Numerous efforts have been made to address the mechanical mismatch between bioelectronic devices and tissues in the past few years. Interfaces that better mimic the properties of biological tissues can be produced with the support of organic materials, which have a unique combination of soft mechanical properties, biocompatibility, and ionic-electronic conduction, which match the properties of living systems and allow the signal to be transduced at the biotic-abiotic interface. In this context, Poly(3-hexylthiophene) (P3HT), a p-type semiconducting polymer, having good biocompatibility, electrical conductivity, and mechanical properties, is studied. In this work, a polymer blend of P3HT and multi-walled carbon nanotubes (MWCNT) is prepared and deposited on the surface as an electroactive thin film resulting in a tunable nanostructured surface. Further, the biological properties of this new substrate in vitro is evaluated. The conductive polymer-based substrate and the HT-22 cell line can be better connected because of this nanostructured surface effect on the cells' responses to local changes in curvature and topography of the materials. This model is simple yet effectively shows the investigation of neuronal responses to morphological characteristics and electronic interfaces.
P3HT-Based Electroactive Films for In Vitro Neuronal Cell Interfacing
Messina G. M. L.
2025-01-01
Abstract
Numerous efforts have been made to address the mechanical mismatch between bioelectronic devices and tissues in the past few years. Interfaces that better mimic the properties of biological tissues can be produced with the support of organic materials, which have a unique combination of soft mechanical properties, biocompatibility, and ionic-electronic conduction, which match the properties of living systems and allow the signal to be transduced at the biotic-abiotic interface. In this context, Poly(3-hexylthiophene) (P3HT), a p-type semiconducting polymer, having good biocompatibility, electrical conductivity, and mechanical properties, is studied. In this work, a polymer blend of P3HT and multi-walled carbon nanotubes (MWCNT) is prepared and deposited on the surface as an electroactive thin film resulting in a tunable nanostructured surface. Further, the biological properties of this new substrate in vitro is evaluated. The conductive polymer-based substrate and the HT-22 cell line can be better connected because of this nanostructured surface effect on the cells' responses to local changes in curvature and topography of the materials. This model is simple yet effectively shows the investigation of neuronal responses to morphological characteristics and electronic interfaces.File | Dimensione | Formato | |
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