Tag Archives: brain pacemakers

Graphene-based materials for brain and heart pacemakers

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A December 10, 2024 news item on phys.org describes research that could make brain implants more comfortable for those who need them,

Two years ago, a medical professional approached scientists at the University of Tabriz in Iran with an interesting problem: Patients were having headaches after pacemaker implants. Working together to investigate, they began to wonder if the underlying issue is the materials used in the pacemakers.

“Managing external noise that affects patients is crucial,” author Baraa Chasib Mezher said. “For example, a person with a brain pacemaker may experience interference from external electrical fields from phones or the sounds of cars, as well as various electromagnetic forces present in daily life. It is essential to develop novel biomaterials for the outlet gate of brain pacemakers that can effectively handle electrical signals.”

A December 10, 2024 American Institute of Physics (AIP) news release (also on EurekAlert), which originated the news item, provides more technical detail,

In an article published this week in AIP Advances, from AIP Publishing, Mezher, who is an Iraqi doctoral student studying in Iran, and her colleagues at the Nanostructured and Novel Materials Laboratory at the University of Tabriz created organic materials for brain and heart pacemakers, which rely on uninterrupted signal delivery to be effective.

“We developed nanocomposites that have excellent mechanical properties and can effectively reduce noise,” Mezher said. “For pacemakers, we are interested in understanding how a material absorbs and disperses energy.”

Using a plastic base known as polypropylene, the researchers added a specially formulated clay called Montmorillonite and different ratios of graphene, one of the strongest lightweight materials. They created five different materials that could be performance-tested.

The authors took detailed measurements of the structure of the composite materials using scanning electron microscopy. Their analysis revealed key characteristics that determine the noise-absorption and signal transmission of the material, including the density and distribution of clay and graphene and the sizes of pores in the material.

“Research groups are actively investigating ways to enhance the performance of pacemakers, and our team focuses specifically on the mechanical, thermal, and other properties of these materials,” Mezher said.

The authors measured the signal-to-noise ratio and how the material performs with different levels of noise. They also tested the impact of the material thickness on performance measures.

“The focus of our ongoing work extends beyond simply identifying biocompatible materials for pacemakers; we aim to improve the connection between the generated signal source and the electrodes,” Mezher said. “Our team is also focused on further developing biomaterials for use within the body, such as materials to enhance the performance of hearing aids.”

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

Enhancing soundproofing performance of polypropylene nanocomposites for implantable electrodes inside the body through graphene and nanoclay; thermomechanical analysis by Baraa Chasib Mezher AL-Kasar (براء جاسب مزهر ال كسار), Shahab Khameneh Asl (شهاب خامنه اصل), Hamed Asgharzadeh (حامداصغرزاده), Seyed Jamaleddin Peighambardoust (سید جمال الدین پیغمبردوست). AIP Advances
Volume 14, Issue 12 December 2024, 125313 DOI: https://doi.org/10.1063/5.0209738 Published online: December 10, 2024

This paper is open access.

Recording brain activity with flexible tentacle electrodes

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A September 4, 2024 news item on ScienceDaily announced some research in Switzerland that improves on electrodes used in brain implants, e.g., like Elon Musk’s company, Neuralink,

Neurostimulators, also known as brain pacemakers, send electrical impulses to specific areas of the brain via special electrodes. It is estimated that some 200,000 people worldwide are now benefiting from this technology, including those who suffer from Parkinson’s disease or from pathological muscle spasms. According to Mehmet Fatih Yanik, Professor of Neurotechnology at ETH Zurich, further research will greatly expand the potential applications: instead of using them exclusively to stimulate the brain, the electrodes can also be used to precisely record brain activity and analyse it for anomalies associated with neurological or psychiatric disorders. In a second step, it would be conceivable in future to treat these anomalies and disorders using electrical impulses.

