Cardiovascular monitoring of elective aortic aneurysm repair using methods of chaos analysis.

F Christ, J M Abicht, M Athelogou, H Baschnegger, M Niklas, K Peter, K Messmer
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引用次数: 5

Abstract

Introduction: Biological signals like arterial blood pressure (ABP) and electrocardiograms are usually displayed in a linear fashion. The often very complex structure may, however, be better described by phase space plots and time-delayed vectors, enabling an advantageous display of the dynamics contained in the signal. The potentials of such a display were investigated during elective aortic aneurysm repair, where profound haemodynamic changes frequently occur.

Method: The peripheral volume pulse was recorded at a digit using noninvasive near infrared photoplethysmography (NIRP). All patients (n = 20, mean age 72.8 years) were invasively monitored using arterial and Swan Ganz catheters. The ABP signal was continuously recorded with a computer (sample rate 128 Hz). Two different phase space plots, [x(t), y(t + 8/128 s) and x(t), d(x(t + 8/128 s) - x(t))/dt] were calculated for the NIRP and the ABP signals and continuously displayed. The stability was subjectively assessed and the fractal dimension calculated using the 'Hausdorff dimension'. The correlation between stability, fractal dimension and frequently used parameters of patient monitoring were investigated.

Results: All patients included in the study had an uncomplicated operation. Cardiac index (CI) and oxygen delivery (DO2) increased, and systemic vascular resistance (SVR) decreased following declamping of the aorta. The ABP signal was generally more stable. After declamping of the aorta, 14 of 16 NIRP signals became unstable, and 9 of 14 ABP signals destabilised. The time required for stabilisation of the signal varied between the individual patients. Thirty minutes after declamping, 11 of 12 ABP signals were stable, whereas 3 out of 9 NIRP signals still revealed an unstable pattern. A fractal dimension was calculated by box counting, which revealed a linear regression over two orders of magnitude in a log-log plot (Hausdorff dimension between 1.19 and 1.71). The mean fractal dimension for NIRP was significantly higher than that of the ABP signal. On clamping and declamping of the aorta, a trend to a higher fractal dimension (p = 0.08) was observed for both signals analysed. No correlation was observed between the fractal dimension and ABP, SVR index, CI, DO2 index and oxygen consumption.

Discussion: The dynamic changes of the signals were emphasised when they were displayed as phase space plots calculated by time-delayed vectors. The time series of the signal revealed a fractal dimension, and the observed increase at the critical time points of the operation, where the need for cardiovascular regulation is most pronounced, support the contention that a physiological system based on non-linear behaviour may enable a rapid response to haemodynamic challenges. An on-line display of phase space plots calculated by time-delayed vectors may in future provide a valuable method of monitoring for high-risk patients.

应用混沌分析方法监测择期主动脉瘤修复的心血管功能。
生物信号如动脉血压(ABP)和心电图通常以线性方式显示。然而,通常非常复杂的结构可以通过相空间图和时间延迟向量更好地描述,从而能够有利地显示信号中包含的动态。这种显示的潜力在选择性主动脉瘤修复期间进行了研究,在那里经常发生深刻的血流动力学变化。方法:采用无创近红外光容积脉搏波仪(NIRP)记录外周容积脉搏。所有患者(n = 20,平均年龄72.8岁)均采用动脉导管和Swan Ganz导管进行有创监测。用计算机连续记录ABP信号(采样率128 Hz)。计算了NIRP和ABP信号的两个不同相空间图[x(t), y(t + 8/128 s)和x(t), d(x(t + 8/128 s) - x(t))/dt],并连续显示。对其稳定性进行了主观评价,并用Hausdorff维数计算了分形维数。探讨了稳定性、分形维数与患者监护常用参数的相关性。结果:所有患者均顺利完成手术。主动脉去主动脉后,心脏指数(CI)和氧输送(DO2)升高,全身血管阻力(SVR)降低。ABP信号总体较为稳定。主动脉去封后,16个NIRP信号中有14个变得不稳定,14个ABP信号中有9个变得不稳定。稳定信号所需的时间因患者而异。去钳后30分钟,12个ABP信号中有11个稳定,而9个NIRP信号中有3个仍然显示不稳定模式。分形维数通过箱形计数计算出来,在对数-对数图中显示出超过两个数量级的线性回归(Hausdorff维数在1.19和1.71之间)。NIRP信号的平均分形维数显著高于ABP信号。在主动脉夹持和去夹持时,观察到两种信号分析的分形维数呈较高趋势(p = 0.08)。分形维数与ABP、SVR指数、CI、DO2指数、耗氧量无相关性。讨论:当信号显示为由时滞矢量计算的相空间图时,强调了信号的动态变化。信号的时间序列显示了分形维数,并且在手术的关键时间点(心血管调节的需求最明显)观察到的增加支持了基于非线性行为的生理系统可能能够对血流动力学挑战做出快速反应的论点。由时滞矢量计算的相空间图的在线显示将来可能为高危患者的监测提供一种有价值的方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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