Conjugated Polymers for Neural Interfaces : Prospects, possibilities and future challenges
Within the field of neuroprosthetics the possibility to use implanted electrodes for communication with the nervous system is explored. Much effort is put into the material aspects of the electrode implant to increase charge injection capacity, suppress foreign body response and build micro sized el...
Main Author: | |
---|---|
Format: | Doctoral Thesis |
Language: | English |
Published: |
KTH, Neuronik
2009
|
Subjects: | |
Online Access: | http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-9817 http://nbn-resolving.de/urn:isbn:978-91-7415-213-5 |
id |
ndltd-UPSALLA1-oai-DiVA.org-kth-9817 |
---|---|
record_format |
oai_dc |
spelling |
ndltd-UPSALLA1-oai-DiVA.org-kth-98172013-01-08T13:06:15ZConjugated Polymers for Neural Interfaces : Prospects, possibilities and future challengesengAsplund, MariaKTH, NeuronikStockholm : KTH2009neuroprostheticsconjugated polymersconducting polymersPEDOTfunctional electrical stimulationneural electrodesMedical engineeringMedicinsk teknikNeuroscienceNeurovetenskapFunctional materialsFunktionella materialWithin the field of neuroprosthetics the possibility to use implanted electrodes for communication with the nervous system is explored. Much effort is put into the material aspects of the electrode implant to increase charge injection capacity, suppress foreign body response and build micro sized electrode arrays allowing close contact with neurons. Conducting polymers, in particular poly(3,4-ethylene dioxythiophene) (PEDOT), have been suggested as materials highly interesting for such neural communication electrodes. The possibility to tailor the material both mechanically and biochemically to suit specific applications, is a substantial benefit with polymers when compared to metals. PEDOT also have hybrid charge transfer properties, including both electronic and ionic conduction, which allow for highly efficient charge injection. Part of this thesis describes a method of tailoring PEDOT through exchanging the counter ion used in electropolymerisation process. Commonly used surfactants can thereby be excluded and instead, different biomolecules can be incorporated into the polymer. The electrochemical characteristics of the polymer film depend on the ion. PEDOT electropolymerised with heparin was here determined to have the most advantageous properties. In vitro methods were applied to confirm non-cytotoxicity of the formed PEDOT:biomolecular composites. In addition, biocompatibility was affirmed for PEDOT:heparin by evaluation of inflammatory response and neuron density when implanted in rodent cortex. One advantage with PEDOT often stated, is its high stability compared to other conducting polymers. A battery of tests simulating the biological environment was therefore applied to investigate this stability, and especially the influence of the incorporated heparin. These tests showed that there was a decline in the electroactivity of PEDOT over time. This also applied in phosphate buffered saline at body temperature and in the absence of other stressors. The time course of degradation also differed depending on whether the counter ion was the surfactant polystyrene sulphonate or heparin, with a slightly better stability for the former. One possibility with PEDOT, often overlooked for biological applications, is the use of its semi conducting properties in order to include logic functions in the implant. This thesis presents the concept of using PEDOT electrochemical transistors to construct textile electrode arrays with in-built multiplexing. Using the electrolyte mediated interaction between adjacent PEDOT coated fibres to switch the polymer coat between conducting and non conducting states, then transistor function can be included in the conducting textile. Analogue circuit simulations based on experimentally found transistor characteristics proved the feasibility of these textile arrays. Developments of better polymer coatings, electrolytes and encapsulation techniques for this technology, were also identified to be essential steps in order to make these devices truly useful. In summary, this work shows the potential of PEDOT to improve neural interfaces in several ways. Some weaknesses of the polymer and the polymer electronics are presented and this, together with the epidemiological data, should point in the direction for future studies within this field. QC 20100623Doctoral thesis, comprehensive summaryinfo:eu-repo/semantics/doctoralThesistexthttp://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-9817urn:isbn:978-91-7415-213-5Trita-STH : report, 1653-3836 ; 2009:1application/pdfinfo:eu-repo/semantics/openAccess |
collection |
NDLTD |
language |
English |
format |
Doctoral Thesis |
sources |
NDLTD |
topic |
