Hybrid Assembly of Polymeric Nanofiber Network for Robust and Electronically Conductive Hydrogels

Principal Investigator: Professor Lizhi Xu (Assistant Professor, Department of Mechanical Engineering)

This project is showcased as the Research Highlight (March – April 2024) in the third exhibition – Technology for Future in Innovation Wing Two

Project information

Background

Hydrogels are promising candidate materials for the construction of soft electronics and biomedical devices due to their mechanical flexibility, structural permeability, and biocompatibility. However, achieving high electrical conductivity and mechanical robustness in hydrogels remains challenging, which limits their practical applications. Professor Lizhi Xu’s research team has developed a new type of electroconductive hydrogels with outstanding mechanical strength and manufacturability.
Schematics and images of electroconductive hydrogels.
Electroconductive hydrogels for wearable electronics.
Cardiac cells cultured on electroconductive hydrogels.

Achievement of the Project

He, H., Li, H., Pu, A. et al. Hybrid assembly of polymeric nanofiber network for robust and electronically conductive hydrogels. Nat Commun 14, 759 (2023). https://doi.org/10.1038/s41467-023-36438-8

About the Scholar

Professor Lizhi Xu is currently an Assistant Professor at the Department of Mechanical Engineering, The University of Hong Kong. He obtained his B.S. degree (2009) in Applied Physics from Beihang University, and his Ph.D. degree (2014) in Materials Science and Engineering from University of Illinois, Urbana-Champaign. He worked as a postdoctoral research fellow at the University of Michigan from 2015 to 2018 before joining The University of Hong Kong. His research interests involve biomimetic materials, soft electronics, biomedical devices, and micro-/nanofabrication.

Press release

HKU Mechanical Engineering team develops electroconductive hydrogel for biomedical applications

The press release article can be founded in HKU Press release (https://www.hku.hk/press/news_detail_26062.html)

Synthetic hydrogels show great promise in tissue repair, drug delivery, medical implants, and many other applications. Hydrogels functionalized with electrically conductive components can be used in bioelectronic devices for cardiac or neural interfaces, for applications such as neural prosthetics, cardiac patches, and electronic skin.

A research team led by Dr Lizhi Xu of the Department of Mechanical Engineering in the Faculty of Engineering at the University of Hong Kong (HKU) has recently developed a new type of electroconductive hydrogels with outstanding mechanical strength and manufacturability, creating opportunities for the engineering of various bioelectronic devices.

The innovation has been published in Nature Communications in an article entitled “Hybrid assembly of polymeric nanofiber network for robust and electronically conductive hydrogels”.

Synthetic hydrogels are water-rich polymeric materials resembling biological soft tissues. They are soft, porous, and biocompatible, enabling a physical interface between natural biological tissues and advanced biomedical tools. In particular, electroconductive hydrogels have attracted wide research attention, as they can be used in bioelectronic devices for cardiac or neural interfaces.

“Existing hydrogels are mechanically weak and difficult to manufacture, which limits their practical utility. We used a unique microscale scaffold for the synthesis of conductive hydrogels. The architecture of the composites provided a combination of properties inaccessible by other hydrogels, which is crucial for realistic applications in bioelectronic devices,” said Dr Xu.

In the new hydrogels developed by Dr Xu’s team, a 3D nanofiber network was utilised as a template to guide the assembly of conducting polymers (such as polypyrrole). The high connectivity of the nanofibers provided both structural robustness and an effective pathway for electron conduction.

“For potential biomedical applications, the device needs to withstand repeated mechanical loading associated with body motion. In this regard, mechanical robustness of the materials would be very important.” Dr Xu explained.

The resulting material developed by the team contains 80% water by weight, while at the same time showing a high electrical conductivity of ~80 S/cm and a mechanical strength of ~9.4 MPa.

“These conductive hydrogels are easy to fabricate. One can pattern them into arrays of electrodes, interconnects, and biosensors, enabling functional systems such as wearable health monitors or cardiac tissue engineering platforms.” Dr Xu said.

“It opens opportunities for many advanced medical tools down the road, such as neural prosthetics, cardiac patches, electronic skin, and so on.” He added.

Dr Xu and his research team earlier created another novel type of hydrogel that mimics tendons, exhibiting remarkable mechanical properties that closely resemble those of natural tendons, along with multiple functionalities that are well-suited for biomedical applications. 
(press release: https://www.hku.hk/press/news_detail_26045.html)

Link to the paper “Hybrid assembly of polymeric nanofiber network for robust and electronically conductive hydrogels”: https://www.nature.com/articles/s41467-023-36438-8

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