Optimization of Silk Films for Use in Composite Conducting Polymer Actuator Devices
Research Mentor(s)
Murphy, Amanda R.
Description
The biocompatibility of conducting polymers (CPs) makes them promising for a variety of biomedical applications such as devices capable of biomimetic movements (artificial muscles). CPs are capable of expansion or contraction when an electric potential is applied in the presence of electrolyte, allowing them to function as actuators in biological fluids. Unfortunately, CPs are brittle and difficult to process. We have developed a method to create an interpenetrating network of silk and CP that combines the excellent mechanical strength of silk and the conductive properties of the polymer, while maintaining biocompatibility. These composite films have been shown to function as actuators in biologically relevant electrolytes. Here, we explore three methods to further optimize and expand the versatility of these composites: 1) Nanopatterning. Methods to produce silk substrates with nanoscale grooves are being developed. These parallel grooves are anticipated to enhance bilayer actuation and dictate direction of movement. 2) Decreasing beta-sheet content. The beta-sheet crystalline regions of regenerated silk films give them mechanical strength, but in excess cause brittleness. Various annealing methods are evaluated to control beta-sheet content and improve flexibility. 3) Silk-chitin films. The addition of chitin nanofibers to silk films is evaluated to improve mechanical properties, conductivity, and actuation.
Document Type
Event
Start Date
14-5-2015 10:00 AM
End Date
14-5-2015 2:00 PM
Department
Chemistry
Genre/Form
student projects; posters
Subjects – Topical (LCSH)
Silk; Conducting polymers; Tissue engineering
Type
Image
Rights
Copying of this document in whole or in part is allowable only for scholarly purposes. It is understood, however, that any copying or publication of this documentation for commercial purposes, or for financial gain, shall not be allowed without the author's written permission.
Language
English
Format
application/pdf
Optimization of Silk Films for Use in Composite Conducting Polymer Actuator Devices
The biocompatibility of conducting polymers (CPs) makes them promising for a variety of biomedical applications such as devices capable of biomimetic movements (artificial muscles). CPs are capable of expansion or contraction when an electric potential is applied in the presence of electrolyte, allowing them to function as actuators in biological fluids. Unfortunately, CPs are brittle and difficult to process. We have developed a method to create an interpenetrating network of silk and CP that combines the excellent mechanical strength of silk and the conductive properties of the polymer, while maintaining biocompatibility. These composite films have been shown to function as actuators in biologically relevant electrolytes. Here, we explore three methods to further optimize and expand the versatility of these composites: 1) Nanopatterning. Methods to produce silk substrates with nanoscale grooves are being developed. These parallel grooves are anticipated to enhance bilayer actuation and dictate direction of movement. 2) Decreasing beta-sheet content. The beta-sheet crystalline regions of regenerated silk films give them mechanical strength, but in excess cause brittleness. Various annealing methods are evaluated to control beta-sheet content and improve flexibility. 3) Silk-chitin films. The addition of chitin nanofibers to silk films is evaluated to improve mechanical properties, conductivity, and actuation.