Photopolymerized microfeatures for directed spiral ganglion neurite and Schwann cell growth

Abstract Cochlear implants (CIs) provide auditory perception to individuals with severe hearing impairment. However, their ability to encode complex auditory stimuli is limited due, in part, to poor spatial resolution caused by electrical current spread in the inner ear. Directing nerve cell process...

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Bibliographic Details
Published in:Biomaterials 2013-01, Vol.34 (1), p.42-54
Main Authors: Tuft, Bradley W, Li, Shufeng, Xu, Linjing, Clarke, Joseph C, White, Scott P, Guymon, Bradley A, Perez, Krystian X, Hansen, Marlan R, Guymon, C. Allan
Format: Article
Language:English
Subjects:
Advanced Basic Science
Animals
Astrocytes - cytology
Astrocytes - metabolism
Cell Proliferation
Dentistry
Light
Linear Models
Micropatterning
Nanoparticles - ultrastructure
Nerve guide
Neural prosthesis
Neurites - metabolism
Neuroglia - cytology
Neuroglia - metabolism
Periodicity
Photopolymerization
Polymerization - radiation effects
Polymers - chemical synthesis
Polymers - chemistry
Rats
Schwann Cells - cytology
Schwann Cells - metabolism
Spiral Ganglion - cytology
Spiral Ganglion - metabolism
Surface topography
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Summary:Abstract Cochlear implants (CIs) provide auditory perception to individuals with severe hearing impairment. However, their ability to encode complex auditory stimuli is limited due, in part, to poor spatial resolution caused by electrical current spread in the inner ear. Directing nerve cell processes towards target electrodes may reduce the problematic current spread and improve stimulatory specificity. In this work, photopolymerization was used to fabricate micro- and nano-patterned methacrylate polymers to probe the extent of spiral ganglion neuron (SGN) neurite and Schwann cell (SGSC) contact guidance based on variations in substrate topographical cues. Micropatterned substrates are formed in a rapid, single-step reaction by selectively blocking light with photomasks which have parallel line-space gratings with periodicities of 10–100 μm. Channel amplitudes of 250 nm–10 μm are generated by modulating UV exposure time, light intensity, and photoinitiator concentration. Gradual transitions are observed between ridges and grooves using scanning electron and atomic force microscopy. The transitions stand in contrast to vertical features generated via etching lithographic techniques. Alignment of neural elements increases significantly with increasing feature amplitude and constant periodicity, as well as with decreasing periodicity and constant amplitude. SGN neurite alignment strongly correlates ( r  = 0.93) with maximum feature slope. Multiple neuronal and glial types orient to the patterns with varying degrees of alignment. This work presents a method to fabricate gradually-sloping micropatterns for cellular contact guidance studies and demonstrates spatial control of inner ear neural elements in response to micro- and nano-scale surface topography.
ISSN:0142-9612
1878-5905
DOI:10.1016/j.biomaterials.2012.09.053