High Gas Barrier Coating Using Non-Toxic Nanosheet Dispersions for Flexible Food Packaging Film

Our nanosheet-based barrier coating gives an environmentally friendlier alternative to the metallised films used in food packaging. This new coating formulation is recyclable, non-toxic and highly efficient at preventing oxygen and water vapour from getting to your snacks.
High Gas Barrier Coating Using Non-Toxic Nanosheet Dispersions for Flexible Food Packaging Film

Open a packet of crisps or a bag of candy, and there it is: the shiny metallised film that keeps our snacks pleasantly crisp and fresh. Structurally, it is a polymer (often PET, polyethylene terephthalate) film coated with a thin layer of a metal, usually aluminium. The glossy looks of such metallised films are a comforting reassurance that our crisps and popcorn are protected from the oxygen and moisture in the environment, thus extending their shelf life.

But these metallised films have a less shiny side to them – their inability to be easily recycled and the high carbon footprint used in their production. Metallised films are also non-transparent, which is a distinct disadvantage when you want to show off the product inside your food packaging, and attract unsuspecting and hungry shoppers on their way to check-out.

So we decided to turn our attention to these current environmental and practical concerns over non-degradable plastics.

Our low energy alternative barrier coating for food packaging eliminates the metallic layer from the polymer packaging film – so not only is it much easier to recycle, completely non-toxic and mechanically stronger than metallised film, it is transparent and has a lower carbon footprint. It is even microwavable.

Our barrier properties arise from a synthetic inorganic material, a layered double hydroxide (LDH), which is prepared by a reconstruction method that allows the formation of high aspect ratio nanosheets. When embedded in a PVA (polyvinyl alcohol) matrix and coated onto a PET film, these nanosheets form what is essentially a complex labyrinth that oxygen or water molecules need to traverse in order to reach the food contained within the packaging (a mechanism known as the “tortuous pathway”). And much like the average person when they encounter a labyrinth: most of the molecules do not enter or eventually just go back the way they came, never reaching the crisps or popcorn we are protecting in the middle of the LDH labyrinth.

Because the LDHs we are using are entirely synthetic (unlike some clays that have been previously used in barrier applications), we can tailor them to be entirely non-toxic, free of any heavy metal traces. Consequently, non-toxic LDHs have been FDA approved as a safe food contact material.

Our experiments have shown the LDH-based barrier coatings to result in extremely low OTR (oxygen transmission rate) and WVTR (water vapour transmission rate) values, and their suitability has been further confirmed by theoretical calculations. We have quantified this improvement of barrier properties by introducing a barrier improvement factor (BIF), and determined that compared to commercial metallised films, our non-toxic LDH nanosheet-based coatings give a BIF that is 40 times higher. 

Our sponsors are in the process of up-scaling this technology to make trial packaging for a wide range of food. So whether its crisps, candy, or a microwave meal, you'll soon be choosing which snacks you want to accompany your Netflix through our transparent, recyclable, low-energy packaging.

DOI: 10.1038/s41467-019-10362-2

Please sign in or register for FREE

If you are a registered user on Research Communities by Springer Nature, please sign in

Subscribe to the Topic

Electrical and Electronic Engineering
Technology and Engineering > Electrical and Electronic Engineering

Related Collections

With collections, you can get published faster and increase your visibility.

Pre-clinical drug discovery

We welcome studies reporting advances in the discovery, characterization and application of compounds active on biologically or industrially relevant targets. Examples include emerging screening technologies, the development of small bioactive compounds/peptides/proteins, and the elucidation of compound structure-activity relationships, target interactions and mechanism-of-action.

Publishing Model: Open Access

Deadline: Mar 31, 2024

Biomedical applications for nanotechnologies

Overall, there are still several challenges on the path to the clinical translation of nanomedicines, and we aim to bridge this gap by inviting submissions of articles that demonstrate the translational potential of nanomedicines with promising pre-clinical data.

Publishing Model: Open Access

Deadline: Dec 31, 2023