A September 4, 2024 ETH Zurich press release (also on EurekAlert), which originated the news item, provides more technical detail about the work,

To this end, Yanik and his team have now developed a new type of electrode that enables more detailed and more precise recordings of brain activity over an extended period of time. These electrodes are made of bundles of extremely fine and flexible fibres of electrically conductive gold encapsulated in a polymer. Thanks to a process developed by the ETH Zurich researchers, these bundles can be inserted into the brain very slowly, which is why they do not cause any detectable damage to brain tissue.

This sets the new electrodes apart from rival technologies. Of these, perhaps the best known in the public sphere is the one from Neuralink, an Elon Musk company [emphasis mine]. In all such systems, including Neuralink’s, the electrodes are considerably wider. “The wider the probe, even if it is flexible, the greater the risk of damage to brain tissue,” Yanik explains. “Our electrodes are so fine that they can be threaded past the long processes that extend from the nerve cells in the brain. They are only around as thick as the nerve-cell processes themselves.”

The research team tested the new electrodes on the brains of rats using four bundles, each made up of 64 fibres. In principle, as Yanik explains, up to several hundred electrode fibres could be used to investigate the activity of an even greater number of brain cells. In the study, the electrodes were connected to a small recording device attached to the head of each rat, thereby enabling them to move freely.

No influence on brain activity

In the experiments, the research team was able to confirm that the probes are biocompatible and that they do not influence brain function. Because the electrodes are very close to the nerve cells, the signal quality is very good compared to other methods.

At the same time, the probes are suitable for long-term monitoring activities, with researchers recording signals from the same cells in the brains of animals for the entire duration of a ten-month experiment. Examinations showed that no brain-tissue damage occurred during this time. A further advantage is that the bundles can branch out in different directions, meaning that they can reach multiple brain areas.

Human testing to begin soon

In the study, the researcher used the new electrodes to track and analyse nerve-cell activity in various areas of the brains of rats over a period of several months. They were able to determine that nerve cells in different regions were “co-activated”. Scientists believe that this large-scale, synchronous interaction of brain cells plays a key role in the processing of complex information and memory formation. “The technology is of high interest for basic research that investigates these functions and their impairments in neurological and psychiatric disorders,” Yanik explains.

The group has teamed up with fellow researchers at the University College London in order to test diagnostic use of the new electrodes in the human brain. Specifically, the project involves epilepsy sufferers who do not respond to drug therapy. In such cases, neurosurgeons may remove a small part of the brain where the seizures originate. The idea is to use the group’s method to precisely localise the affected area of the brain prior to tissue removal.

Brain-machine interfaces

There are also plans to use the new electrodes to stimulate brain cells in humans. “This could aid the development of more effective therapies for people with neurological and psychiatric disorders”, says Yanik. In disorders such as depression, schizophrenia or OCD, there is often impairments in specific regions of the brain, which leads to problems in evaluation of information and decision making. Using the new electrodes, it might be possible to detect the pathological signals generated by the neural networks in the brain in advance, and then stimulate the brain in a way that would alleviate such disorders. Yanik also thinks that this technology may give rise to brain-machine interfaces for people with brain injuries. In such cases, the electrodes might be used to read their intentions and thereby, for example, to control prosthetics or a voice-output system.

A bundle of extremely fine electrode fibres in the brain (microscope image). (Image: Yasar TB et al. Nature Communications 2024, modified) Courtesy: ETH Zurich

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

Months-long tracking of neuronal ensembles spanning multiple brain areas with Ultra-Flexible Tentacle Electrodes by Tansel Baran Yasar, Peter Gombkoto, Alexei L. Vyssotski, Angeliki D. Vavladeli, Christopher M. Lewis, Bifeng Wu, Linus Meienberg, Valter Lundegardh, Fritjof Helmchen, Wolfger von der Behrens & Mehmet Fatih Yanik. Nature Communications volume 15, Article number: 4822 (2024) DOI https://doi.org/10.1038/s41467-024-49226-9 Published online: 06 June 2024

This paper is open access.