Tag Archives: Han-Yan Wu

Key obstacle to integrated bioelectronic implants removed with use of solid-state hydrogel

Leave a reply

Cyborgs calling? It seems a logical extension from the work being described in Michael Berger’s August 28, 2025 Nanowerk Spotlight article, Note: A link has been removed,

Electronic devices that can sense, process, and respond to biological signals are reshaping how researchers approach medicine, neuroscience, and human–machine interaction [emphasis mine]. These systems, often soft, flexible, and powered by organic materials, promise to monitor brain activity, stimulate nerves, and control prosthetics with a level of precision and integration that rigid silicon electronics cannot match. The ambition is clear: build circuits that are not just compatible with the body, but functionally embedded within it.

Yet at the core of many of these bioelectronic systems lies a persistent technical obstacle. Organic electrochemical transistors—or OECTs—have emerged as one of the most promising components for such interfaces. They operate at low voltages, work well in wet environments, and can amplify faint biological signals. But their performance has depended almost entirely on liquid electrolytes—saline-based solutions that shuttle ions in and out of the transistor channel. While effective at driving fast switching and strong responses, these liquids are difficult to confine. They spread, leak, evaporate, and cause interference between closely packed devices. They make miniaturization harder, circuit integration more complex, and long-term implantation more fragile.

Solid-state electrolytes have been explored as a replacement. Some are made from ionic gels or charged polymers, others from hydrogels with modified compositions. But each compromise has created new limitations: reduced ion mobility, patterning challenges, long response times, or incompatibility with both p-type and n-type transistor operation. These tradeoffs have made it difficult to build dense, fast, reliable circuits for real use in living systems.

Now, researchers in Sweden report a material system that brings this goal closer. Writing in Advanced Materials (“A Photo‐Patternable Solid‐State Electrolyte for High‐Performance, Miniaturized, and Implantable Organic Electrochemical Transistor‐Based Circuits”), the team presents a hydrogel-based solid-state electrolyte that is both photopatternable and fast enough to match the performance of liquid systems.

This turns out to be a hydrogel and seaweed story, from Berger’s August 28, 2025 article,

Using a naturally derived polymer from seaweed and a light-activated crosslinker, they’ve built a platform that enables high-speed operation, micrometer-scale precision, and compatibility with flexible, implantable devices. The system supports both logic circuits and spiking neural mimics, all operating on a solid-state foundation—offering a solution to a long-standing bottleneck in bioelectronic circuit design.

This work introduces a solid-state hydrogel based on ι-carrageenan, a charged polysaccharide extracted from red seaweed, crosslinked with poly(ethylene glycol) diacrylate (PEGDA). When exposed to ultraviolet light, PEGDA forms a permanent network that locks the ι-carrageenan into a soft, water-stable gel. The result is a solid-state electrolyte that can be patterned with high precision, while maintaining ionic conductivity at levels comparable to liquid saline.

The hydrogel can be processed as a liquid and selectively hardened using light exposure. Before crosslinking, it spreads easily for coating or printing. After UV exposure, it forms a water-insoluble gel that can be patterned down to 15 micrometers. This resolution is sufficient for building densely packed circuits on flexible substrates. Crucially, the material retains ionic conductivity above 10 millisiemens per centimeter—on par with 0.1 molar sodium chloride. That conductivity enables fast ion movement through the gel, preserving the switching speed and signal fidelity expected of high-performance OECTs.

To move beyond digital logic, the researchers designed a circuit that mimics the behavior of a spiking neuron. This organic electrochemical neuron (OECN) was based on the leaky integrate-and-fire model used in artificial neural networks. It combines complementary OECTs with a reset transistor and integrates them into a spiking architecture that converts a continuous input into transient voltage pulses. The circuit was encapsulated using a biocompatible layer of parylene and fabricated on an ultrathin flexible substrate.

To demonstrate biological relevance, the team implanted this device in mice. They connected it to flexible stimulation electrodes coated with PEDOT:PSS, a conductive polymer that lowers electrode impedance. The system was wrapped around the cervical vagus nerve, a major nerve involved in autonomic regulation of the heart and digestive system. When inactive, the device produced no physiological effect. When activated to spike at frequencies between 1 and 20 hertz, it induced a measurable drop in heart rate of 2 to 4 percent—consistent with the known effects of vagus nerve stimulation.

Unlike previous systems based on liquid electrolytes, this device remained stable after implantation, with no fluid reservoirs or leakage pathways. Its function did not degrade after encapsulation, and spiking behavior remained consistent. The reduction in spiking frequency observed after implantation was attributed to the mouse acting as an external load, not to any failure of the circuit.

The platform introduced in this study enables a new level of complexity and stability in soft bioelectronics. It demonstrates that solid-state, hydrogel-based circuits can meet the electrical demands of real-world applications without sacrificing manufacturability or implant safety. By bridging the gap between ionic transport and scalable circuit design, this work sets the foundation for future generations of bioelectronic therapies and neural interfaces.

Berger’s August 28, 2025 article offers a lot more detail and his explanations tend to be accessible (relatively speaking).

