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Motion artifact–controlled micro–brain sensors between hair follicles for persistent augmented reality brain–computer interfacesMotion artifact-controlled micro-brain sensors between hair follicles for persistent augmented reality brain-computer interfaces

Other Titles
Motion artifact-controlled micro-brain sensors between hair follicles for persistent augmented reality brain-computer interfaces
Authors
Kim, HodamKim, Ju HyeonLee, Yoon JaeLee, JiminHan, HyojeongYi, HoonKim, HyeonseokKim, HojoongKang, Tae WoogChung, SuyeongBan, SeunghyebLee, ByeongjunLee, HaranIm, Chang-HwanCho, Seong J.Sohn, Jung WooYu, Ki JunKang, Tae JuneYeo, Woon-Hong
Issue Date
Apr-2025
Publisher
National Academy of Sciences
Keywords
augmented reality; brain–computer interfaces; conducting polymer; electroencephalography; micro–brain sensors
Citation
Proceedings of the National Academy of Sciences of the United States of America, v.122, no.15, pp 1 - 12
Pages
12
Indexed
SCIE
SCOPUS
Journal Title
Proceedings of the National Academy of Sciences of the United States of America
Volume
122
Number
15
Start Page
1
End Page
12
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/207334
DOI
10.1073/pnas.2419304122
ISSN
0027-8424
1091-6490
Abstract
Modern brain–computer interfaces (BCI), utilizing electroencephalograms for bidirectional human–machine communication, face significant limitations from movement-vulnerable rigid sensors, inconsistent skin–electrode impedance, and bulky electronics, diminishing the system’s continuous use and portability. Here, we introduce motion artifact–controlled micro–brain sensors between hair strands, enabling ultralow impedance density on skin contact for long-term usable, persistent BCI with augmented reality (AR). An array of low-profile microstructured electrodes with a highly conductive polymer is seamlessly inserted into the space between hair follicles, offering high-fidelity neural signal capture for up to 12 h while maintaining the lowest contact impedance density (0.03 kΩ·cm−2) among reported articles. Implemented wireless BCI, detecting steady-state visually evoked potentials, offers 96.4% accuracy in signal classification with a train-free algorithm even during the subject’s excessive motions, including standing, walking, and running. A demonstration captures this system’s capability, showing AR-based video calling with hands-free controls using brain signals, transforming digital communication. Collectively, this research highlights the pivotal role of integrated sensors and flexible electronics technology in advancing BCI’s applications for interactive digital environments.
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서울 공과대학 > ETC > 1. Journal Articles
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COLLEGE OF ENGINEERING (서울 바이오메디컬공학전공)
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