Borrowing from biology for green chemistry solutions to pollutants

10 February, 2026

Yang Hui with Professor Jadranka Travas-Sejdic

In the hunt for chemical systems that can carry out multiple tasks efficiently, and reconfigure themselves for different purposes, our researchers at Massey University and at the University of Auckland are finding the best inspiration comes from the biological cell.

'Biological systems can make and unmake things', says Principal Investigator Associate Professor Catherine Whitby of Te Kunenga ki Pūrehuroa Massey University. 'Biological systems have some very simple building blocks, but organise them into a remarkable arrangement of different kinds of materials. So, the overarching idea is, how can we mimic some of that?'

Waipapa Taumata Rau University of Auckland Professor Jakranka Travas-Sedjic agrees.

'In biological cells there are organelles with different functions which respond to stimuli and communicate with each other,' she says. 'We wanted to create artificial cells with distinct components doing different tasks and then use cascade-type reactions to imitate those parts talking to each other.'

Jadranka and Catherine are both part of our Reconfigurable Systems Research Programme team which is focused on progress towards a zero-waste planet. They both emphasise that it is their PhD students who have been doing all the hard work in translating ideas into experiments and making exciting discoveries.

Already, Yang Hui (Jadranka’s PhD student) has made artificial cells that can admit different types of molecules through their external membrane just by varying pH and temperature. To make her simple cells, Yang Hui works with hydrogel capsules which are absorbent, jelly-like particles. The ones she’s made in the lab have a core of water and a shell of two different types of polymer networks enabling them to respond precisely to more than one environmental stimulus.

“Designing artificial cells is one thing but showing that you can control components within a ‘water in water in water’ system is quite challenging to achieve,” Jadranka says. The researchers have published their novel approach for making these tiny (400 micrometres to three millimetres in size) cell-like beads. The water-based design means the hydrogel capsules are compatible with biological systems and could be used for environmental sensing and monitoring.

Yang Hui has gone on to work out how to carry out different reactions in each of two different compartments within the hydrogel capsules. She says there’s been a lot of troubleshooting, persistence and innovation to get to this point. “But I’m pleased we’ve been able to control not only the movement of molecules, but also the sequence of reactions within the capsule – I think that’s very cool.” The work has just been published in the Chemical Engineering Journal and Jadranka says of this progress, “Immediately, there are potential applications in green chemistry because, by doing sequential reactions within a single small system, you are saving time and minimising waste.”

Immediately, there are potential applications in green chemistry because, by doing sequential reactions within a single small system, you are saving time and minimising waste.
Professor Jadranka Travas-Sejdic Principal Investigator University of Auckland

Meanwhile, Shivangi Chourasia (Catherine’s PhD student) is developing reconfigurable emulsions which can change their shape and structure in response to external stimuli such as light or temperature. Emulsions consist of liquids that don’t usually mix but, for example, heating can cause two liquids to mix into a single phase, while cooling re-establishes multiple internal droplets. Light irradiation can also cause shape changes through variations in tension at the boundaries between different liquids.

Shivangi’s research looks at how adding tiny, solid particles to these emulsions influences the shape and behaviour of droplets. Known as Pickering emulsions when particles are added, these mixtures can be reconfigured under different stimuli – something Shivangi is working out how to control. Currently, she is trialling particles with different properties to see how they influence the stability of the emulsions. Shivangi’s emulsions could be used for sensing enzyme activity in healthcare applications, for multi-stage drug delivery, or as self-adjusting lenses in phone cameras and microscopes.

And what will the hydrogel capsules be used for? Jadranka and Yang Hui are currently working on the possibility of programmable pollutant remediation. With capsules acting like miniature porous sponges, they could soak up various types of pollutants and degrade them inside different compartments with specially chosen catalysts. Jadranka explains they’re currently working at the proof-of-concept level and would ultimately collaborate with engineers to figure out the best uses for these materials.

The PhD students agree that working on cell-like behaviour from different perspectives has enabled them to learn from each other and make their projects more interesting. They are both grateful to be part of the MacDiarmid Institute. As Yang Hui says, “I’m very happy to be a MacDiarmid Institute PhD student because they organise a lot of fantastic activities which have given me opportunities to talk to different people, learn about other projects, and even some history and Māori culture. Shivangi and I have also been able to attend various symposia and a student conference in Melbourne.”

Internationally, there is research on artificial cells from various perspectives, but Catherine believes some real novelty has arisen in this project because of the diversity of expertise she and Jadranka have brought together and by being part of an organisation of material scientists who can advise on magnetics or electronics or other fields. “Being part of the MacDiarmid Institute gave us the opportunity to learn about each other’s work, identify overlaps, come up with new ideas, and slowly build what’s turned into a fantastic collaboration.” Jadranka agrees, “We cannot emphasise enough the role of MacDiarmid Institute in this work. It really is an organisation that facilitates the free exchange of ideas and ability to learn from others.”

Being part of the MacDiarmid Institute gave us the opportunity to learn about each other’s work, identify overlaps, come up with new ideas, and slowly build what’s turned into a fantastic collaboration.
Associate Professor Catherine Whitby Principal Investigator Massey University

Tags: Towards Zero Waste - Reconfigurable Systems, Jadranka Travas- Sejdic, catherine whitby