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

A Photo-Patternable Solid-State Electrolyte for High-Performance, Miniaturized, and Implantable Organic Electrochemical Transistor-Based Circuits by Miao Xiong, Chi-Yuan Yang, Junpeng Ji, April S. Caravaca, Qi Guo, Qifan Li, Mary J. Donahue, Dace Gao, Han-Yan Wu, Adam Marks, Yincai Xu, Deyu Tu, Iain McCulloch, Peder S. Olofsson, Simone Fabiano. Advanced Materials DOI: https://doi.org/10.1002/adma.20250931 First published: 22 August 2025

This paper is open access.

Artificial organic neuron mimics characteristics of biological nerve cells

Leave a reply

There’s a possibility that in the future, artificial neurons could be used for medical treatment according to a January 12, 2023 news item on phys.org,

Researchers at Linköping University (LiU), Sweden, have created an artificial organic neuron that closely mimics the characteristics of biological nerve cells. This artificial neuron can stimulate natural nerves, making it a promising technology for various medical treatments in the future.

Work to develop increasingly functional artificial nerve cells continues at the Laboratory for Organic Electronics, LOE. In 2022, a team of scientists led by associate professor Simone Fabiano demonstrated how an artificial organic neuron could be integrated into a living carnivorous plant [emphasis mine] to control the opening and closing of its maw. This synthetic nerve cell met two of the 20 characteristics that differentiate it from a biological nerve cell.

I wasn’t expecting a carnivorous plant, living or otherwise. Sadly, they don’t seem to have been able to include it in this image although the ‘green mitts’ are evocative,

Caption: Artificial neurons created by the researchers at Linköping University. Credit: Thor Balkhed

A January 13, 2023 Linköping University (LiU) press release by Mikael Sönne (also on EurkeAlert but published January 12, 2023), which originated the news item, delves further into the work,

In their latest study, published in the journal Nature Materials, the same researchers at LiU have developed a new artificial nerve cell called “conductance-based organic electrochemical neuron” or c-OECN, which closely mimics 15 out of the 20 neural features that characterise biological nerve cells, making its functioning much more similar to natural nerve cells.

“One of the key challenges in creating artificial neurons that effectively mimic real biological neurons is the ability to incorporate ion modulation. Traditional artificial neurons made of silicon can emulate many neural features but cannot communicate through ions. In contrast, c-OECNs use ions to demonstrate several key features of real biological neurons”, says Simone Fabiano, principal investigator of the Organic Nanoelectronics group at LOE.

In 2018, this research group at Linköping University was one of the first to develop organic electrochemical transistors based on n-type conducting polymers, which are materials that can conduct negative charges. This made it possible to build printable complementary organic electrochemical circuits. Since then, the group has been working to optimise these transistors so that they can be printed in a printing press on a thin plastic foil. As a result, it is now possible to print thousands of transistors on a flexible substrate and use them to develop artificial nerve cells.

In the newly developed artificial neuron, ions are used to control the flow of electronic current through an n-type conducting polymer, leading to spikes in the device’s voltage. This process is similar to that which occurs in biological nerve cells. The unique material in the artificial nerve cell also allows the current to be increased and decreased in an almost perfect bell-shaped curve that resembles the activation and inactivation of sodium ion channels found in biology.

“Several other polymers show this behaviour, but only rigid polymers are resilient to disorder, enabling stable device operation”, says Simone Fabiano

In experiments carried out in collaboration with Karolinska Institute (KI), the new c-OECN neurons were connected to the vagus nerve of mice. The results show that the artificial neuron could stimulate the mice’s nerves, causing a 4.5% change in their heart rate.

The fact that the artificial neuron can stimulate the vagus nerve itself could, in the long run, pave the way for essential applications in various forms of medical treatment. In general, organic semiconductors have the advantage of being biocompatible, soft, and malleable, while the vagus nerve plays a key role, for example, in the body’s immune system and metabolism.

The next step for the researchers will be to reduce the energy consumption of the artificial neurons, which is still much higher than that of human nerve cells. Much work remains to be done to replicate nature artificially.

“There is much we still don’t fully understand about the human brain and nerve cells. In fact, we don’t know how the nerve cell makes use of many of these 15 demonstrated features. Mimicking the nerve cells can enable us to understand the brain better and build circuits capable of performing intelligent tasks. We’ve got a long road ahead, but this study is a good start,” says Padinhare Cholakkal Harikesh, postdoc and main author of the scientific paper.

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

Ion-tunable antiambipolarity in mixed ion–electron conducting polymers enables biorealistic organic electrochemical neurons by Padinhare Cholakkal Harikesh, Chi-Yuan Yang, Han-Yan Wu, Silan Zhang, Mary J. Donahue, April S. Caravaca, Jun-Da Huang, Peder S. Olofsson, Magnus Berggren, Deyu Tu & Simone Fabiano. Nature Materials volume 22, pages 242–248 (2023) DOI: https://doi.org/10.1038/s41563-022-01450-8 Published online: 12 January 2023 Issue Date: February 2023

This paper is open access.