The journal Advanced Materials has reported on the success of Israeli researchers in creating conductors that are relevant to solar energy generation, biomedical engineering, and more using by-products of the food industry that would otherwise be discarded as waste. The technology demonstrated in the article allows for the simple, fast, cost-effective, and environmentally friendly production of biopolymers, which include applications for electrophysiological signal sensing.
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The study was conducted under the leadership of Assistant Professor Nadav Amdursky, and doctoral students Ramesh Nandi and Yuval Agam.
According to Prof. Amdursky, “The current global green trend has not bypassed industry, and numerous groups worldwide are working on new solutions that will limit the pollution caused by the production of synthetic materials and by their very presence. One of the options is, of course, the use of natural materials, and the big challenge is to adapt them to meet needs.”
The two main approaches in environmentally conscious chemistry are environmental chemistry – the creation of environmentally friendly materials; and sustainable chemistry – production based on available degradable materials and energy-efficient processes.
The present research integrates the two approaches in an environmentally friendly production process that yields environmentally friendly products in the context of conductive polymers.
Polymers are long chains made up of thousands of building blocks called monomers.
Silk, wool, and cotton fibers are examples of natural polymers, whereas nylon and PVC are synthetic polymers. Conductive polymers are a subgroup of polymers, and they serve a vast variety of applications: electronics, energy storage, fuel cells, medicine, and others.
These polymers are currently produced using processes that are costly and cause pollution due to the use of derivatives of oil, gas, and fossil fuel.
The alternative proposed by the Technion research team is protein polymers – molecules that are present in different biological tissues such as silk and wool fibers, spider webs, hair, and nails. Here, as mentioned, they are by-products of the food industry that would otherwise be discarded as waste.
According to Prof. Amdursky, “The inspiration to use proteins to create conductive polymers originated in the unique function of proteins in nature – they are exclusively responsible for transporting various charge carriers in flora and fauna; for example, in cellular respiration or in photosynthesis in plants.”
The researchers created transparent polymer films with high conductivity. This film is suitable for biological and biomedical applications since it is non-toxic. It is biodegradable in the human body, and can be stretched to approximately 400% of its original length, without significantly impairing its electrical properties. Its conductivity is among the highest detected in biological materials.
According to Prof. Amdursky, “The production of the film in our research was a one-pot process, spontaneous, inexpensive, fast, energy efficient, and nonpolluting. In the article, we demonstrate the use of the film as ‘artificial skin’ that noninvasively monitors electrophysiological signals. These signals play a meaningful part in brain and muscle activity, and therefore their external monitoring is a highly important challenge.”
Prof. Amdursky emphasizes that since this technology is designed for application and commercialization, “the economic consideration is key, and consequently, it is most important to lower the costs of production processes so that they will yield a product that is competitive, also in terms of price, with petroleum-based polymers, and happily, we have succeeded.
This is in addition to the reduction in environmental damage in the production phase as well as during use. The new polymer is fully biodegradable in less than 48 hours, as opposed to synthetic polymers, which are not biodegradable and as result, pollute our planet.”
The research was sponsored by the Gutwirth Fund (Ramesh Nandi was awarded a scholarship), the United States – Israel Binational Science Foundation, the Ministry of Science and Technology, and a PhosAgro/UNESCO/IUPAC green chemistry research grant. The researchers thank the Nancy and Stephen Grand Technion Energy Program (GTEP) for its financial support through the NEVET program, and the Russell Berrie Nanotechnology Institute (RBNI) for the use of the Institute’s research infrastructure.