TY - JOUR
T1 - In Vivo Photopolymerization
T2 - Achieving Detailed Conducting Patterns for Bioelectronics
AU - Ek, Fredrik
AU - Abrahamsson, Tobias
AU - Savvakis, Marios
AU - Bormann, Stefan
AU - Mousa, Abdelrazek H.
AU - Shameem, Muhammad Anwar
AU - Hellman, Karin
AU - Yadav, Amit Singh
AU - Betancourt, Lazaro Hiram
AU - Ekström, Peter
AU - Gerasimov, Jennifer Y.
AU - Simon, Daniel T.
AU - Marko-Varga, György
AU - Hjort, Martin
AU - Berggren, Magnus
AU - Strakosas, Xenofon
AU - Olsson, Roger
N1 - Publisher Copyright:
© 2024 The Author(s). Advanced Science published by Wiley-VCH GmbH.
PY - 2024
Y1 - 2024
N2 - Bioelectronics holds great potential as therapeutics, but introducing conductive structures within the body poses great challenges. While implanted rigid and substrate-bound electrodes often result in inflammation and scarring in vivo, they outperform the in situ-formed, more biocompatible electrodes by providing superior control over electrode geometry. For example, one of the most researched methodologies, the formation of conductive polymers through enzymatic catalysis in vivo, is governed by diffusion control due to the slow kinetics, with curing times that span several hours to days. Herein, the discovery of the formation of biocompatible conductive structures through photopolymerization in vivo, enabling spatial control of electrode patterns is reported. The process involves photopolymerizing novel photoactive monomers, 3Es (EDOT-trimers) alone and in a mixture to cure the poly(3, 4-ethylenedioxythiophene)butoxy-1-sulfonate (PEDOT-S) derivative A5, resulting in conductive structures defined by photolithography masks. These reactions are adapted to in vivo conditions using green and red lights, with short curing times of 5–30 min. In contrast to the basic electrode structures formed through other in situ methods, the formation of specific and layered patterns is shown. This opens up the creation of more complex 3D layers-on-layer circuits in vivo.
AB - Bioelectronics holds great potential as therapeutics, but introducing conductive structures within the body poses great challenges. While implanted rigid and substrate-bound electrodes often result in inflammation and scarring in vivo, they outperform the in situ-formed, more biocompatible electrodes by providing superior control over electrode geometry. For example, one of the most researched methodologies, the formation of conductive polymers through enzymatic catalysis in vivo, is governed by diffusion control due to the slow kinetics, with curing times that span several hours to days. Herein, the discovery of the formation of biocompatible conductive structures through photopolymerization in vivo, enabling spatial control of electrode patterns is reported. The process involves photopolymerizing novel photoactive monomers, 3Es (EDOT-trimers) alone and in a mixture to cure the poly(3, 4-ethylenedioxythiophene)butoxy-1-sulfonate (PEDOT-S) derivative A5, resulting in conductive structures defined by photolithography masks. These reactions are adapted to in vivo conditions using green and red lights, with short curing times of 5–30 min. In contrast to the basic electrode structures formed through other in situ methods, the formation of specific and layered patterns is shown. This opens up the creation of more complex 3D layers-on-layer circuits in vivo.
KW - biocompatibility, bioelectronics
KW - in vivo
KW - photolithography
KW - photopolymerization
U2 - 10.1002/advs.202408628
DO - 10.1002/advs.202408628
M3 - Article
C2 - 39509564
AN - SCOPUS:85208231089
SN - 2198-3844
SP - 1
EP - 10
JO - Advanced Science
JF - Advanced Science
M1 - 2408628
ER -