ҳ

Home

Scientists mimic heart muscle cells with conductive plastic

03 June 2026

Anders Törneholm

For the first time, scientists have succeeded in artificially mimicking the ion signalling of heart muscle cells. To succeed, researchers at LiU have used organic electronics based on conductive plastics. The findings, published in Nature Communications, open up for new types of prostheses, heart implants and sensors in the long term.

A couple of men standing next to each other in front of a blackboard. Photographer: Thor Balkhed
Researchers Dace Gao and Deyu Tu are part of the research group that have used conductive plastics to mimic heart muscle cells.

“There’s a reason why nature has endowed cardiac muscle cells with this particular type of electrical signalling. We do not merely want to mimic the biology, but also to harness the principles that make these signals so effective,” says Simone Fabiano, Professor of Materials Science at Linköping University.

The human heart beats about 2.6 billion times in an average lifetime. This happens continuously, 24 hours a day, throughout life. One of the keys to the untiring work of the heart muscle cells is the transport of potassium, sodium and calcium ions in and out of the cells. The ion transport initiates an electrical impulse called action potential. This in turn causes the muscles of the heart to contract and the blood is pumped forward.

A close up of a person holding a piece of electronic equipment. Thor Balkhed
The circuit is created on a large glass substrate. However, it would be possible to miniaturize it (0,15 mm) on an other biocompatible substrate.

Slow calcium transport

But artificially mimicking this ion transport and action potential has been a challenge, as heart muscle cells differ from other cells in the body. This is because the ion channel that transports calcium works relatively slowly compared to the sodium and potassium channels.

“It’s precisely this slowness that creates a bottleneck if you try to work with traditional electronics that are designed to be fast. In this case, organic electronics are better, because they can transport both ions and electrons and therefore communicate in the same way as the cells in the body,” says Dace Gao, postdoc at the Laboratory of Organic Electronics, LOE, at LiU and lead author of the scientific article published in Nature Communications.

What he and his colleagues at LOE, Campus Norrköping, have done instead is develop an artificial heart muscle cell made of conductive plastic that mimics the electrical function, that is, the action potential, of the cell.

Simone Fabiano. Thor Balkhed
Simone Fabiano, Professor of Materials Science at Linköping University.

Hardware allows testing

The same research group has previously developed artificial nerve cells that mimic the properties of biological nerve cells. Developing artificial heart muscle cells was a natural next step, as there was no hardware that could imitate the special ion signalling.

According to Simone Fabiano, there are two main reasons for mimicking the electrical dynamics of cardiac muscle cells using organic electronics. One is that researchers can gain a deeper understanding of the material properties required to recreate biology-like signals. The other is that such systems could, in the long term, be used as bioelectronic models and interfaces:

“Since this is hardware, we can in a controlled manner investigate how changes in, for example, ion concentration and pH affect heart-like electrical signals. In the future, we also hope to be able to connect such systems more closely to biological cardiac muscle cells,” says Simone Fabiano.

New types of medical technology

The researchers envision, for example, how this technology could contribute to small ‘natural’ pacemakers, implants that can activate muscles or sensors that can detect early disturbances in heart function and initiate measures. But this hinges on solving a key issue.

“The artificial cells must be able to receive a signal from a biological cell and then pass the signal on to other cells. The artificial heart muscle cells would then act as a bridge and we will get significantly closer to biomedical applications,” says Dace Gao.

A close up of a person's hand holding a cell phone. Thor Balkhed
The properties of organic electronics make serial fabrication of circuits such as the artificial cardiomyocyte possible.

The study was funded mainly by the Knut and Alice Wallenberg Foundation, the Wallenberg Initiative Materials Science for Sustainability, the Swedish Research Council, the European Research Council, the Marie Skłodowska-Curie Actions Postdoctoral Fellowships programme, the Swedish Foundation for Strategic Research, Vinnova and through the Swedish Government Strategic Research Area in Materials Science on Advanced Functional Materials (AFM) at Linköping University.

Article: , Dace Gao, Junpeng Ji, Simone De Prà, Miao Xiong, Wenlong Jin, Ugo Bruno, Han-Yan Wu, Aleksandr Khudiakov, Andreas W. Erhardt, Chi-Yuan Yang, Peter J. Schwartz, Luca Sala, Iain McCulloch, Adrica Kyndiah, Mario Caironi, Magnus Berggren, Deyu Tu, Simone Fabiano, Nature Communications 2026, published online 6 May 2026. DOI: 10.1038/s41467-026-72584-5

Contact

Photo of Simone Fabiano

Simone Fabiano

Professor, Head of Unit
Photo of Dace Gao

Dace Gao

Postdoc

Read more about the research

A man standing in a lab.

Prestigious chemistry award to Simone Fabiano

This year’s Göran Gustafsson Prize in Chemistry is awarded to LiU Professor Simone Fabiano. His research focuses on organic semiconductors and how so‑called doping can improve conductivity and yield new properties.
Researcher with blue gloves by microscope.

Plastic nerve cells become more advanced – and simpler

An artificial neuron made of conductive plastics that can perform advanced functions similar to those of biological nerve cells has been demonstrated by researchers at LiU.
Sheet of glass with droplet.

Next-generation sustainable electronics are doped with air

Researchers at LiU have developed a new method where organic semiconductors can become more conductive with the help of air as a dopant. The study is a significant step towards future sustainable organic semiconductors.

Research environment

Power plant, organic electronics, a red rose.

Laboratory of Organic Electronics

World-leading competence in organic and hybrid materials, from design and modeling to applications in energy, electronics and bioelectronics. Sustainability focus and pipeline from science to commercialization deliver high-impact innovation.

Strategic research

Closeup of electronic component held with tweezers, part of a mans face in the backgound

Advanced Functional Materials - AFM

Advanced Functional Materials, AFM, is an interdisciplinary research environment conducting studies in advanced functional materials. The initiative is based on a government investment with strategic research areas as its foundation.

Latest news from LiU

Woman at office.

Biogenic carbon dioxide could become a key resource as biogas expands

During the production and upgrading of biogas, carbon dioxide is released, a greenhouse gas that affects the climate. However, research at ҳ shows that this carbon dioxide has several uses and could become an important resource.
A man wearing glasses standing in front of a red wall.

Moral economy perspectives through history

When a crisis arises, a humanitarian urge to help others is often awakened. But what happens when emotions rule and knowledge is lacking? Norbert Götz, professor of modern history, has researched the conditions of humanitarian aid.
A men and his reflecetion near a brick wall.

Lubunca – a powerful language of hidden words

What can a hidden language tell us about freedom, identity and survival? By studying Lubunca, Burak Alp Çakar explores the emancipatory power of words and how they can empower, protect and keep communities alive.