Research
Edible hydrogels could replace some plastics Researchers in the Vignolini lab have found a way to make a sustainable, edible cellulose gel that changes colour when you press it.
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Nathan Pitt, ©University of Cambridge
n a paper published in Advanced Materials, the researchers demonstrate how hydroxypropyl cellulose (HPC) can be mixed with gelatine and water in a scalable fashion to create a material that changes colour in response to certain stimuli, making it ideal as a sensor, especially where biocompatibility and/or cost are key considerations. HPC is a highly viscous, biodegradable cellulose derivative used widely in the medical and other industries, for example as an eye treatment and as a thickener and stabiliser in various foods. Interestingly, HPC can form structural colour, which is colour achieved through its inherent structure rather than through any external pigments or dyes. This is termed photonic HPC. Although extensive studies have been conducted on photonic HPC, the development of cellulose applications has been slow, most likely due to the prevalence of plastic alternatives. However, as environmental concerns become more widespread the search for more eco-friendly materials has become increasingly urgent, with potential applications for bio-compatible cellulose derivatives again receiving attention. “My goal is to take HPC and find applications for it that can easily be scaled up,” explains Charlie Barty-King, a PhD student here and the paper’s first author. “Chemistry is good at finding amazing new materials but they often cost too much or are difficult to handle -- we’re focused on the opposite of that – we want to find economic and scalable materials that can begin to compete with plastics.”
Professor Silvia Vignolini led the research One advantage of the gel is that it maintains the liquid HPC’s vibrant colouration as well as its ability to change colour in response to pressure, known as mechanochromism. “Other researchers have devised ways of capturing the photonic HPC state into a solid, but without retaining its ability to change colour,” says Charlie.
To do this, Charlie and colleagues in the Vignolini Bio-inspired Photonics group and the Institute for Manufacturing (IfM) mixed HPC with gelatine and water, all of which are widely available, to create a gelled material that is mouldable as a continuous, unsupported solid. “Before, if people wanted to capture the photonic HPC state, which is a liquid, they needed an external architecture,” he explains, “but here we’ve actually added an internal architecture, so it’s a solid gelatine network with pockets of HPC within it which can still flow, providing a dynamic colouration yet solid material.”
In fact, the new cellulose gel’s mechanochromism is enhanced in two ways: First, because the gelatine gives elasticity to the material, the gel has a quicker mechanochromic relaxation time, which is the time the material takes to return to its original colour after the pressure is relaxed. Second, this same elastic quality means a greater pressure is needed to achieve a colour change. So a sensor made from this gel would be able to respond at
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