MRS Bulletin Materials News Podcast

Episode 5: Inkjet-printed material tailored for biocompatible wearable electronics

MRS Bulletin Season 5 Episode 5

In this podcast episode, MRS Bulletin’s Sophia Chen interviews Prof. Esma Ismailova and graduate student Marina Galliani from Mines Saint-Etienne about their work toward creating biocompatible, eco-friendly materials for wearable electronics. For this particular project, they developed a conducting material based on a commercial polymer known as PEDOT-PSS, in a water-based solution. They combined it with various solvents to tune the electrical conductivity, which is dependent on the shape and structure of the polymers in the material as they dry. The researchers tested the material’s conductivity on several substrates, including paper-based substrates and textiles. To make the material printable, they also needed to tune the material’s viscosity. Because the material relies on inkjet printers that are already commonly available, this material is relatively easy to incorporate into industrial processes. This work was published in a recent issue of APL Bioengineering

SOPHIA CHEN: Welcome to MRS Bulletin’s Materials News Podcast, providing breakthrough news & interviews with researchers on the hot topics in materials research. My name is Sophia Chen. Marina Galliani and her team have designed a wearable step counter, which can be incorporated into a sock. It counts your steps because it’s got flexible electrodes on it that complete a circuit when you put your foot down. 

MARINA GALLIANI: We are measuring the open and closed circuit state of our device.

SOPHIA CHEN: Galliani’s key innovation is the material that makes up the electrodes. She’s a materials scientist graduate student working in Esma Ismailova’s lab at Mines Saint-Etienne. They’re working to create biocompatible, eco-friendly materials for wearables, as Ismailova explains.

ESMA ISMAILOVA: We’ll try to combine organic electronic materials with biology at different levels.

SOPHIA CHEN: For this particular project, they developed a conducting material that they can make using an inkjet printer. This means they can fabricate devices by printing, which uses up less material than traditional manufacturing methods.

ESMA ISMAILOVA: We're reducing the waste generation by processing these materials.

SOPHIA CHEN: They made the material based on a commercial polymer known as PEDOT-PSS, in a water-based solution. They combined it with various solvents to tune the electrical conductivity. The conductivity is based on the shape and structure of the polymers in the material as they dry. So to tune the material’s conductivity, Galliani alters the solvents in the material. This changes the alignment of the polymers in the material as it dries. They tested the material’s conductivity on several substrates, including paper-based substrates and textiles. To make the material printable, they also needed to tune the material’s viscosity.

MARINA GALLIANI: Since we start with a water-based solution, this fluid has surface tension that is close to that of water. In this case, for inkjet printing application, this value is too high. The surfactant is mainly used to reduce the surface tension of the liquid.

SOPHIA CHEN: To characterize the material, they ran many different tests. They tested the material’s ability to withstand wetting. 

ESMA ISMAILOVA: Imagine you're wearing this device against your skin and you're sweating. So sweat can dissolve the PEDOT-PSS itself. 

SOPHIA CHEN: To keep the material from dissolving, they added crosslinker to the material to help it link with the substrate. They also tested its mechanical properties by bending it. They were able to bend the material over a radius of 800 microns, which is beyond the usual requirements for wearable electronics.

ESMA ISMAILOVA: The bending radius in the flexible electronics is set to one millimeter.

SOPHIA CHEN: To test its biocompatibility, they put the ink on a glass slide and cultured human stem cells on top of it.

ESMA ISMAILOVA: In our case, the cell continued growing and developed as a normal to the standard way.

SOPHIA CHEN: Other than the material itself, Ismailova says that they’ve developed a framework for designing and evaluating biocompatible organic materials that others can use. For future directions, Ismailova says they want to find more applications for the material. She’s open to collaborations in industry to scale up the material. Because the material relies on inkjet printers that are already commonly available, this material is relatively easy to incorporate into industrial processes.

ESMA ISMAILOVA: The processes that we use here are quite straightforward transferable to industry.

SOPHIA CHEN: This work was published in a recent issue of APL Bioengineering. My name is Sophia Chen from the Materials Research Society. For more news, log onto the MRS Bulletin website at mrsbulletin.org and follow us on twitter, @MRSBulletin. Don’t miss the next episode of MRS Bulletin Materials News – subscribe now. Thank you for listening.