Nanoparticles of Push–Pull Triphenylamine-Based Molecules for Light-Controlled Stimulation of Neuronal Activity

Abstract: Organic semiconductor materials with a unique set of properties are very attractive for interfacing biological objects and can be used for noninvasive therapy or detection of biological signals. Here, we describe the synthesis and investigation of a novel series of organic push−pull conjugated molecules with the starshaped architecture, consisting of triphenylamine as a branching electron donor core linked through the thiophene π-spacer to electron-withdrawing alkyl-dicyanovinyl groups. The molecules could for… Show more

“…Functional nanomaterials with photoelectric conversion properties can selectively target a certain cell type and generate a local electric field under light irradiation. The photoelectric effect can directly change the cell membrane's electrochemical equilibrium and activate voltage-gated ion channels for neuromodulation (Luponosov et al 2024). For example, quantum dots (QDs) are semiconductor nanoparticles that show discrete energy levels, spectrally sharp emission, and high quantum efficiency under visible light illumination.…”

Functional nanotransducer-mediated wireless neural modulation techniques

“…Functional nanomaterials with photoelectric conversion properties can selectively target a certain cell type and generate a local electric field under light irradiation. The photoelectric effect can directly change the cell membrane's electrochemical equilibrium and activate voltage-gated ion channels for neuromodulation (Luponosov et al 2024). For example, quantum dots (QDs) are semiconductor nanoparticles that show discrete energy levels, spectrally sharp emission, and high quantum efficiency under visible light illumination.…”

Functional nanotransducer-mediated wireless neural modulation techniques