This study considered the use of various inherently conducting polymer (ICP)-based devices for utilisation with the cochlear implant. Investigations centred on the use of polypyrrole (PPy) to produce a mechanical sensor, actuators and controlled release devices. The development of a novel force sensor using the electrodes that are an integrated part of the cochlear implant itself was also investigated. Investigation into mechanically induce electrical signals using PPybased mechanical sensors showed that the polarity of the voltage output was dependent on the dopant ion in the conducting polymer. In addition, it was found that the signal amplitude was related to the redox state of the PPy and the concentration of mobile dopant ions within the PPy. This led to the “stress induced ion flux” mechanism being proposed for the first time to explain such observations. Actuator systems developed in this study included a PPy trilayer bending actuator, a PPy microfluidic pump and a PPy-coated hollow fibre. The study of PPy trilayer actuators led to several findings including a high amplitude harmonic vibration using a PPy/TFSI trilayer actuator, the first time that such behaviour has been observed for ICP-based mechanical actuators. A study of the blocking forces generated using such actuators in ionic liquid electrolytes suggested that switching from cathodic contraction to cathodic expansion occurs under the application of reducing potentials. This switching behaviour was found to depend on the amplitude and time of the electrochemical stimulation employed. It was shown that the expulsion of the dopant anion (PF6-) from the reduced polymer (- 0.8 V vs. Ag/Ag+) did not support the previously claimed cathodic expansion model. An ion diffusion controlled mechanism was proposed to explain the results obtained. Investigations into the novel “tube in tube actuator nodule” (TITAN) microfluidic pump based on PPy had led to the significant finding that, for the first time, the intrinsic resistance of PPy can be utilised to carry out peristaltic actuation for the purpose of fluid transport. The electrochemically controlled release of a model anion from the internal volume of a PPy-coated platinised PVDF hollow fibre was successfully demonstrated. Such controlled release was ascribed to the electrochemically activated incorporation / expulsion of small anions upon redox switching of polypyrrole resulting in enhanced ion transport across the concentration gradient from the internal volume of the hollow fibre to the receiving solution. The experimental findings suggested that electrochemically controlled release of anionic drugs is a real possibility using a device configuration consisting of a reservoir coated with an ICP membrane. By studying the electrochemical impedance changes in response to impact forces on the tip of a cochlear implant in artificial perilymph solution, it was found that the cochlear implant electrode itself can be used to detect impact forces. The findings were significant because such an approach provides a simple and safe method for the detection of possible dangers during surgical implantation of the cochlear implant. Factors influencing the response were investigated and these included solution composition and the orientation of the impact forces encountered.
History
Citation
Wu, Yanzhe, Sensors and actuators for the cochlear implant using inherently conducting polymers, PhD thesis, Department of Chemistry, University of Wollongong, 2006. http://ro.uow.edu.au/theses/172
Year
2006
Thesis type
Doctoral thesis
Faculty/School
Department of Chemistry
Language
English
Disclaimer
Unless otherwise indicated, the views expressed in this thesis are those of the author and do not necessarily represent the views of the University of Wollongong.