Wearable microfluidic biosensors with haptic feedback for continuous monitoring of hydration biomarkers in workers

IF 15.1 1区医学 Q1 HEALTH CARE SCIENCES & SERVICES NPJ Digital Medicine Pub Date : 2025-02-01 DOI:10.1038/s41746-025-01466-9

Julia C. Spinelli, Brandon J. Suleski, Donald E. Wright, Joseph L. Grow, Gabriel R. Fagans, Maura J. Buckley, Da Som Yang, Kaitao Yang, Steven M. Beil, Jessica C. Wallace, Thomas S. DiZoglio, Jeffrey B. Model, Shirley Love, David E. Macintosh, Alan P. Scarth, Matthew T. Marrapode, Corinna Serviente, Raudel Avila, Barrak K. Alahmad, Michael A. Busa, John A. Wright, Weihua Li, Douglas J. Casa, John A. Rogers, Stephen P. Lee, Roozbeh Ghaffari, Alexander J. Aranyosi

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Abstract

Real-time monitoring of hydration biomarkers in tandem with biophysical markers can offer valuable physiological insights about heat stress and related thermoregulatory response. These metrics have been challenging to achieve with wearable sensors. Here we present a closed-loop electrochemical/biophysical wearable sensing device and algorithms that directly measure whole-body sweat loss, sweating rate, sodium concentration, and sodium loss with electrode arrays embedded in a microfluidic channel. The device contains two temperature sensors for skin temperature and thermal flux recordings, and an accelerometer for real-time monitoring of activity level. An onboard haptic module enables vibratory feedback cues to the wearer once critical sweat loss thresholds are reached. Data is stored onboard in memory and autonomously transmitted via Bluetooth to a smartphone and cloud portal. Field studies conducted in physically demanding activities demonstrate the key capabilities of this platform to inform hydration interventions in highly challenging real-world settings.

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具有触觉反馈的可穿戴微流体生物传感器，用于连续监测工人体内的水合生物标志物

水合生物标志物与生物物理标志物的实时监测可以为热应激和相关的体温调节反应提供有价值的生理学见解。这些指标一直是可穿戴传感器难以实现的。在这里，我们提出了一个闭环电化学/生物物理可穿戴传感装置和算法，直接测量全身出汗损失、出汗率、钠浓度和钠损失，电极阵列嵌入微流体通道。该设备包含两个温度传感器，用于记录皮肤温度和热通量，以及一个加速度计，用于实时监测活动水平。一旦达到临界失汗阈值，机载触觉模块可以向佩戴者提供振动反馈提示。数据存储在车载内存中，并通过蓝牙自动传输到智能手机和云门户。在高体力要求的活动中进行的现场研究表明，该平台的关键能力可以在极具挑战性的现实环境中为水化干预提供信息。

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来源期刊

NPJ Digital Medicine Multiple-

CiteScore

25.10

自引率

3.30%

发文量

170

审稿时长

15 weeks

期刊介绍： npj Digital Medicine is an online open-access journal that focuses on publishing peer-reviewed research in the field of digital medicine. The journal covers various aspects of digital medicine, including the application and implementation of digital and mobile technologies in clinical settings, virtual healthcare, and the use of artificial intelligence and informatics. The primary goal of the journal is to support innovation and the advancement of healthcare through the integration of new digital and mobile technologies. When determining if a manuscript is suitable for publication, the journal considers four important criteria: novelty, clinical relevance, scientific rigor, and digital innovation.