Nature and Biodiversity

This material made from crabs could cut plastic pollution

Workers unload bushel baskets of live blue crabs into a large carriage before pressure steaming them at the A.E. Phillips & Son Inc. crab picking house on Hooper's Island in Fishing Creek, Maryland August 26, 2015. Young people in the small rural shore towns of Chesapeake Bay, which straddles the eastern U.S. states of Maryland and Virginia, are shunning the erratic pay of "watermen", who catch crabs using skills such as baiting a crab pot or handling a trotline, previously passed down through the generations. Seasonal workers from Mexico fill many of the manual jobs in picking houses to process the crustaceans. The industry faces other headwinds, environmental issues and an increasingly global agricultural market among them. Last year's harvest was the lowest recorded in 25 years after the crab population crashed in the 1990s and early 2000s. REUTERS/Jonathan Ernst TPX IMAGES OF THE DAY PICTURE 18 OF 29 FOR WIDER IMAGE STORY "CRAB CATCHING BLUES"SEARCH "CRABS BLUES" FOR ALL IMAGES       TPX IMAGES OF THE DAY      - GF10000243007

The material is partly comprised of chitosan, derived from chitin, which is found in crab shells. Image: REUTERS/Jonathan Ernst

Jeff Mulhollem
Public Relations Specialist/Science Writer, Penn State University

Researchers have created a new kind of biomaterial that could be used to replace plastic coatings in packaging of foods and other items, cutting down on pollution that results from its use and production.

Completely compostable, the material—a polysaccharide polyelectrolyte complex—is comprised of nearly equal parts of treated cellulose pulp from wood or cotton, and chitosan, which is derived from chitin—the primary ingredient in the exoskeletons of arthropods and crustaceans.

The main source of chitin is the mountains of leftover shells from lobsters, crabs, and shrimp that humans consume.

These environmentally friendly barrier coatings have numerous applications ranging from water-resistant paper, to coatings for ceiling tiles and wallboard, to food coatings to seal in freshness, according to lead researcher Jeffrey Catchmark, a professor of agricultural and biological engineering at Penn State.

“The material’s unexpected strong, insoluble adhesive properties are useful for packaging as well as other applications, such as better performing, fully natural wood-fiber composites for construction and even flooring,” he says. “And the technology has the potential to be incorporated into foods to reduce fat uptake during frying and maintain crispness. Since the coating is essentially fiber-based, it is a means of adding fiber to diets.”

The amazingly sturdy and durable bond between carboxymethyl cellulose and chitosan is the key, he explained. The two very inexpensive polysaccharides—already used in the food industry and in other industrial sectors—have different molecular charges and lock together in a complex that provides the foundation for impervious films, coatings, adhesives, and more.

The potential reduction of pollution is immense if these barrier coatings replace millions of tons of petroleum-based plastic associated with food packaging used every year in the United States—and much more globally, Catchmark notes.

He points out that the global production of plastic is approaching 300 million tons per year. In a recent year, more than 29 million tons of plastic became municipal solid waste in the United States and almost half was plastic packaging. It is anticipated that 10 percent of all plastic produced globally will become ocean debris, representing a significant ecological and human health threat.

The polysaccharide polyelectrolyte complex coatings performed well in research, the findings of which were published recently in Green Chemistry. Paperboard coated with the biomaterial, comprised of nanostructured fibrous particles of carboxymethyl cellulose and chitosan, exhibited strong oil and water barrier properties. The coating also resisted toluene, heptane and salt solutions and exhibited improved wet and dry mechanical and water vapor barrier properties.

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“These results show that polysaccharide polyelectrolyte complex-based materials may be competitive barrier alternatives to synthetic polymers for many commercial applications,” says Catchmark, who, in concert with Penn State, has applied for a patent on the coatings.

“In addition, this work demonstrates that new, unexpected properties emerge from multi-polysaccharide systems engaged in electrostatic complexation, enabling new high-performance applications.”

Catchmark began experimenting with biomaterials that might be used instead of plastics a decade or so ago out of concerns for sustainability. He became interested in cellulose, the main component in wood, because it is the largest volume sustainable, renewable material on earth. Catchmark studied its nanostructure—how it is assembled at the nanoscale.

He believed he could develop natural materials that are more robust and improve their properties, so that they could compete with synthetic materials that are not sustainable and generate pollution—such as the low-density polyethylene laminate applied to paper board, Styrofoam, and solid plastic used in cups and bottles.

“The challenge is, to do that you’ve got to be able to do it in a way that is manufacturable, and it has to be less expensive than plastic,” Catchmark explains. “Because when you make a change to something that is greener or sustainable, you really have to pay for the switch. So it has to be less expensive in order for companies to actually gain something from it. This creates a problem for sustainable materials—an inertia that has to be overcome with a lower cost.”

Catchmark currently is working to develop commercialization partners in different industry sectors for a wide variety of products.

“We are trying to take the last step now and make a real impact on the world, and get industry people to stop using plastics and instead use these natural materials,” he says. “So they (consumers) have a choice—after the biomaterials are used, they can be recycled, buried in the ground, or composted, and they will decompose. Or they can continue to use plastics that will end up in the oceans, where they will persist for thousands of years.”

The US Department of Agriculture supported this work. Southern Champion Tray, of Chattanooga, Tennessee, provided paperboard and information on its production for experiments.

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