Nature-inspired rollable electronics

• Published in: NPG Asia materials Vol. 11; no. 1; pp. 1 - 10
• Main Authors: Lee, Gunhee, Choi, Yong Whan, Lee, Taemin, Lim, Kyung Seob, Shin, Jooyeon, Kim, Taewi, Kim, Hyun Kuk, Koo, Bon-Kwon, Kim, Han Byul, Lee, Jong-Gu, Ahn, Kihyeon, Lee, Eunhan, Lee, Min Suk, Jeon, Jin, Yang, Hee Seok, Won, Phillip, Mo, Seongho, Kim, Namkeun, Jeong, Myung Ho, Roh, Yeonwook, Han, Seungyong, Koh, Je-Sung, Kim, Sang Moon, Kang, Daeshik, Choi, Mansoo
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 22.11.2019; Nature Publishing Group
• Subjects: 639/166/985; 639/925/927/1007; Bioelectricity; Biomaterials; Biomedical materials; Biotechnology; Blood vessels; Chemistry and Materials Science; Circuits; Electronic circuits; Electronic devices; Electronics; Energy Systems; Materials Science; Object recognition; Optical and Electronic Materials; Organs; Radius of curvature; Sensors; Structural Materials; Surface and Interface Science; Swine; Temperature sensors; Thin Films
• ISSN: 1884-4049; 1884-4057
• DOI: 10.1038/s41427-019-0169-z

Inspired by the rolling mechanism of the proboscis of a butterfly, rollable electronics that can be rolled and unrolled to a great extent on demand are developed. Generally, electronic devices that are attached to various surfaces to acquire biosignals require mechanical flexibility and sufficient adhesive force. The rollable platform provides sufficient force that grips onto the entire target surface without destroying the target organ. To prove the versatility of our device not only in gripping and detecting biosignals from micro objects but also in performing a variety of functions, thin-film electronics including a heater, strain sensor and temperature sensor are constructed on the rollable platform, and it is confirmed that all the electronics operate normally in the rolled and unrolled states without breakdown. Then, micro bio-objects are gripped by using the rollable platform, and their tiny motions are successfully detected with the sensor on the platform. Furthermore, the detection of the pulse wave signals of swine under diverse experimental conditions is successfully conducted by rolling up the rollable system around the blood vessel of the swine, the result of which proves the feasibility of a rollable platform as a biomedical device. Bioelectronics: Unfurling devices for a better fit Rollable electronic devices inspired by butterflies have been fabricated by researchers in South Korea for biomedical applications. Bioelectronic devices can be attached to the body, either outside on the skin or inside on internal organs. They can then monitor and even help regulate the operation of the organ. Ensuring that bioelectronic components stay attached is tricky, particularly for tubular organs with a small radius of curvature, such as blood vessels. Gunhee Lee from the Seoul National University and co-workers constructed a thin-film electronic circuit that they could tightly roll and unroll on demand, in the same way a butterfly unfurls its proboscis, to grip the target organ with sufficient force. The viability of their device, which included a heater, strain and temperature sensor, was demonstrated by monitoring the femoral artery of a pig. Inspired by the rolling mechanism of the proboscis of a butterfly, a rollable electronics which can be rolled and unrolled on demand is developed. The rollable platform provides sufficient force which grips onto the entire target surface without destroying the target. Micro bio-objects are gripped by using the rollable platform and their tiny motions are successfully detected with the sensor on the platform. Furthermore, detecting pulse wave signals of the swine is successfully conducted by rolling up the rollable system around the blood vessel of swine, which result proves the feasibility of rollable platform as a biomedical device.