SDSU researcher turning switchgrass into bioplastics

But as humans have become increasingly reliant on plastic, serious environmental issues, like the Great Pacific Garbage Patch, have emerged. A natural, plastic-like alternative is sorely needed and, according to South Dakota State University (Brookings, SD, USA) researcher Srinivas Janaswamy, a sustainable remedy is within reach.

Janaswamy’s research is on the leading edge of bioplastic development. Over the past few years, he has demonstrated how biodegradable films can be successfully created from a variety of agriculture byproducts, including avocado peels, and spent coffee grounds.

A new study from Janaswamy's lab has demonstrated how a transparent and strong biodegradable film can be derived from switchgrass (Pancium virgatum), a perennial prairie tallgrass native to North America.

In the United States, switchgrass grows abundantly and in a variety of different climates, making it a valuable resource for soil conservation, ornamental grass, heat production, and biofuels. Switchgrass is also composed of roughly 58 % lignocellulosic material, making it an ideal material for the development of plastic-replacing products.

To make the films, Janaswamy and his research team – which includes Sajal Bhattarai, an SDSU grad and a graduate research assistant at Purdue University – first extracted lignocellulosic material, the most abundant renewable biomass on Earth, from milled switchgrass. Lignocellulosic material, or plant dry matter, is composed of cellulose, hemicellulose, and lignin.

After the material was extracted, a filtration, bleaching, washing, and drying process resulted in a white residue that was then used to create the films. Once fully dried, the team assessed the film's qualities.

Results showed the films to be transparent, high in tensile strength and completely biodegradable within 40 days at 30 % soil moisture. The last characteristic – biodegradation – is crucial in the development of bioplastics as the primary challenge with petroleum-based plastics is their inability to degrade. For example, a plastic bottle will take more than 700 years to naturally degrade in soil. Bioplastics, ideally, would biodegrade in a fraction of that time, greatly reducing the amount of plastic waste in the environment.

"This research successfully demonstrates biodegradable, biocompatible, strong, and transparent films can be made from the lignocellulosic residue of switchgrass", Janaswamy said. "The film possesses high tensile strength, low water vapour permeability, and good biodegradability".

The one downside of the films is relatively low elongation, especially in comparison to synthetic films. Janaswamy attributes this to the structural nature of the rigid lignocellulose network structure. Plasticizers, liquids added to plastics to soften them, generally improve film flexibility and elongation. However, plasticizers were not tested in this particular study. Janaswamy notes this will be an area of interest for future research.

Outside of eliminating plastic waste and subsequently helping the environment, this work could help farmers in the region generate extra income, as the materials utilized for bioplastics are often either underused or not used at all.

"Our planet needs sustainable, economical and environmentally friendly solutions to address the repercussions of plastics", Janaswamy said. "The strong and biodegradable switchgrass residue-based films open up a new window of opportunities to design and develop reusable, recyclable and compostable films from underutilized, inexpensive and abundant agricultural biomass, contributing to the circular rural economy in a friendly and sustainable manner".

Financial support for this work was provided by the U.S. Department of Agriculture's National Institute of Food and Agriculture. The full study, which was published in the academic journal Resources, Conservation and Recycling under the title "Biodegradable films from the lignocellulosic residue of switchgrass", can be found following the link below. AT

https://doi.org/10.1016/j.resconrec.2023.107322
https://www.sdstate.edu/

Based on article by Addison Dehaven