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Topographically Conductive Butterfly Wing Substrates for Directed Spiral Ganglion Neuron Growth

Hao Wei, Zhuoyue Chen, Yangnan Hu, Wei Cao, Xiaofeng Ma, Chen Zhang, Xia Gao, Xiaoyun Qian, Yuanjin Zhao, Renjie Chai

2021Small45 citationsDOI

Abstract

Spiral ganglion neuron (SGN) degeneration can lead to severe hearing loss, and the directional regeneration of SGNs has shown great potential for improving the efficacy of auditory therapy. Here, a novel 3D conductive microstructure with surface topologies is presented by integrating superaligned carbon-nanotube sheets (SA-CNTs) onto Morpho Menelaus butterfly wings for SGN culture. The parallel groove-like topological structures of M. Menelaus wings induce the cultured cells to grow along the direction of its ridges. The excellent conductivity of SA-CNTs significantly improves the efficiency of cellular information conduction. When integrating the SA-CNTs with M. Menelaus wings, the SA-CNTs are aligned in parallel with the M. Menelaus ridges, which further strengthens the consistency of the surface topography in the composite substrate. The SA-CNTs integrated onto butterfly wings provide powerful physical signals and regulate the behavior of SGNs, including cell survival, adhesion, neurite outgrowth, and synapse formation. These features indicate the possibility of directed regeneration after auditory nerve injury.

Topics & Concepts

Carbon nanotubeNeuriteMaterials scienceRegeneration (biology)Spiral ganglionNanotechnologyElectrical conductorNeuronAnatomyNeuroscienceComposite materialBiologyCell biologyInner earBiochemistryIn vitroAdvanced Materials and MechanicsNeuroscience and Neural EngineeringAdvanced Sensor and Energy Harvesting Materials
Topographically Conductive Butterfly Wing Substrates for Directed Spiral Ganglion Neuron Growth | Litcius