neuroprosthetics conjugated polymers conducting polymers PEDOT functional electrical stimulation neural electrodes Medical engineering Medicinsk teknik Neuroscience Neurovetenskap Functional materials Funktionella material |
spellingShingle |
neuroprosthetics conjugated polymers conducting polymers PEDOT functional electrical stimulation neural electrodes Medical engineering Medicinsk teknik Neuroscience Neurovetenskap Functional materials Funktionella material Asplund, Maria Conjugated Polymers for Neural Interfaces : Prospects, possibilities and future challenges |
description |
Within the field of neuroprosthetics the possibility to use implanted electrodes for communication with the nervous system is explored. Much effort is put into the material aspects of the electrode implant to increase charge injection capacity, suppress foreign body response and build micro sized electrode arrays allowing close contact with neurons. Conducting polymers, in particular poly(3,4-ethylene dioxythiophene) (PEDOT), have been suggested as materials highly interesting for such neural communication electrodes. The possibility to tailor the material both mechanically and biochemically to suit specific applications, is a substantial benefit with polymers when compared to metals. PEDOT also have hybrid charge transfer properties, including both electronic and ionic conduction, which allow for highly efficient charge injection. Part of this thesis describes a method of tailoring PEDOT through exchanging the counter ion used in electropolymerisation process. Commonly used surfactants can thereby be excluded and instead, different biomolecules can be incorporated into the polymer. The electrochemical characteristics of the polymer film depend on the ion. PEDOT electropolymerised with heparin was here determined to have the most advantageous properties. In vitro methods were applied to confirm non-cytotoxicity of the formed PEDOT:biomolecular composites. In addition, biocompatibility was affirmed for PEDOT:heparin by evaluation of inflammatory response and neuron density when implanted in rodent cortex. One advantage with PEDOT often stated, is its high stability compared to other conducting polymers. A battery of tests simulating the biological environment was therefore applied to investigate this stability, and especially the influence of the incorporated heparin. These tests showed that there was a decline in the electroactivity of PEDOT over time. This also applied in phosphate buffered saline at body temperature and in the absence of other stressors. The time course of degradation also differed depending on whether the counter ion was the surfactant polystyrene sulphonate or heparin, with a slightly better stability for the former. One possibility with PEDOT, often overlooked for biological applications, is the use of its semi conducting properties in order to include logic functions in the implant. This thesis presents the concept of using PEDOT electrochemical transistors to construct textile electrode arrays with in-built multiplexing. Using the electrolyte mediated interaction between adjacent PEDOT coated fibres to switch the polymer coat between conducting and non conducting states, then transistor function can be included in the conducting textile. Analogue circuit simulations based on experimentally found transistor characteristics proved the feasibility of these textile arrays. Developments of better polymer coatings, electrolytes and encapsulation techniques for this technology, were also identified to be essential steps in order to make these devices truly useful. In summary, this work shows the potential of PEDOT to improve neural interfaces in several ways. Some weaknesses of the polymer and the polymer electronics are presented and this, together with the epidemiological data, should point in the direction for future studies within this field. === QC 20100623 |
author |
Asplund, Maria |
author_facet |
Asplund, Maria |
author_sort |
Asplund, Maria |
title |
Conjugated Polymers for Neural Interfaces : Prospects, possibilities and future challenges |
title_short |
Conjugated Polymers for Neural Interfaces : Prospects, possibilities and future challenges |
title_full |
Conjugated Polymers for Neural Interfaces : Prospects, possibilities and future challenges |
title_fullStr |
Conjugated Polymers for Neural Interfaces : Prospects, possibilities and future challenges |
title_full_unstemmed |
Conjugated Polymers for Neural Interfaces : Prospects, possibilities and future challenges |
title_sort |
conjugated polymers for neural interfaces : prospects, possibilities and future challenges |
publisher |
KTH, Neuronik |
publishDate |
2009 |
url |
http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-9817 http://nbn-resolving.de/urn:isbn:978-91-7415-213-5 |
work_keys_str_mv |
AT asplundmaria conjugatedpolymersforneuralinterfacesprospectspossibilitiesandfuturechallenges |
_version_ |
1716509080832442368 |