Chae-Eun Lee scite author profile

A number of research attempts to understand and modulate sensory and motor skills that are beyond the capability of humans have been underway. They have mainly been expounded in rodent models, where numerous reports of controlling movement to reach target locations by brain stimulation have been achieved. However, in the case of birds, although basic research on movement control has been conducted, the brain nuclei that are triggering these movements have yet to be established. In order to fully control flight navigation in birds, the basic central nervous system involved in flight behavior should be understood comprehensively, and functional maps of the birds’ brains to study the possibility of flight control need to be clarified. Here, we established a stable stereotactic surgery to implant multi-wire electrode arrays and electrically stimulated several nuclei of the pigeon’s brain. A multi-channel electrode array and a wireless stimulation system were implanted in thirteen pigeons. The pigeons' flight trajectories on electrical stimulation of the cerebral nuclei were monitored and analyzed by a 3D motion tracking program to evaluate the behavioral change, and the exact stimulation site in the brain was confirmed by the postmortem histological examination. Among them, five pigeons were able to induce right and left body turns by stimulating the nuclei of the tractus occipito-mesencephalicus (OM), nucleus taeniae (TN), or nucleus rotundus (RT); the nuclei of tractus septo-mesencephalicus (TSM) or archistriatum ventrale (AV) were stimulated to induce flight aviation for flapping and take-off with five pigeons.

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Intaglio Contact Printing of Versatile Carbon Nanotube Composites and Its Applications for Miniaturizing High‐Performance Devices

Joo

Lee

Kang

et al. 2021

Small

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Composites based on carbon nanotubes (CNTs) are promising patternable materials that can be engineered to incorporate the outstanding properties of CNTs into various applications via printing technologies. However, conventional printing methods for CNTs require further improvement to overcome the major drawbacks that limit the patterning resolution and target substrate. Herein, an intaglio contact printing method based on a CNT/paraffin composite is presented for realizing highly precise CNT network patterns without restrictions on the substrate. In this method, the CNT/paraffin composite can be patterned with a high resolution (<10 µm) and neatly transferred onto various substrates with a wide range of surface energies, including human skin. The patterned composite exhibits high durability against structural deformations, and structural damage caused by fatigue accumulation can be cured in a few seconds. In addition, miniaturized sensing and energy‐harvesting applications are demonstrated with high performances. The present method facilitates the rapid fabrication of highly precise interdigitated electrodes via one‐step printing, enabling high‐performance operation and miniaturization of the devices. It is anticipated that these results will not only spur the further development of various applications of CNTs but also contribute to advances in soft lithography methods applicable to many fields of science and engineering.

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Intaglio Contact Printing of Versatile Carbon Nanotube Composites and Its Applications for Miniaturizing High‐Performance Devices (Small 3/2022)

Joo

Lee

Kang

et al. 2022

Small

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Device Miniaturization Intaglio contact printing enables the realization of highly precise carbon nanotube (CNT) network patterns exhibiting multi‐functionalities without restrictions on the substrate. In article number 2106174, Soonmin Seo, Yoon‐Kyu Song, Ju‐Hyung Kim, and co‐workers present this method for the fabrication and miniaturization of high‐performance devices, including flexible fringe‐effect capacitive sensors.

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Big data analysis of the Metaverse travel

Lee¹

2022

jhts

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Chae-Eun Lee

Sitting Posture Prediction and Correction System using Arduino-Based Chair and Deep Learning Model

Current Stimulation of the Midbrain Nucleus in Pigeons for Avian Flight Control

Intaglio Contact Printing of Versatile Carbon Nanotube Composites and Its Applications for Miniaturizing High‐Performance Devices

Intaglio Contact Printing of Versatile Carbon Nanotube Composites and Its Applications for Miniaturizing High‐Performance Devices (Small 3/2022)

Big data analysis of the Metaverse travel

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