Nanocellulose film and Kiragami hydrogels

A Kirigami pattern of the hydrogel (top) and the hydrogel swollen from dry state (bottom). (Image: NIMS) [downloaded from https://www.nanowerk.com/nanotechnology-news3/newsid=65005.php]

An April 11, 2024 news item on Nanowerk highlights research that combines kiragami with hydrogel production, Note 1: A link has been removed, Note 2: Kiragami is described in the excerpt after this one,

New options for making finely structured soft, flexible and expandable materials called hydrogels have been developed by researchers at Tokyo University of Agriculture and Technology (TUAT). Their work extends the emerging field of ‘kirigami hydrogels’, in which patterns are cut into a thin film allowing it to later swell into complex hydrogel structures.

An April 12, 2024 Tokyo University of Agriculture and Technology (TUAT) press release, which originated the news item, on JCN Newswire, Note: Distribution of press releases can be spread out over days (sometimes identical press releases are sent out twice, months apart),

Hydrogels have a network of water-attracting (hydrophilic) molecules, allowing their structure to swell substantially when exposed to water that becomes incorporated within the molecular network. Researchers Daisuke Nakagawa and Itsuo Hanasaki worked with an initially dry film composed of nanofibers of cellulose, the natural material that forms much of the structure of plant cell walls.

They used laser processing to cut structures into the film before water was added allowing the film to swell. The particular design of the Kirigami pattern works in such a way that the width increases when stretched in the longitudinal direction, which is called the auxetic property. This auxetic property emerges provided that the thickness grows sufficiently when the original thin film is wet.

“As Kirigami literally means the cut design of papers [emphasis mine], it was originally intended for thin sheet structures. On the other hand, our two-dimensional auxetic mechanism manifests when the thickness of the sheet is sufficient, and this three dimensionality of the hydrogel structure emerges by swelling when it is used. It is convenient to store it in the dry state before use, rather than keeping the same water content level of the hydrogel.” says Hanasaki. “Furthermore, the auxeticity is maintained during the cyclic loading that causes the adaptive deformation of the hydrogel to reach another structural state. It will be important for the design of intelligent materials.”

Potential applications for the adaptive hydrogels include soft components of robotic technologies, allowing them to respond flexibly when interacting with objects they are manipulating, for example. They might also be incorporated into soft switches and sensor components. Hydrogels are also being explored for medical applications, including tissue engineering, wound dressings, drug delivery systems and materials that can adapt flexibly to movement and growth. The advance in kirigami hydrogels achieved by the TUAT team significantly extends the options for future hydrogel applications.

“Keeping the designed characteristics while showing adaptivity to the environmental condition is advantageous for the development of multifunctionality,” Hanasaki concludes

Here’s a link to and a citation for the paper,

Adaptive plasticity of auxetic Kirigami hydrogel fabricated from anisotropic swelling of cellulose nanofiber film by Daisuke Nakagawa & Itsuo Hanasaki. Science and Technology of Advanced Materials Volume 25, 2024 – Issue 1 Article: 2331959 DOI: https://doi.org/10.1080/14686996.2024.2331959 Published online: 02 Apr 2024

This is an open access paper.

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