Versatile nano–micro collagen fiber-based wearable electronics for health monitoring and thermal management

Bai, Zhongxue; Wang, Xuechuan; Huang, Meng-Chen; Zheng, Manhui; Ouyang, Yu; Hao, Dongyu; Wang, Yu; Zou, Xiaoliang; Cui, Boqiang; Xie, Long; Zha, Siyu; Ju, Haiyan; Liu, Xinhua

doi:10.1039/d2ta08263b

Cited by 30 publications

(17 citation statements)

References 91 publications

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“…However, most emerging strain sensors suffer from insufficient strength and conductivity, small sensitivity, weak interference immunity, and deficient functions for some specific applications. 68 Pressure Sensing. For the surface that can undergo elastic deformation, the external contact force will produce extrusion.…”

Section: ■ Sensing Devicesmentioning

confidence: 99%

“…When soft grippers grasp cups of different sizes or when humanoid fingers make different gestures, the strain sensor can give corresponding feedback, paving the way for accurate control of the actuator system and human–computer safety interaction. However, most emerging strain sensors suffer from insufficient strength and conductivity, small sensitivity, weak interference immunity, and deficient functions for some specific applications …”

Section: Sensing Devicesmentioning

confidence: 99%

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Personalized Medical Devices Connect Monitoring and Assistance: Emerging Wearable Soft Robotics

et al. 2023

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As wearable health devices have the ability of intelligent monitoring, they are becoming cutting-edge technology in medical and health fields. However, the simplification of functions limits their further development. In addition, soft robotics with actuation functions can achieve therapeutic effects by doing external work, but their monitoring function is not sufficiently developed. The efficient integration of the two can guide future development. The functional integration of actuation and sensing can not only monitor the human body and surrounding environment but also realize actuation and assistance. Recent evidence shows that emerging wearable soft robotics can become the future of personalized medical treatment. In this Perspective, the comprehensive development in the field of actuators for simple structure soft robotics and the field of wearable application sensors are introduced, as well as their manufacturing processes and various potential medical applications. Furthermore, the challenges faced in this field are discussed, and future development directions are proposed.

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Section: ■ Sensing Devicesmentioning

confidence: 99%

Section: Sensing Devicesmentioning

confidence: 99%

Personalized Medical Devices Connect Monitoring and Assistance: Emerging Wearable Soft Robotics

et al. 2023

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Section: Introductionmentioning

confidence: 99%

“…Meeting these aforementioned requirements often requires the combination of fabrics with various materials possessing distinct properties. Recently, conductive materials have been used to compound with fabrics to realize various sensing functions, and the conductive materials reported include metals and their derivatives, , conductive polymers, , liquid electrodes, and so on. Among these materials, conductive hydrogels have been most commonly used because of their superior biocompatibility and comfort. , However, many of the existing functional fabrics have been found only responding to few stimuli or only suited to few wearable scenarios. − Therefore, this inability to simultaneously achieve multistimuli responses and diversified wearable application scenarios highlights a critical need to expand both multistimuli responses and multiapplication scenarios for these functional fabrics.…”

Section: Introductionmentioning

confidence: 99%

Polyacrylamide–Poly(vinyl alcohol)–Sodium Alginate–Reduced Graphene Oxide/Nylon Fabrics with Multistimuli Responses

Chen,

Dai,

Yan

et al. 2023

ACS Appl. Polym. Mater.

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In recent years, various functional fabrics capable of responding to multistimuli have been widely recognized as promising wearable devices. However, the obtained composite functional fabrics have only been applied in a few scenarios, rendering the achievement of multifunctional wearable application scenarios a difficult goal. Therefore, there is an urgent need to expand the diversity of wearable applications for functional fabrics. Herein, we design hydrogel composite fabrics capable of responding to multiple stimuli, including vibration, temperature, strain, and pressure, to enable wearable multiapplication scenarios. The hydrogel composite fabrics, based on nylon fabrics (NFs), are fabricated with polyacrylamide (PAM)–poly(vinyl alcohol) (PVA)–sodium alginate (SA)–reduced graphene oxide (rGO)/NFs (PAM–PVA–SA–rGO/NFs). The PAM–PVA–SA–rGO/NFs exhibit a higher elastic stiffness coefficient (2.79 N cm–1) than the blank NFs (1.76 N cm–1), good temperature sensitivity in the range of 30–80 °C, and excellent detecting ability for urine presence with a threshold of unit area of 2.55 × 10–3 mL cm–2. The PAM–PVA–SA–rGO/NFs can not only respond to multiple stimuli but also be integrated into clothing for wearable multiapplication scenarios, such as detecting human speaking and breathing, intelligent sleeves, and diaper alarms. Additionally, the mechanisms of the above phenomena are revealed. These results indicate that the PAM–PVA–SA–rGO/NFs will provide inspiration for the development of intelligence systems, feedback devices, soft robotics, wearable devices, etc.

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“…In terms of materials, the selection of excellent conductive materials is another key factor in achieving the high sensitivity of strain sensors. Due to their excellent electrical properties, most research has studied carbon nanotubes, 19 MXene, 20 graphene, 21 metal nanoparticles, 22 and a series of conducting polymers 23,24 as functional sensing elements. It is worth mentioning that graphene is widely used in the sensing field.…”

Section: Introductionmentioning

confidence: 99%

A solely biobased strain sensor with an ultra-precision response via a surface graphitization strategy

Yang,

Yuan,

Wang

et al. 2023

J. Mater. Chem. A

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Versatile nano–micro collagen fiber-based wearable electronics for health monitoring and thermal management

Abstract: As a vital component of wearable electronics, flexible strain sensors have drawn vast attention due to their capabilities in capturing postures and monitoring various human activities. However, most emerging strain...

Cited by 30 publications

References 91 publications

Personalized Medical Devices Connect Monitoring and Assistance: Emerging Wearable Soft Robotics

Personalized Medical Devices Connect Monitoring and Assistance: Emerging Wearable Soft Robotics

Polyacrylamide–Poly(vinyl alcohol)–Sodium Alginate–Reduced Graphene Oxide/Nylon Fabrics with Multistimuli Responses

A solely biobased strain sensor with an ultra-precision response via a surface graphitization strategy

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