Fabrication and application of conductive biosurfaces
Neurons communicate via secretion of neurotransmitters which trigger electrical responses to modulate neuronal firings and consequently, animal behaviors. Therefore, monitoring these signals in neurons of ambulatory subjects is crucial to investigate the neural basis of behavior, a fundamental go...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2013
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| Online Access: | http://hdl.handle.net/10356/54780 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Neurons communicate via secretion of neurotransmitters which trigger electrical responses to modulate neuronal firings and consequently, animal
behaviors. Therefore, monitoring these signals in neurons of ambulatory subjects is crucial to investigate the neural basis of behavior, a fundamental goal in neuroscience. In addition, even as common diseases afflicting the elderly across the globe, there is no cure for such neurological disorders.
Neural electrode, designed and used to achieve recording of neural signals and
stimulating neurons in the central and peripheral nervous system has attracted
considerable interest as a potential approach for such neurological disorders. The
challenges for researchers in this field are, however, to obtain stable neural signals
for extended periods of time, which is often hindered by physiological environment,
high interfacial impedance, and foreign body response. The goal ofmy resersach in
this thesis is, therefore, to develop neural electrodes that facilitate electrical signal
recording with minimized cellular response.
In our research, we had mainly focused on the surface modification of neural
electrodes with nanostructured coatings consisting of conductive polymers and/or
carbon nanotubes (Cbl'Ts) with the aim to overcome the existing challenges and
explore possible solutions to improve the electrode performance, e.g. lowering the
interfacial impedance, enhancing the charge transfer capability, extending the
electrode life time, and improving the cell-electrode integration. Several
electrically conductive and cellular compatible nanostructured coatings consisting of conductive polymers and/or CNTs had been developed, including but not
restricted to porous multilayered polypyrrole (PPy)-coated multiwalled carbon
nanotube (MWCNT) films, highly porous and fibrillary-textured nanostructured
poly(3,4-ethylenedioxythiophene) (PEDOT) films, and vertically aligned PEDOT
nanotube arrays. When applying these nanostructures to microelectrodes,
significantly lower interfacial impedance, larger charge storage capacity, improved
electrochemical stability, and better cell-electrode integration have been observed.
We believe that these nanoengineered materials would be great canditates to
interface neural tissues and could contribute to the development of neural
engineering. |
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