Research News

[Prof. Seung Hwan Ko] Digital selective transformation and patterning of highly conductive hydrogel bioelectronics by laser-ind

Author
김민아
Date
2024-04-29
Views
124

Abstract



The patterning of poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) hydrogels with excellent electrical property and spatial resolution is a challenge for bioelectronic applications. However, most PEDOT:PSS hydrogels are fabricated by conventional manufacturing processes such as photolithography, inkjet printing, and screen printing with complex fabrication steps or low spatial resolution. Moreover, the additives used for fabricating PEDOT:PSS hydrogels are mostly cytotoxic, thus requiring days of detoxification. Here, we developed a previously unexplored ultrafast and biocompatible digital patterning process for PEDOT:PSS hydrogel via phase separation induced by a laser. We enhanced the electrical properties and aqueous stability of PEDOT:PSS by selective laser scanning, which allowed the transformation of PEDOT:PSS into water-stable hydrogels. PEDOT:PSS hydrogels showed high electrical conductivity of 670 S/cm with 6-μm resolution in water. Furthermore, electrochemical properties were maintained even after 6 months in a physiological environment. We further demonstrated stable neural signal recording and stimulation with hydrogel electrodes fabricated by laser.


DISCUSSION



We present a strategy for the micropatterning of high-performance PEDOT:PSS hydrogels through a laser-induced phase separation process. The developed hydrogels showed high electrical properties with a fine pattern resolution and maintained their electrical and electrochemical properties for an extended period in a physiological environment. The material properties of PEDOT:PSS hydrogels can be tuned by controlling the AuNP concentration and laser parameters. This process is promising for various engineering fields that require electrode materials with excellent aqueous stability in electrolytes and high electrical properties, such as bioelectronics, energy devices, and e-skin devices.

More Information : Digital selective transformation and patterning of highly conductive hydrogel bioelectronics by laser-induced phase separation | Science Advances