Department of Medicine, McGill University, Montreal, Quebec, Canada; Institut national de sante publique du Quebec (INSPQ), Montreal, Quebec, Canada.
Department of Medicine, McGill University, Montreal, Quebec, Canada; Division of Clinical Epidemiology, McGill University Health Centre, Montreal, Quebec, Canada.
Environ Res. 2016 Jul;148:207-247. doi: 10.1016/j.envres.2016.03.013. Epub 2016 Apr 14.
Dysfunction of the autonomic nervous system is one of the postulated pathways linking short-term exposure to air pollution to adverse cardiovascular outcomes. A hypothesis is that exposure to air pollution decreases heart rate variability, a recognized independent predictor of poorer cardiovascular prognosis.
We conducted a structured review of panel studies published between 1946 and July 2015 of the association between ambient air pollution and parameters of heart rate variability reflecting autonomic nervous function. We focused on exposure to mass concentrations of fine particles (PM2.5), nitrogen dioxide (NO2), and ozone (O3), and four commonly used indices of heart rate variability (HRV): standard deviation of all normal-to-normal intervals (SDNN); root mean square of successive differences in adjacent normal-to-normal intervals (RMSSD); high frequency power (HF); and low frequency power (LF). We searched bibliographic databases and references of identified articles and abstracted characteristics of their design and conduct, and synthesized the quantitative findings in graphic form according to health condition of the study population and the functional form of the HRV indices used in the regression analyses.
A total of 33 panel studies were included: 31, 12, and 13 studies were used to investigate ambient exposure to PM2.5, NO2 and O3, respectively. We found substantial variation across studies in terms of design characteristics and statistical methodologies, and we identified some studies that may have had methodological and statistical issues. Because many panel studies were not comparable to each other, meta-analyses were not generally possible, although we were able to pool the results obtained amongst older adults who had cardiovascular disease for the 24-h average concentrations of PM2.5 prior to the heart rate variability measurements. In studies of PM2.5 among older adults with cardiovascular disease, logarithmic transformations of the HRV indices were used in ten studies. Negative associations across all HRV indices were found in 60-86% of these studies for periods of exposures ranging from 5-min to 5-days. The pooled percent changes for an increase of 10μg/m(3) in the 24-h prior to the measurements of HRV were: -2.11% for SDNN (95% confidence interval (95%CI): -4.00, -0.23%), -3.29% for RMSSD (95%CI: -6.32, -0.25%), -4.76% for LF (95%CI: -12.10, 2.58%), and -1.74% for HF (95%CI: -7.79, 4.31%). No transformations were used in seven studies of PM2.5 among older adults with cardiovascular disease, and we found for absolute differences pooled changes in the HRV indices, for an increase of 10μg/m(3), of -0.31ms for SDNN (95%CI: -1.02, 0.41ms) and -1.22ms for RMSSD (95%CI: -2.37; -0.07ms). For gaseous pollutants, negative associations over periods of exposure ranging from 5-min or to 5-days prior to the heart rate variability measurements were reported in 71-83% of studies of NO2 and 57-100% of studies of O3, depending of the indices of heart rate variability. However, many of these studies had statistical or methodological issues, and in the few studies without these issues the confidence intervals were relatively wide and mostly included the null.
We were not persuaded by the results that there was an association between PM2.5 and any of the four indices of heart rate variability. For NO2 and O3 the number of high-quality studies was insufficient to draw any definite conclusions. Further panel studies with improved design and methodologies are needed to help establish or refute an association between ambient exposure to air pollution and heart rate variability.
自主神经系统功能障碍是将短期暴露于空气污染与不良心血管结局联系起来的一种假设途径。一种假设是,暴露于空气污染会降低心率变异性,这是心血管预后较差的公认独立预测指标。
我们对 1946 年至 2015 年 7 月期间发表的关于环境空气污染与反映自主神经功能的心率变异性参数之间关联的面板研究进行了系统综述。我们专注于细颗粒物(PM2.5)、二氧化氮(NO2)和臭氧(O3)的质量浓度以及心率变异性的四个常用指标(HRV)的暴露:所有正常到正常间隔的标准差(SDNN);相邻正常到正常间隔的均方根差异(RMSSD);高频功率(HF);低频功率(LF)。我们搜索了文献数据库和已确定文章的参考文献,并提取了其设计和实施的特征,并根据研究人群的健康状况和回归分析中使用的 HRV 指数的功能形式,以图形形式综合了定量发现。
共纳入 33 项面板研究:分别有 31、12 和 13 项研究用于调查 PM2.5、NO2 和 O3 的环境暴露。我们发现,在设计特征和统计方法学方面,研究之间存在很大差异,并且我们确定了一些可能存在方法学和统计学问题的研究。由于许多面板研究彼此之间不可比,因此通常无法进行荟萃分析,尽管我们能够汇集在心血管疾病老年人中进行的 PM2.5 24 小时平均浓度的结果,用于 HRV 测量之前。在心血管疾病老年人的 PM2.5 研究中,在 10 项研究中使用了 HRV 指数的对数变换。在这些研究中,在 5 分钟至 5 天的暴露期间,所有 HRV 指数均发现了 60-86%的负面关联。在 HRV 测量之前的 24 小时内,PM2.5 浓度增加 10μg/m3 时,各项指标的百分比变化为:SDNN 减少 2.11%(95%置信区间[95%CI]:-4.00,-0.23%),RMSSD 减少 3.29%(95%CI:-6.32,-0.25%),LF 减少 4.76%(95%CI:-12.10,2.58%),HF 减少 1.74%(95%CI:-7.79,4.31%)。在心血管疾病老年人的 PM2.5 7 项研究中未使用任何变换,我们发现 HRV 指数的绝对差异,PM2.5 浓度增加 10μg/m3 时,SDNN 减少 0.31ms(95%CI:-1.02,0.41ms)和 RMSSD 减少 1.22ms(95%CI:-2.37;-0.07ms)。对于气态污染物,在 HRV 测量之前的 5 分钟或 5 天的暴露期内,报告了与 NO2 和 O3 的研究中分别有 71-83%和 57-100%的研究中存在负面关联,具体取决于心率变异性指数。然而,其中许多研究存在统计学或方法学问题,在没有这些问题的少数研究中,置信区间相对较宽,大多数包含零假设。
我们对 PM2.5 与四个心率变异性指数中的任何一个之间存在关联的结果均不满意。对于 NO2 和 O3,高质量研究的数量不足以得出明确的结论。需要进一步开展具有改进设计和方法学的面板研究,以帮助确定或反驳环境空气污染与心率变异性之间的关联。
