Ordered growth of neurons on diamond

Ordered growth of neurons on diamond

Diamond has a number of unique properties that make it an attractive electronic and bio-electronic material. Here we show the ordered growth of mammalian neurons, the principal electrogenic cells of the nervous system, on diamond. Proteins were specifically patterned on diamond surfaces by micro-con...

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Bibliographic Details
Published in:Biomaterials Vol. 25; no. 18; pp. 4073 - 4078
Main Authors: Specht, Christian G., Williams, Oliver A., Jackman, Richard B., Schoepfer, Ralf
Format: Journal Article
Language:English
Published: Netherlands Elsevier Ltd 01-08-2004
Subjects:
Adsorption
Animals
Biocompatibility
Cell Adhesion - physiology
Cell Culture Techniques - methods
Cell Division - physiology
Cell Polarity - physiology
Cell Survival - physiology
Cells, Cultured
Coated Materials, Biocompatible - chemistry
Diamond
Diamond - chemistry
Laminin
Laminin - chemistry
Laminin - pharmacology
Materials Testing
Mice
Micro-contact printing (μCP)
Network
Neuron
Neurons - cytology
Neurons - drug effects
Neurons - physiology
Tissue Engineering - methods
Micro-contact printing (μCP)
Biocompatibility
Diamond
Laminin
Neuron
Network
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Summary:Diamond has a number of unique properties that make it an attractive electronic and bio-electronic material. Here we show the ordered growth of mammalian neurons, the principal electrogenic cells of the nervous system, on diamond. Proteins were specifically patterned on diamond surfaces by micro-contact printing. Mouse cortical neurons were then cultured on these substrates. Neuron adhesion and outgrowth was specific for those areas of the diamond that had been stamped with laminin, resulting in ordered growth of high resolution. Neurons survived in culture for the duration of the experiment, and laminin patterns were stable for at least 1 week in culture. The relative biocompatibility of diamond and the suitability of neuron interfacing with the hydrogen surface conductivity layer make this an interesting model for the formation of defined neuronal networks and for implants.
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ISSN:0142-9612
1878-5905
DOI:10.1016/j.biomaterials.2003.11.006