Chest-scale self-compensated epidermal electronics for standard 6-precordial-lead ECG

Yin, Lang; Wang, Youhua; Zhan, Jian; Bai, Yunzhao; Hou, Chunfeng; Wu, Jerry J.; Wang, Yuzhou; Huang, YongAn

doi:10.1038/s41528-022-00159-7

Cited by 8 publications

(7 citation statements)

References 46 publications

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“…The concept of extended electrodes can be applied to the work that has been recently reported. [37] The laminated stack was then placed on an acrylic substrate with a thermal release tape between them. The metals (platinum for temperature and gold for ECG electrodes) were deposited successively via ebeam on the other side of the middle PI film using shadow masks.…”

Section: Methods Results and Discussionmentioning

confidence: 99%

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Flex-to-Stretch Hybrid Electronics—Bonding-Free Robust Interface for Wearable Wireless Physiological Monitoring

Gandla,

Kang,

Kim

et al. 2024

IEEE Internet Things J.

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Hybrid electronics require a robust mechanical interface between externally fabricated stretchable sensors and flexible printed circuit boards (FPCBs) to obtain stable electrophysiological information. The most advanced technique for the integration of FPCBs with stretchable sensors is anisotropic conductive film bonding. Fabricating highperformance sensors requires microfabrication techniques, such as photolithography and etching, which are cumbersome and expensive. Therefore, a sensor fabrication process that supports FPCB manufacturing with lower complexity and cost is required. Herein, we propose a bonding-free approach for fabricating FPCBs and stretchable sensors on a single substrate. This approach utilizes in-and out-of-plane mechanical gradients to obtain a robust and durable mechanical interface for a smooth transition of the internal mechanical stress compliance, as confirmed by experiments and simulations. The gradient mesh patterns, without ACF bonding, can withstand tensile strains of over 30% before experiencing electrical breakdown. Additionally, Kirigami-inspired mesh patterns can extend stretchability by over 100%. The electrical performance of temperature sensors (linear response to temperature changes) and ECG sensors (clear visibility of PQRST peaks) remains stable under various physical activities. User-accessible, facile laser ablation and cutting techniques compatible with the FPCB manufacturing process were employed to fabricate stretchable sensors. This approach enables the development of FPCB-compatible on-skin stretchable sensors with robust mechanical properties.

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Section: Methods Results and Discussionmentioning

confidence: 99%

“…A comparison of our wearable device sensors and features with previous studies is presented in Table S2. [1], [2], [52], [3], [10], [37], [44], [48]- [51]…”

Section: Characteristics Of Temperature Ecg and Acceleration Sensorsmentioning

confidence: 99%

Flex-to-Stretch Hybrid Electronics—Bonding-Free Robust Interface for Wearable Wireless Physiological Monitoring

Gandla,

Kang,

Kim

et al. 2024

IEEE Internet Things J.

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“…Recently, research has been conducted on utilizing materials with superior deformability, such as liquid metals, at connection points between soft electrode materials and rigid computing devices to avoid mechanical and electrical stress. For example, Yin et al utilized a liquid metal as a soldering material to connect epidermal electronics with a flexible printed circuit board (fPCB) . They demonstrated robust connections without damage or degradation issues, thanks to the fluidic properties of the liquid metal.…”

Section: Future Perspectivesmentioning

confidence: 99%

“…For example, Yin et al utilized a liquid metal as a soldering material to connect epidermal electronics with a flexible printed circuit board (fPCB). 179 They demonstrated robust connections without damage or degradation issues, thanks to the fluidic properties of the liquid metal. The electrodes, thin enough to wrap around a hair (1.6 μm thick) and large enough to cover the entire chest area, were connected to the bulky fPCB including a lithium battery using liquid metal, showcasing the reliability of the liquid metal-based connection strategy.…”

Section: Future Perspectivesmentioning

confidence: 99%

Next-Generation Cardiac Interfacing Technologies Using Nanomaterial-Based Soft Bioelectronics

Han,

Sunwoo,

Park

et al. 2024

ACS Nano

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Cardiac interfacing devices are essential components for the management of cardiovascular diseases, particularly in terms of electrophysiological monitoring and implementation of therapies. However, conventional cardiac devices are typically composed of rigid and bulky materials and thus pose significant challenges for effective long-term interfacing with the curvilinear surface of a dynamically beating heart. In this regard, the recent development of intrinsically soft bioelectronic devices using nanocomposites, which are fabricated by blending conductive nanofillers in polymeric and elastomeric matrices, has shown great promise. The intrinsically soft bioelectronics not only endure the dynamic beating motion of the heart and maintain stable performance but also enable conformal, reliable, and large-area interfacing with the target cardiac tissue, allowing for high-quality electrophysiological mapping, feedback electrical stimulations, and even mechanical assistance. Here, we explore nextgeneration cardiac interfacing strategies based on soft bioelectronic devices that utilize elastic conductive nanocomposites. We first discuss the conventional cardiac devices used to manage cardiovascular diseases and explain their undesired limitations. Then, we introduce intrinsically soft polymeric materials and mechanical restraint devices utilizing soft polymeric materials. After the discussion of the fabrication and functionalization of conductive nanomaterials, the introduction of intrinsically soft bioelectronics using nanocomposites and their application to cardiac monitoring and feedback therapy follow. Finally, comments on the future prospects of soft bioelectronics for cardiac interfacing technologies are discussed.

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“…Tattooable electronics, also known as epidermal electronics, create conformal interfacing with the skin in the absence of the substrates, which facilitates better wearability and high fidelity. [55][56][57] Utilization of thin and soft materials for conformability enlarges the contact area of the electrode on the skin and reduces the impedance, resulting in a high SNR. Interference on the movement of the body is reduced because the devices are able to deform regarding the displacement of the skin.…”

Section: Tattooable Devicementioning

confidence: 99%

Emerging Bio‐Interfacing Wearable Devices for Signal Monitoring: Overview of the Mechanisms and Diverse Sensor Designs to Target Distinct Physiological Bio‐Parameters

Kim

Kwon

et al. 2023

Advanced Sensor Research

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Recently, personalized medical diagnostics and treatments have received significant interest due to the rising demand for reliable, rapid, and cost-effective healthcare services. In the recent development of wearable devices, ways to engineer devices to extend their reliability, minimize the risk of infection, and expand the scope of application have been focused on improving conventional clinical procedures. With the increasing interest in personalized healthcare, wearable devices have received substantial interest because they monitor each physiological parameter for specific clinical interest. These unique bio-parameters of individuals can be recorded from different target organs for the analysis of various functions, ranging from simple bodily movement to clinical treatment. In this review, the recent advances in sensors for recording unique bio-signals from the human body are discussed. Based on each unique bio-signals, a comprehensive analysis of wearable platforms for clinical diagnosis is provided, including subjects such as the selection of materials, device design structure, and application strategies for therapeutic significance. Furthermore, the challenges and future potential direction of modern bio-sensor devices are discussed extensively.

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Chest-scale self-compensated epidermal electronics for standard 6-precordial-lead ECG

Cited by 8 publications

References 46 publications

Flex-to-Stretch Hybrid Electronics—Bonding-Free Robust Interface for Wearable Wireless Physiological Monitoring

Flex-to-Stretch Hybrid Electronics—Bonding-Free Robust Interface for Wearable Wireless Physiological Monitoring

Next-Generation Cardiac Interfacing Technologies Using Nanomaterial-Based Soft Bioelectronics

Emerging Bio‐Interfacing Wearable Devices for Signal Monitoring: Overview of the Mechanisms and Diverse Sensor Designs to Target Distinct Physiological Bio‐Parameters

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