Periodic Reporting for period 1 - BIKE (Bioconductive Iongels for Cutaneous Electrophysiology)
Okres sprawozdawczy: 2018-01-01 do 2019-12-31
This has a number of limitations: the aqueous hydrogel dries out after several hours causing the loss of electrophysiological signal, the water evaporation causes short circuits and refilling the aqueous hydrogel is time-consuming and discomfortable.
This project addresses these problems associated with the use of water-based electrolytes through the development of a new generation of gels, bioconductive iongels.
The healthcare sector needs a new generation of materials with soft mechanical properties and superior ionic/electrical conductivity in order to interface between human tissue and electronics. For example, as discussed above, the performance of commercial, widely used cutaneous electrodes is limited due to the poor stability of the electronic-skin interface. Consequently, this project is potentially high social impact and it will lead to the development of new materials to improve the electronic-skin interface ensuring the adequate acquisition of electrical signals to monitor the activity of an organ. Higher- quality data will enable the early detection of different diseases related to the heart, brain or muscles, such as arrhythmias, epilepsy or muscular problems.
To overcome problems associated with the use of water-based electrolytes in electrophysiological diagnostic procedures, this project aims to develop innovative materials: iongels, ionic liquid integrated into a polymer network. Due to the negligible vapor pressure of ionic liquids, long-term recordings can be made without the problem of evaporation. Moreover, the iongel can decrease impedance at the interface with a patient’s skin, thus improving the stability of the electronic-skin interface. The iongels have been fabricated ensuring good adhesion, biocompatibility with skin, conductivity and biodegradability.
Overall, the focus of this project is to create a new generation of bioconductive iongels and determine the potential of these state-of-the-art materials for improving the performance and lifetime of electrical health monitoring systems.
A new conducting hydrogel with high Na+ content has been prepared to use in organic electronic devices. This novel hydrogel was synthesized by the photopolymerization of poly(ethylene glycol)-dimethacrylate and sodium acrylate. Specifically, an organic electrochemical transistor (OECT) has been fabricated to use the Na+- hydrogel. The vast majority of the OECTs reported in literature operate using a liquid aqueous electrolyte. We show that the performance of the Na+ hydrogel in OECTs is as good as the performance of the common liquid electrolytes used for OECTs, but with the Na+- hydrogel the stability of the device is higher.
In order to understand the electronic - skin cell interactions, a 3D platform able to host and monitor the cell growth has been prepared. To develop the 3D platform, an electrically conductive polymer, PEDOT and a natural polysaccharide, Xantham Gum, has been combined.
To enhance the electrophysiological recordings, materials that can reduce impedance across the interface between the electrode and the skin have been synthesised : PEDOT:PSS/Ionic Liquid films. PEDOT:PSS/Ionic Liquid films are PEDOT polymers that can retain ionic liquid, combining ionic and electronic conduction to fabricated all-in-one electrodes.
Finally new electroactive materials that can incorporate bio(functionality) or thermoresponsiveness have been designed.
The exploitation and dissemination of the scientific results was done through publications in peer reviewed international journals and presentations at international conferences. During this year, I deliver oral communications in two international conferences and I publish five articles .
Moreover, the outreach activities of these findings are likely to generate great public interest, providing European citizens with greater awareness about the actions that the EU is undertaking to improve their health and social wealth (Horizon 2020 program).