High frequency and low frequency displayed similar behavior in both cases. Although frequency band peaks did not yield clear results, continuous wave transform analysis showed that the frequency spectrum tended to shift into the high-frequency range as pressure increased. In summary, increased pressure prompted increased bradycardia, and HRV shifted into high-frequency range.
本研究旨在通过分析心率变异性(HRV)的潜在变化,确定高压对心率调节的影响。10名潜水员分别暴露于绝对压力为1、2、3和4个大气压(ATA)的环境中。测试在高压舱内进行。在每个大气压下,让仰卧的受试者记录10分钟的心率(HR)。采用频率模式(快速傅里叶变换和连续小波变换)分析HRV。结果证实随着压力增加出现心动过缓。在2、3和4个ATA后,心率下降具有统计学意义。信号能量(归一化TP值)逐渐上升,在2个ATA时变得显著。在这两种情况下,高频和低频表现出相似的行为。尽管频段峰值未得出明确结果,但连续小波变换分析表明,随着压力增加,频谱倾向于向高频范围移动。总之,压力增加促使心动过缓加剧,且HRV向高频范围转变。
