Department of Electrical and Computer Engineering, Georgia Institute of Technology, Atlanta, GA, United States of America.
Physiol Meas. 2017 Nov 30;38(12):2235-2248. doi: 10.1088/1361-6579/aa9772.
Objective and Approach: Sepsis, a dysregulated immune-mediated host response to infection, is the leading cause of morbidity and mortality in critically ill patients. Indices of heart rate variability and complexity (such as entropy) have been proposed as surrogate markers of neuro-immune system dysregulation with diseases such as sepsis. However, these indices only provide an average, one dimensional description of complex neuro-physiological interactions. We propose a novel multiscale network construction and analysis method for multivariate physiological time series, and demonstrate its utility for early prediction of sepsis.
We show that features derived from a multiscale heart rate and blood pressure time series network provide approximately 20% improvement in the area under the receiver operating characteristic (AUROC) for four-hour advance prediction of sepsis over traditional indices of heart rate entropy ([Formula: see text] versus [Formula: see text]). Our results indicate that this improvement is attributable to both the improved network construction method proposed here, as well as the information embedded in the higher order interaction of heart rate and blood pressure time series dynamics. Our final model, which included the most commonly available clinical measurements in patients' electronic medical records and multiscale entropy features, as well as the proposed network-based features, achieved an AUROC of [Formula: see text].
Prediction of the onset of sepsis prior to clinical recognition will allow for meaningful earlier interventions (e.g. antibiotic and fluid administration), which have the potential to decrease sepsis-related morbidity, mortality and healthcare costs.
败血症是一种感染引起的免疫失调宿主反应,是危重病患者发病率和死亡率的主要原因。心率变异性和复杂性(如熵)等指数已被提议作为败血症等疾病神经-免疫系统失调的替代标志物。然而,这些指数仅提供了复杂神经生理相互作用的平均、一维描述。我们提出了一种新的多尺度网络构建和分析方法,用于多变量生理时间序列,并证明其在败血症的早期预测中的实用性。
我们表明,源自多尺度心率和血压时间序列网络的特征提供了约 20%的改善,用于对败血症进行提前四小时的预测,超过心率熵的传统指数([公式:见文本] 与 [公式:见文本])。我们的结果表明,这种改进归因于这里提出的改进网络构建方法,以及心率和血压时间序列动力学的高阶相互作用中嵌入的信息。我们的最终模型包括患者电子病历中最常用的临床测量值、多尺度熵特征以及基于网络的特征,其 AUC 为 [公式:见文本]。
在临床识别之前预测败血症的发生将允许进行有意义的早期干预(例如抗生素和液体管理),这有可能降低败血症相关的发病率、死亡率和医疗保健成本。
