Flexible adaptive sensing tonometry for medical-grade multi-parametric hemodynamic monitoring

IF 12.3 1区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Mengkang Deng, Chentao Du, Jiayuan Fang, Changshun Xu, Chenhui Guo, Jiantao Huang, Kang Li, Lei Chen, Yuan-Ting Zhang, Yu Chang, Tingrui Pan
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Abstract

Continuous hemodynamic monitoring in a wearable means can play a crucial role in managing hypertension and preventing catastrophic cardiovascular events. In this study, we have described the fully wearable tonometric device, referred to as flexible adaptive sensing tonometry (FAST), which is capable of continuous and accurate monitoring of hemodynamic parameters within the medical-grade precision. In particular, the FAST system integrates a 1 × 8 unit array of highly sensitive and highly flexible iontronic sensing (FITS) with 1 mm spatial resolution and a closed-loop motion system. The flexible tonometric architecture has been used to determine the radial arterial position with high sensitivity and high conformability, which simplifies the biaxial searching process of the traditional applanation tonometry into a highly efficient uniaxial applanation while keeping the medical-precision assessments. Importantly, a self-calibration algorithm can be automatically implemented during the applanation process, from which the intra-arterial blood pressure wave can be continuously predicted within the medical-grade precision, and subsequently, multi-parametric hemodynamic analysis can be performed in real-time. Experimental validations on health volunteers have demonstrated that the FAST measurements are all within the required accuracy of the clinical standards for continuous pulse wave assessments, blood pressure monitoring as well as other key hemodynamic parameter evaluations. Therefore, the FAST system, by integrating the flexible iontronic sensing array, provides a real-time, medical-grade hemodynamic monitoring solution in a continuously wearable manner, from which remote patient-centered monitoring can be delivered with both medical precision and convenience.

Abstract Image

Abstract Image

用于医疗级多参数血液动力学监测的灵活自适应传感眼压计
可穿戴式连续血液动力学监测在管理高血压和预防灾难性心血管事件方面发挥着至关重要的作用。在这项研究中,我们介绍了一种完全可穿戴的眼压测量设备,即灵活自适应传感眼压测量系统(FAST),它能够在医疗级精度范围内连续、准确地监测血液动力学参数。特别是,FAST 系统集成了空间分辨率为 1 毫米的高灵敏度和高灵活性离子电子传感(FITS)的 1 × 8 单元阵列和闭环运动系统。这种灵活的眼压计结构用于确定具有高灵敏度和高顺应性的径向动脉位置,从而在保持医疗精度评估的同时,将传统平视眼压计的双轴搜索过程简化为高效的单轴平视。重要的是,该仪器可在测压过程中自动执行自校准算法,从而在医疗级精度内持续预测动脉内血压波,并随后实时执行多参数血流动力学分析。在健康志愿者身上进行的实验验证表明,FAST 测量的准确度均符合连续脉搏波评估、血压监测以及其他关键血液动力学参数评估的临床标准要求。因此,FAST 系统通过集成灵活的离子电子传感阵列,以连续可穿戴的方式提供了实时、医疗级的血液动力学监测解决方案,可提供以患者为中心的远程监测,既具有医疗精度,又非常方便。
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来源期刊
CiteScore
17.10
自引率
4.80%
发文量
91
审稿时长
6 weeks
期刊介绍: npj Flexible Electronics is an online-only and open access journal, which publishes high-quality papers related to flexible electronic systems, including plastic electronics and emerging materials, new device design and fabrication technologies, and applications.
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