Groundbreaking biodegradable film keeps food fresh for longer

A derivative of limonene from citrus rind, blended with chitosan, a biopolymer from exoskeletons of crustaceans

Computer generated image of packaging materials derived from petroleum. (CREDIT: Creative Commons)

Indiscriminate use of packaging materials derived from petroleum has led to a huge buildup of plastic in landfills and the ocean, as these materials have low degradability and are not significantly recycled. To mitigate this problem and meet growing demand for products that are safe for human health and the environment, the food industry is investing in the development of more sustainable packaging alternatives that preserve nutritional quality as well as organoleptic traits such as color, taste, smell and texture.

An example is a film made of a compound derived from limonene, the main component of citrus fruit peel, and chitosan, a biopolymer derived from the chitin present in exoskeletons of crustaceans.

The film was developed by a research group in São Paulo state, Brazil, comprising scientists in the Department of Materials Engineering and Bioprocesses at the State University of Campinas’s School of Chemical Engineering (FEQ-UNICAMP) and the Packaging Technology Center at the Institute of Food Technology (ITAL) of the São Paulo State Department of Agriculture and Supply, also in Campinas.

The results of the research are reported in an article published in Food Packaging and Shelf Life.


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“We focused on limonene because Brazil is one of the world’s largest producers of oranges [if not the largest] and São Paulo is the leading orange-producing state,” said Roniérik Pioli Vieira, last author of the article and a professor at FEQ-UNICAMP.

Limonene has been used before in film for food packaging to enhance conservation thanks to its antoxidant and anti-microbial action, but its performance is impaired by volatility and instability during the packaging manufacturing process, even on a laboratory scale.

This is one of the obstacles to the use of bioactive compounds in commercial packaging. It is often produced in processes that involve high temperatures and high shear rates due to cutting or shaping. Bioactive additives easily degrade in these processes.

The material was designed by Brazilian researchers and includes a derivative of limonene from citrus rind, blended with chitosan, a biopolymer from exoskeletons of crustaceans, (CREDIT: FEQ-UNICAMP)

“To solve this problem, we came up with the idea of using a derivative of limonene called poly(limonene), which isn’t volatile or particularly unstable,” Vieira said.

The researchers chose chitosan for the film matrix because it is a polymer of natural origin and has well-known antoxidant and anti-microbial properties. Their hypothesis was that combining the two materials would produce a film with enhanced bioactive properties.

In the laboratory, the scientists compared films with limonene and poly(limonene) in varying proportions to address the challenge of finding a way to combine them with chitosan, since theoretically they do not mix. The researchers opted for polymerization, a process in which polymers is made from smaller organic molecules.

In this case, they used a compound with polar chemical functions to start the reaction and to increase interaction between the additive and the polymer matrix. They then analyzed the resulting film to evaluate properties such as antioxidant capacity, light and water vapor protection, and resistance to high temperatures.

The results were highly satisfactory. “The films with the poly(limonene) additive outperformed those with limonene, especially in terms of antoxidant activity, which was about twice as potent,” Vieira said. The substance also performed satisfactorily as an ultraviolet radiation blocker and was found to be non-volatile, making it suitable for large-scale production of packaging, where processing conditions are more severe.

The films are not yet available for use by manufacturers, mainly because chitosan-based plastic is not yet produced on a sufficiently large scale to be competitive, but also because the poly(limonene) production process needs to be optimized to improve yield and to be tested during the manufacturing of commercial packaging.

“Our group is working on this. We’ve investigated other applications of poly(limonene) in the biomedical field, for example. We’re trying to demonstrate the multifunctionality of this additive, whose origins are renewable,” Vieira said.

The study was funded by FAPESP via two projects (20/14837-3 and 21/04043-2).


Note: Materials provided by Fundação de Amparo à Pesquisa do Estado de São Paulo. Content may be edited for style and length.

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Joseph Shavit
Joseph ShavitSpace, Technology and Medical News Writer
Joseph Shavit is the head science news writer with a passion for communicating complex scientific discoveries to a broad audience. With a strong background in both science, business, product management, media leadership and entrepreneurship, Joseph possesses the unique ability to bridge the gap between business and technology, making intricate scientific concepts accessible and engaging to readers of all backgrounds.