Washable, Sewable, All-Carbon Electrodes and Signal Wires for Electronic Clothing

Taylor, Lauren W.; Williams, Steven M.; Yan, J. Stephen; Dewey, Oliver S.; Vitale, Flavia; Pasquali, Matteo

doi:10.1021/acs.nanolett.1c01039

Cited by 52 publications

(36 citation statements)

References 37 publications

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“…Recently, a type of washable, sewable, and all-carbon electrode was developed using CNT threads. 212 These electrodes demonstrated metal-level conductivity (6.6 ± 0.7 MS/m), which can be sewn onto a shirt for ECG signal measurement (Figure 3g). Even though these textile-based biopotential sensors represent a promising alternative to the traditional electrodes that are usually adopted in clinical practice, currently, there are still two limitations hampering the broad introduction of e-textiles with biopotential signal acquisition capability to the healthcare system.…”

Section: Physical Sensing For Diagnosticsmentioning

confidence: 99%

Electronic Textiles for Wearable Point-of-Care Systems

et al. 2021

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Traditional public health systems are suffering from limited, delayed, and inefficient medical services, especially when confronted with the pandemic and the aging population. Fusing traditional textiles with diagnostic, therapeutic, and protective medical devices can unlock electronic textiles (e-textiles) as point-of-care platform technologies on the human body, continuously monitoring vital signs and implementing round-the-clock treatment protocols in close proximity to the patient. This review comprehensively summarizes the research advances on e-textiles for wearable point-of-care systems. We start with a brief introduction to emphasize the significance of e-textiles in the current healthcare system. Then, we describe textile sensors for diagnosis, textile therapeutic devices for medical treatment, and textile protective devices for prevention, by highlighting their working mechanisms, representative materials, and clinical application scenarios. Afterward, we detail e-textiles’ connection technologies as the gateway for real-time data transmission and processing in the context of 5G technologies and Internet of Things. Finally, we provide new insights into the remaining challenges and future directions in the field of e-textiles. Fueled by advances in chemistry and materials science, textile-based diagnostic devices, therapeutic devices, protective medical devices, and communication units are expected to interact synergistically to construct intelligent, wearable point-of-care textile platforms, ultimately illuminating the future of healthcare system in the Internet of Things era.

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Section: Physical Sensing For Diagnosticsmentioning

confidence: 99%

Electronic Textiles for Wearable Point-of-Care Systems

et al. 2021

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“…In fact, biocompatible materials can achieve the interface between the electronic devices and the biological environment, while it can meet the new requirements of the development and broaden the corresponding biotechnology and semiconductor applications, such as implant chips, [242,243] artificial neurons [244,245] and electronic skin. [246][247][248] Ferroelectric materials have promising potential in traditional non-volatile memory as a result of the characteristics of ferroelectric phase transition under an electric field. [9,249,250] However, traditional inorganic ferroelectric materials are insensitive to light, which limits their application in photonic memristive devices.…”

Section: Others Materialsmentioning

confidence: 99%

Section: Active Materials For Photonic Memristive and Memristive‐like...mentioning

confidence: 99%

Advances in Emerging Photonic Memristive and Memristive‐Like Devices

et al. 2022

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Possessing the merits of high efficiency, low consumption, and versatility, emerging photonic memristive and memristive-like devices exhibit an attractive future in constructing novel neuromorphic computing and miniaturized bionic electronic system. Recently, the potential of various emerging materials and structures for photonic memristive and memristive-like devices has attracted tremendous research efforts, generating various novel theories, mechanisms, and applications. Limited by the ambiguity of the mechanism and the reliability of the material, the development and commercialization of such devices are still rare and in their infancy. Therefore, a detailed and systematic review of photonic memristive and memristive-like devices is needed to further promote its development. In this review, the resistive switching mechanisms of photonic memristive and memristive-like devices are first elaborated. Then, a systematic investigation of the active materials, which induce a pivotal influence in the overall performance of photonic memristive and memristive-like devices, is highlighted and evaluated in various indicators. Finally, the recent advanced applications are summarized and discussed. In a word, it is believed that this review provides an extensive impact on many fields of photonic memristive and memristive-like devices, and lay a foundation for academic research and commercial applications.

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“…In that context, digital therapeutics, consumer wearables and mobile apps, connected biomedical apps, smartphone cameras, connected virtual assistants in home care, but also health system disease management apps, care teams cooperation tools, interactive programs, personal health records, telemedicine and virtual visits to the doctor, and clinical trial tools have to be mentioned (21,22). Here, intelligent clothing using nanotube fibers to monitor heart metrics also comes into play (23).…”

Section: Moderated End-user Collaborationmentioning

confidence: 99%

Transformation of Health and Social Care Systems—An Interdisciplinary Approach Toward a Foundational Architecture

Blobel

Oemig²,

Ruotsalainen

et al. 2022

Front. Med.

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ObjectiveFor realizing pervasive and ubiquitous health and social care services in a safe and high quality as well as efficient and effective way, health and social care systems have to meet new organizational, methodological, and technological paradigms. The resulting ecosystems are highly complex, highly distributed, and highly dynamic, following inter-organizational and even international approaches. Even though based on international, but domain-specific models and standards, achieving interoperability between such systems integrating multiple domains managed by multiple disciplines and their individually skilled actors is cumbersome.MethodsUsing the abstract presentation of any system by the universal type theory as well as universal logics and combining the resulting Barendregt Cube with parameters and the engineering approach of cognitive theories, systems theory, and good modeling best practices, this study argues for a generic reference architecture model moderating between the different perspectives and disciplines involved provide on that system. To represent architectural elements consistently, an aligned system of ontologies is used.ResultsThe system-oriented, architecture-centric, and ontology-based generic reference model allows for re-engineering the existing and emerging knowledge representations, models, and standards, also considering the real-world business processes and the related development process of supporting IT systems for the sake of comprehensive systems integration and interoperability. The solution enables the analysis, design, and implementation of dynamic, interoperable multi-domain systems without requesting continuous revision of existing specifications.

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Washable, Sewable, All-Carbon Electrodes and Signal Wires for Electronic Clothing

Cited by 52 publications

References 37 publications

Electronic Textiles for Wearable Point-of-Care Systems

Electronic Textiles for Wearable Point-of-Care Systems

Advances in Emerging Photonic Memristive and Memristive‐Like Devices

Transformation of Health and Social Care Systems—An Interdisciplinary Approach Toward a Foundational Architecture

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