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Thiophene-Based Trimers for In Vivo Electronic Functionalization of Tissues

Daniele Mantione, Emin Istif, Gwennaël Dufil, Lorenzo Vallan, Daniela Parker, Cyril Brochon, Éric Cloutet, Georges Hadziioannou, Magnus Berggren, Eleni Stavrinidou, Eleni Pavlopoulou

2020ACS Applied Electronic Materials38 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Electronic materials that can self-organize in vivo and form functional components along the tissue of interest can result in a seamless integration of the bioelectronic interface. Previously, we presented in vivo polymerization of the conjugated oligomer ETE-S in plants, forming conductors along the plant structure. The EDOT–thiophene–EDOT trimer with a sulfonate side group polymerized due to the native enzymatic activity of the plant and integrated within the plant cell wall. Here, we present the synthesis of three different conjugated trimers based on thiophene and EDOT or purely EDOT trimers that are able to polymerize enzymatically in physiological pH in vitro as well as in vivo along the roots of living plants. We show that by modulating the backbone and the side chain, we can tune the electronic properties of the resulting polymers as well as their localization and penetration within the root. Our work paves the way for the rational design of electronic materials that can self-organize in vivo for spatially controlled electronic functionalization of living tissue.

Topics & Concepts

TrimerThiopheneConjugated systemPolymerizationOligomerPolymerMaterials scienceSurface modificationIn vivoNanotechnologyChemistryPolymer chemistryOrganic chemistryDimerBiologyComposite materialBiotechnologyPhysical chemistryConducting polymers and applicationsAdvanced Sensor and Energy Harvesting MaterialsPolydiacetylene-based materials and applications
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