Soft Microfluidic Wearable Sensors for Biomedical Applications

C. Lim
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引用次数: 1

Abstract

The future of healthcare wearables lies in continual sensing in an unobtrusive manner. Tactile sensing is especially important to capture mechanotransduced signals arising from the body, or as a result of interactions with the external environment. However, conventional sensors are rigid, stiff and obstrusive. Therefore, one of the key objectives is to confer flexibility and stretchability to our sensing elements, while maintaining its sensitivity and robustness. Here, we develop a novel liquid-based microfluidic and microtubular sensors that possess high flexibility, durability, and sensitivity. The sensors comprise a soft elastomer-based microfluidic template encapsulating a conductive liquid which serves as the active sensing element of the device. This sensor is capable of distinguishing and quantifying the various user-applied mechanical forces it is subjected to. We demonstrated healthcare applications of our sensors in rehabilitation monitoring, artificial sensing and disease tracking such as that for diabetic patients. Overall, our work highlights the potential of the liquid-based microfluidic sensing platforms in a wide range of healthcare applications and further facilitates the exploration and realization of functional liquid-state device technology.
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生物医学应用的软微流体可穿戴传感器
医疗可穿戴设备的未来在于以一种不引人注目的方式持续感知。触觉感知对于捕获来自身体或与外部环境相互作用的机械转导信号尤其重要。然而,传统的传感器是刚性的,僵硬的和突兀的。因此,关键目标之一是赋予我们的传感元件的灵活性和可拉伸性,同时保持其灵敏度和鲁棒性。在这里,我们开发了一种新型的基于液体的微流体和微管传感器,具有高灵活性,耐用性和灵敏度。传感器包括软弹性体微流控模板,该模板封装导电液体,该导电液体作为该装置的主动传感元件。这种传感器能够区分和量化它所受到的各种用户施加的机械力。我们展示了我们的传感器在康复监测、人工传感和疾病跟踪(如糖尿病患者)方面的医疗应用。总的来说,我们的工作突出了基于液体的微流控传感平台在广泛的医疗保健应用中的潜力,并进一步促进了功能性液态器件技术的探索和实现。
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