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The Conversation
The Conversation
Environment
Keiron Roberts, Senior Lecturer in Sustainability and the Built Environment, University of Portsmouth

Biodegradable plastic in clothing doesn't break down nearly as quickly as hoped – new research

Discarded clothing is responsible for millions of tonnes of plastic waste each year. Yudhistira99/Shutterstock

Plastic pollution has emerged as one of the most pressing environmental challenges of our time. Over 100 million tonnes of plastic enters the environment each year, with more than 10 million tonnes ending up in our oceans. These plastics break down into harmful microplastic particles so small they can be consumed by wildlife.

We all recognise discarded bottles and bags as plastic waste. But the synthetic fibres that are woven into our clothing – polyester, nylon, acrylic and others – are equally problematic. Every year, more than 60 million tonnes of plastic fabric is produced, a considerable amount of which ultimately finds it way to landfill.

One promising approach to tackle this crisis is the use of “biodegradable” plastics. These plastics are designed to break down naturally into gases and water, which are then released back into the environment without causing long-lasting damage.


Read more: When biodegradable plastic is not biodegradable


But the reality of biodegradable plastic (or “bioplastic”) falls short of meeting our expectations. New research, led by the Scripps Institution of Oceanography in San Diego, California, has found that a popular bioplastic material called polylactic acid does not break down in the environment nearly as quickly as hoped.

The researchers suspended fibre samples from both bio- and oil-based plastic materials, as well as natural fibres such as cotton, in coastal waters and on the seafloor. Over time, they examined these individual fibres under a microscope to see if they were breaking down. While cotton fibres began to break down within a month, synthetic fibres, including bioplastic materials such as polylactic acid, showed no signs of breaking down even after 400 days submerged in the ocean.

A figure showing the disintegration time in days for five types of material exposed to coastal waters.
Disintegration time in days for five types of material exposed to coastal waters. Royer et al. (2023), CC BY-NC-ND

Finding their way into the sea

The plastic pollution that stems from clothing is a particularly tricky area. Clothes are often not recycled or even recyclable, and they release tiny plastic fibres into the environment through gradual wear and tear.

Clothing fibres can reach our oceans via multiple pathways. Clothes that are washed into the sea, for example, will be broken up physically by wave action or friction with sand particles. This process leads to the release of fibres as the garment frays.

Even by just wearing our clothes, plastic fibres are discharged into the environment – some of which may eventually settle in the ocean. And during the process of washing our clothes, fibres become dislodged and are carried down our drains, also potentially ending up the sea.


Read more: Hundreds of millions of microplastic particles could be flowing into UK rivers, hidden in raw sewage


No matter what we do, clothing fibres will inevitably find their way into the environment. So, it is sensible to give serious consideration to what happens to these fibres once released.

Why does this matter?

Research has found evidence that polylactic acid microfibres are potentially toxic to marine organisms, including jellyfish. The jellyfish studied changed their pulse frequency when exposed to high concentrations of these plastic fibres, potentially reducing their ability to hunt, avoid predators, and maintain orientation in the water.

The presence of polylactic acid fibres in the marine environment may cause jellyfish numbers and behaviour to change. Such changes could have far-reaching implications for marine ecosystems. Jellyfish are widely distributed across all oceans and play a crucial role in the marine food web, both as predators and prey.

A compass jellyfish drifting off the Welsh coast.
A compass jellyfish drifting off the Welsh coast. JDScuba/Shutterstock

The longevity of polylactic acid fibres in the marine environment is another concern. The longer these fibres remain in the environment, the more likely it is they will be eaten by marine organisms.

Bioaccumulation, where microplastics and their associated chemicals accumulate across a marine food web, is then likely to occur. Research has found evidence of microplastic bioaccumulation across multiple species and microplastic types.

Tackling plastic pollution

No matter how the plastic enters the environment, solutions are needed to tackle plastic pollution. Biodegradable plastics are one potential option, but only if they are made from materials that are truly able to break down quickly in the natural environment. They would reduce the time in which plastic materials spend in the environment.

As with conventional plastics, though, bioplastics must still be disposed of correctly. But research has found that the labels and instructions on many biodegradable products are often confusing and misleading. In a study of 9,701 UK citizens, many reported not having understood the meaning of the labels of degradable, compostable and biodegradable plastics.

A person holding a biodegradable plastic bag.
Research shows many people misunderstand the meaning of the labels of degradable, compostable and biodegradable plastics. wisely/Shutterstock

This could lead to biodegradable and non-biodegradable plastics being disposed of incorrectly. Plastic that is released into the environment may not decompose, and will instead break down into small pieces of microplastic.

Polylactic acid can break down in specialised industrial composting plants. But even then, not all composting processes can handle every type of bioplastic. The plastic material has to meet specific criteria and produce compost of a minimum standard.

As the world uses more biodegradable plastic, we need to make sure this material’s environmental footprint is minimised. With that in mind, improving labelling and disposal instructions and improving access to industrial composting could all help.

The Conversation

Dr Keiron Roberts receives funding from UNEP and Innovate UK

Fay Couceiro receives funding from Southern Water, OFWAT and multiple charities involved with GB Row Challenge (https://www.gbrowchallenge.com/).

Dr Muhammad Ali receives funding from Innovate UK and the construction industry.

This article was originally published on The Conversation. Read the original article.

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