基于年龄因素的无袖带连续血压测量方法研究

高血压的精准检测与实时监测是极具现实意义与社会价值的重要课题。传统的袖带式血压监测技术无法实现连续血压测量，且长时间佩戴袖带阻断血流也会给受试者带来不适。因此，发展无袖带连续血压测量技术是血压监测领域迫切需要解决的问题。当前最常用的无袖带血压测量方法为基于脉搏波传输时间（Pulse Transit Time, PTT）的血压测量方法，其中PTT是基于光电容积脉搏波（Photoplethysmography, PPG）的关键参数。在可穿戴式脉搏波传感器中，对原始脉搏波信号的滤波操作会改变脉搏波波形特征点的时序，导致PTT计算误差，进而影响血压估测精度。

本研究首先探讨滤波对于PTT的影响，并定量探究年龄与PTT定义对无限冲激响应（Infinite Impulse Response, IIR）滤波引起的PTT变化的影响。选取20-29岁、30-39岁、40-49岁、50-59岁、60岁以上5个年龄组的健康受试者100名，每组20名参与实验。同时记录心电、手指与耳垂脉搏波信号，根据不同的脉搏波波形特征点确定了8种PTT定义，计算和比较5个年龄组和8种PTT定义下，预处理与滤波后脉搏波信号的PTT差异和相对差异。结果显示，在手指脉搏波信号中，滤波引起的PTT差异与相对差异受年龄与PTT定义的显著影响，呈现出随年龄增长而单调变化的趋势，其中20-29岁组PTT变化最大，50-59岁组PTT变化最小。在所有定义中，脉搏波波峰定义下的PTT变化最小，一阶导脉搏波波峰定义下的滤波引起的PTT变化与年龄的线性关系最强。在耳垂脉搏波信号中，50-59岁组与脉搏波波峰定义下的滤波引起的PTT变化最小。结果表明，在基于PTT的血压估计方法中应该考虑年龄与PTT定义等生理与技术因素。

随后，本课题延续前述研究思路，深入探讨年龄信息对于脉搏波血压估测的影响，采用卷积神经网络-门控循环单元（CNN-GRU）架构，将年龄信息融入注意力池化模块。模型在PulseDB数据库上的验证结果表明，收缩压与舒张压估测误差分别为4.92 ± 7.12 mmHg与3.05 ± 3.84 mmHg，满足美国医疗器械促进协会（AAMI）标准。

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