A supertough electro-tendon based on spider silk composites

Pan, Liang; Wang, Fan; Cheng, Yuan; Leow, Wan Ru; Zhang, Yong‐Wei; Wang, Ming; Cai, Pingqiang; Ji, Baohua; Li, Dechang; Chen, Xiao

doi:10.1038/s41467-020-14988-5

Cited by 80 publications

(59 citation statements)

References 55 publications

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“…Ionic conduction in the biological system plays a central role in the transmission of vital signs and performing physiological activities, such as the transmission of nerve signals, muscle contraction, heart beating, and blood pressure control. [ 1–24 ] Highly efficiently and precisely collecting or delivering these ionic signals are of great interest in clinical neurophysiology and material science for future wisdom medical and AI device controlling. [ 1,25–30 ] Therefore, an electrode that complies with the curved biological surface and has low bioelectrical interfacial impedance (the ideal impedance of electrode‐skin system is 6–10 kΩ which is the intrinsic impedance of skin) is in demand to effectively couple the ionic fluxes in electrolytic tissues and electronic current in recording devices.…”

Section: Figurementioning

confidence: 99%

A Compliant Ionic Adhesive Electrode with Ultralow Bioelectronic Impedance

et al. 2020

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Simultaneous implementation of high signal‐to‐noise ratio (SNR) but low crosstalk is of great importance for weak surface electromyography (sEMG) signals when precisely driving a prosthesis to perform sophisticated activities. However, due to gaps with the curved skin during muscle contraction, many electrodes have poor compliance with skin and suffer from high bioelectrical impedance. This causes serious noise and error in the signals, especially the signals from low‐level muscle contractions. Here, the design of a compliant electrode based on an adhesive hydrogel, alginate–polyacrylamide (Alg‐PAAm) is reported, which eliminates those large gaps through the strong electrostatic interaction and abundant hydrogen bond with the skin. The obtained compliant electrode, having an ultralow bioelectrical impedance of ≈20 kΩ, can monitor even 2.1% maximal voluntary contraction (MVC) of muscle. Furthermore, benefiting from the high SNR of >5:1 at low‐level MVC, the crosstalk from irrelevant muscle is minimized through reducing the electrode size. Finally, a prosthesis is successfully demonstrated to precisely grasp a needle based on a 9 mm2 Alg‐PAAm compliant electrode. The strategy to design such compliant electrodes provides the potential for improving the quality of dynamically weak sEMG signals to precisely control prosthesis in performing purposefully dexterous activity.

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Section: Figurementioning

confidence: 99%

A Compliant Ionic Adhesive Electrode with Ultralow Bioelectronic Impedance

et al. 2020

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“…Flexible and stretchable electronics, including deformable sensors, displays, memories, and energy devices, have received significant attention owing to their potential for use in smart wearable devices that collect and store personal, physiological information for medical and healthcare monitoring. [ 1–7 ] Developing these advanced electronics is highly contingent on the development and discovery of materials with desirable electrical and mechanical properties. Recently, significant progress has been made toward the development of stretchable insulators and conductors, including polymeric dielectrics, metal nanowire, and conjugate polymer composites.…”

Section: Introductionmentioning

confidence: 99%

Solution‐Processed Stretchable Ag₂S Semiconductor Thin Films for Wearable Self‐Powered Nonvolatile Memory

Cho

Yang

et al. 2021

Advanced Materials

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Compared with the large plastic deformation observed in ductile metals and organic materials, inorganic semiconductors have limited plasticity (<0.2%) due to their intrinsic bonding characters, restricting their widespread applications in stretchable electronics. Herein, the solution‐processed synthesis of ductile α‐Ag2S thin films and fabrication of all‐inorganic, self‐powered, and stretchable memory devices, is reported. Molecular Ag2S complex solution is synthesized by chemical reduction of Ag2S powder, fabricating wafer‐scale highly crystalline Ag2S thin films. The thin films show stretchability due to the intrinsic ductility, sustaining the structural integrity at a tensile strain of 14.9%. Moreover, the fabricated Ag2S‐based resistive random access memory presents outstanding bipolar switching characteristics (Ion/Ioff ratio of ≈105, operational endurance of 100 cycles, and retention time >106 s) as well as excellent mechanical stretchability (no degradation of properties up to stretchability of 52%). Meanwhile, the device is highly durable under diverse chemical environments and temperatures from −196 to 300 °C, especially maintaining the properties for 168 h in 85% relative humidity and 85 °C. A self‐powered memory combined with motion sensors for use as a wearable healthcare monitoring system is demonstrated, offering the potential for designing high‐performance wearable electronics that are usable in daily life in a real‐world setting.

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“…All three remain major challenges currently faced by sensor sutures fabrication. [6,26] To this end and as shown in Figure 2d, the strain of BSS with a collagen core fiber reached 50% with 7.2 N tensile force applied. Normalized resistance increased to 1.25, showing the high sensitivity of BSS to function as a strain sensor.…”

Section: Doi: 101002/adma202004733mentioning

confidence: 71%

Biomimicking Antibacterial Opto‐Electro Sensing Sutures Made of Regenerated Silk Proteins

et al. 2020

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Surgical sutures play an important role across a wide range of medical treatments and a wide variety exist, differing in strength, size, composition, and performance. Recently, increasing interest has been paid to bioactive and electronic sutures made of synthetic polymers, owing to their ability to reduce inflammation as well as medically and/or electronically facilitate wound healing. However, integrating sensing capabilities into bioactive sutures without adversely affecting their mechanical strength, biocompatibility, and/or bioactivity remains challenging. In this work, a set of biomimicking, antibacterial, and sensing sutures based on the regenerated silk fibroin is designed and fabricated. These sensing sutures, inspired by the “core–shell” multilayered structure of natural spider‐silk fibers, are hierarchically structured and heterogeneously functionalized to allow for the integration of multiple, clinically favorable functions into one suture device. These functions included: reducing inflammation and bacterial infection in wound sites, measuring tension of both the tissue and suture, and aiding tissue healing via multi‐modal controlled drug and growth factor release. Critically, these functions are coupled with real‐time optical and electronic monitoring capabilities. This approach provides greater insight into multifunctional sutures with inherent sensing capabilities and offers enormous potential in both therapeutic and diagnostic applications.

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A supertough electro-tendon based on spider silk composites

Cited by 80 publications

References 55 publications

A Compliant Ionic Adhesive Electrode with Ultralow Bioelectronic Impedance

A Compliant Ionic Adhesive Electrode with Ultralow Bioelectronic Impedance

Solution‐Processed Stretchable Ag₂S Semiconductor Thin Films for Wearable Self‐Powered Nonvolatile Memory

Biomimicking Antibacterial Opto‐Electro Sensing Sutures Made of Regenerated Silk Proteins

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A supertough electro-tendon based on spider silk composites

Cited by 80 publications

References 55 publications

A Compliant Ionic Adhesive Electrode with Ultralow Bioelectronic Impedance

A Compliant Ionic Adhesive Electrode with Ultralow Bioelectronic Impedance

Solution‐Processed Stretchable Ag2S Semiconductor Thin Films for Wearable Self‐Powered Nonvolatile Memory

Biomimicking Antibacterial Opto‐Electro Sensing Sutures Made of Regenerated Silk Proteins

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Product

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Solution‐Processed Stretchable Ag₂S Semiconductor Thin Films for Wearable Self‐Powered Nonvolatile Memory