Department of Critical Care Medicine, The Hospital for Sick Children, Toronto, ON, Canada.
Department of Medicine, Technion, Haifa, Israel.
Pediatr Crit Care Med. 2019 Jul;20(7):e333-e341. doi: 10.1097/PCC.0000000000001984.
Physiologic signals are typically measured continuously in the critical care unit, but only recorded at intermittent time intervals in the patient health record. Low frequency data collection may not accurately reflect the variability and complexity of these signals or the patient's clinical state. We aimed to characterize how increasing the temporal window size of observation from seconds to hours modifies the measured variability and complexity of basic vital signs.
Retrospective analysis of signal data acquired between April 1, 2013, and September 30, 2015.
Critical care unit at The Hospital for Sick Children, Toronto.
Seven hundred forty-seven patients less than or equal to 18 years old (63,814,869 data values), within seven diagnostic/surgical groups.
None.
Measures of variability (SD and the absolute differences) and signal complexity (multiscale sample entropy and detrended fluctuation analysis [expressed as the scaling component α]) were calculated for systolic blood pressure, heart rate, and oxygen saturation. The variability of all vital signs increases as the window size increases from seconds to hours at the patient and diagnostic/surgical group level. Significant differences in the magnitude of variability for all time scales within and between groups was demonstrated (p < 0.0001). Variability correlated negatively with patient age for heart rate and oxygen saturation, but positively with systolic blood pressure. Changes in variability and complexity of heart rate and systolic blood pressure from time of admission to discharge were found.
In critically ill children, the temporal variability of physiologic signals supports higher frequency data capture, and this variability should be accounted for in models of patient state estimation.
生理信号通常在重症监护病房连续测量,但仅在患者健康记录中以间歇性时间间隔记录。低频数据采集可能无法准确反映这些信号的可变性和复杂性,也无法反映患者的临床状态。我们旨在描述将观察的时间窗口大小从秒增加到小时如何改变基本生命体征的测量可变性和复杂性。
2013 年 4 月 1 日至 2015 年 9 月 30 日期间采集的信号数据的回顾性分析。
多伦多 SickKids 医院的重症监护病房。
704 名年龄在 18 岁及以下的患者(63,814,869 个数据值),分为七个诊断/手术组。
无。
为收缩压、心率和血氧饱和度计算了变异性(SD 和绝对差异)和信号复杂度(多尺度样本熵和去趋势波动分析[表示为标度分量α])。所有生命体征的变异性随着窗口大小从秒增加到小时,在患者和诊断/手术组水平上均增加。在组内和组间的所有时间尺度上,变异性的幅度都存在显著差异(p < 0.0001)。心率和血氧饱和度的变异性与患者年龄呈负相关,而与收缩压呈正相关。在入院到出院期间,发现心率和收缩压的变异性和复杂性发生了变化。
在危重病儿童中,生理信号的时间变异性支持更高频率的数据采集,并且在患者状态估计模型中应考虑这种变异性。
