TY - JOUR
T1 - An All-Protein Multisensory Highly Bionic Skin
AU - Li, Shengyou
AU - Liu, Andeng
AU - Qiu, Wu
AU - Wang, Yimeng
AU - Liu, Guoqing
AU - Liu, Jiarong
AU - Shi, Yating
AU - Li, Yaxian
AU - Li, Jianing
AU - Cai, Wenjie
AU - Park, Cheolmin
AU - Ye, Meidan
AU - Guo, Wenxi
N1 - Publisher Copyright:
© 2024 American Chemical Society.
PY - 2024/2/6
Y1 - 2024/2/6
N2 - To achieve a highly realistic robot, closely mimicking human skin in terms of materials and functionality is essential. This paper presents an all-protein silk fibroin bionic skin (SFBS) that emulates both fast-adapting (FA) and slow-adapting (SA) receptors. The mechanically different silk film and hydrogel, which exhibited skin-like properties, such as stretchability (>140%), elasticity, low modulus (<10 kPa), biocompatibility, and degradability, were prepared through mesoscopic reconstruction engineering to mimic the epidermis and dermis. Our SFBS, incorporating SA and FA sensors, demonstrated a highly sensitive (1.083 kPa-1) static pressure sensing performance (in vitro and in vivo), showed the ability to sense high-frequency vibrations (50-400 Hz), could discriminate materials and sliding, and could even identify the fine morphological differences between objects. As proof of concept, an SFBS-integrated rehabilitation glove was synthesized, which could help stroke patients regain sensory feedback. In conclusion, this work provides a practical approach for developing skin equivalents, prostheses, and smart robots.
AB - To achieve a highly realistic robot, closely mimicking human skin in terms of materials and functionality is essential. This paper presents an all-protein silk fibroin bionic skin (SFBS) that emulates both fast-adapting (FA) and slow-adapting (SA) receptors. The mechanically different silk film and hydrogel, which exhibited skin-like properties, such as stretchability (>140%), elasticity, low modulus (<10 kPa), biocompatibility, and degradability, were prepared through mesoscopic reconstruction engineering to mimic the epidermis and dermis. Our SFBS, incorporating SA and FA sensors, demonstrated a highly sensitive (1.083 kPa-1) static pressure sensing performance (in vitro and in vivo), showed the ability to sense high-frequency vibrations (50-400 Hz), could discriminate materials and sliding, and could even identify the fine morphological differences between objects. As proof of concept, an SFBS-integrated rehabilitation glove was synthesized, which could help stroke patients regain sensory feedback. In conclusion, this work provides a practical approach for developing skin equivalents, prostheses, and smart robots.
KW - capacitive sensors
KW - electronic skin
KW - mechanoreceptors
KW - silk fibroin
KW - triboelectricity
UR - https://www.scopus.com/pages/publications/85184300620
U2 - 10.1021/acsnano.3c12525
DO - 10.1021/acsnano.3c12525
M3 - 文章
C2 - 38258755
AN - SCOPUS:85184300620
SN - 1936-0851
VL - 18
SP - 4579
EP - 4589
JO - ACS Nano
JF - ACS Nano
IS - 5
ER -