TY - JOUR
T1 - Hexagonal metal complex based mechanically robust transparent ultrathin gold µECoG for electro-optical neural interfaces
AU - Kim, Duhee
AU - Bissannagari, Murali
AU - Kim, Boil
AU - Hong, Nari
AU - Park, Jaeu
AU - Lim, Hyeongtae
AU - Lee, Junhee
AU - Lee, Jungha
AU - Kim, Yoon Kyoung
AU - Cho, Youngjae
AU - Lee, Kwang
AU - Lee, Junghyup
AU - Yoon, Jong Hyeok
AU - Jang, Jae Eun
AU - Tsai, David
AU - Lee, Sanghoon
AU - Kwon, Hyuk Jun
AU - Choe, Han Kyoung
AU - Kang, Hongki
N1 - Publisher Copyright:
© The Author(s) 2025.
PY - 2025/12
Y1 - 2025/12
N2 - Transparent electro-optical neural interfacing technologies offer simultaneous high-spatial-resolution microscopic imaging, and high-temporal-resolution electrical recording and stimulation. However, fabricating transparent, flexible, and mechanically robust neural electrodes with high electrochemical performance remains challenging. In this study, we fabricated transparent (72.7% at 570 nm), mechanically robust (0.05% resistance change after 50k bending cycles) ultrathin Au microelectrodes for micro-electrocorticography (µECoG) using a hexadentate metal-polymer ligand bonding with an EDTA/PSS seed layer. These transparent µECoG arrays, fabricated with biocompatible gold, exhibit excellent electrochemical properties (0.73 Ω·cm2) for neural recording and stimulation with long-term stability. We recorded brain surface waves in vivo, maintaining a low baseline noise and a high signal-to-noise ratio during acute and two-week recordings. In addition, we successfully performed optogenetic modulation without light-induced artifacts at 7.32 mW/mm2 laser power density. This approach shows great potential for scalable, implantable neural electrodes and wearable optoelectronic devices in digital healthcare systems.
AB - Transparent electro-optical neural interfacing technologies offer simultaneous high-spatial-resolution microscopic imaging, and high-temporal-resolution electrical recording and stimulation. However, fabricating transparent, flexible, and mechanically robust neural electrodes with high electrochemical performance remains challenging. In this study, we fabricated transparent (72.7% at 570 nm), mechanically robust (0.05% resistance change after 50k bending cycles) ultrathin Au microelectrodes for micro-electrocorticography (µECoG) using a hexadentate metal-polymer ligand bonding with an EDTA/PSS seed layer. These transparent µECoG arrays, fabricated with biocompatible gold, exhibit excellent electrochemical properties (0.73 Ω·cm2) for neural recording and stimulation with long-term stability. We recorded brain surface waves in vivo, maintaining a low baseline noise and a high signal-to-noise ratio during acute and two-week recordings. In addition, we successfully performed optogenetic modulation without light-induced artifacts at 7.32 mW/mm2 laser power density. This approach shows great potential for scalable, implantable neural electrodes and wearable optoelectronic devices in digital healthcare systems.
UR - https://www.scopus.com/pages/publications/105012842040
U2 - 10.1038/s41528-025-00403-w
DO - 10.1038/s41528-025-00403-w
M3 - Article
AN - SCOPUS:105012842040
SN - 2397-4621
VL - 9
JO - npj Flexible Electronics
JF - npj Flexible Electronics
IS - 1
M1 - 31
ER -