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High Oxygen Barrier Packaging Materials from Protein-rich Single-Celled Organisms

2025 2 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 48 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Kiran Reddy Baddigam, Kiran Reddy Baddigam, Kiran Reddy Baddigam, Kiran Reddy Baddigam, Elodie Guilloud, Mikael S. Hedenqvist, Mikael S. Hedenqvist, Mikael S. Hedenqvist, Bor Shin Chee, Elodie Guilloud, Bor Shin Chee, Kiran Reddy Baddigam, Kiran Reddy Baddigam, Mikael S. Hedenqvist, Elodie Guilloud, Mikael S. Hedenqvist, Elodie Guilloud, Elodie Guilloud, Anna J. Svagan, Bor Shin Chee, Elodie Guilloud, Mikael S. Hedenqvist, Anna J. Svagan, Bor Shin Chee, Chaitra Venkatesh, Chaitra Venkatesh, Mikael S. Hedenqvist, Mikael S. Hedenqvist, Helena Koninckx, Helena Koninckx, Helena Koninckx, Margaret Brennan Fournet Helena Koninckx, Kim Windey, Anna J. Svagan, Kim Windey, Mikael S. Hedenqvist, Kim Windey, Kim Windey, Kim Windey, Margaret Brennan Fournet Margaret Brennan Fournet Margaret Brennan Fournet Kim Windey, Mikael S. Hedenqvist, Anna J. Svagan, Mikael S. Hedenqvist, Mikael S. Hedenqvist, Mikael S. Hedenqvist, Mikael S. Hedenqvist, Anna J. Svagan, Anna J. Svagan, Mikael S. Hedenqvist, Margaret Brennan Fournet Margaret Brennan Fournet Mikael S. Hedenqvist, Margaret Brennan Fournet

Summary

Researchers developed bioplastic packaging films and trays from protein-rich single-celled microbial biomass using glycerol as a plasticizer, producing materials with good mechanical strength and an exceptionally low oxygen transmission rate. The resulting materials outperformed many conventional fossil-based packaging films on oxygen barrier performance while offering a renewable and biodegradable alternative.

Fossil-based plastics pose significant environmental challenges due to their persistence and carbon footprint, resulting in pollution and long-term climate change. In the present study innovative bioplastic films and trays for packaging applications were developed from protein-rich microbial biomass with glycerol as the plasticizer. The microbial biomass demonstrated excellent film-forming properties through compression molding, and the final materials exhibited good mechanical properties and excellent gas barrier properties - an average oxygen permeability coefficient of 0.33 cm3 mm m-2 day-1 atm-1 at 50% relative humidity and 23 °C. The oxygen barrier properties highlight these microbial biomass materials as a promising, sustainable alternative to fossil-based synthetic films like EVOH, which are widely used in multilayer food packaging. Beyond offering a microplastic-free solution, the protein-rich materials present an opportunity to mitigate microplastic pollution at the end of their lifecycle. The current results position bioplastics based on microbial biomass as a critical step forward in addressing environmental sustainability challenges with current commercial packaging materials.

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