Nano-Scale Vision Implant Promises New Hope for Blindness

Summary: Researchers developed a novel vision implant, featuring electrodes as small as a single neuron. This advanced technology, designed to interface directly with the visual cortex, could significantly enhance the visual perception in individuals who are blind.

By utilizing a unique mix of non-corrosive materials, the implant remains stable and functional within the body over extended periods. The study marks a significant step toward more detailed and sustainable vision restoration.

Key Facts:

  1. Ultra-Small Electrodes: The implant’s electrodes are the size of a single neuron, enabling a higher resolution of electrical stimulation to the brain’s visual areas.
  2. Material Innovation: The implant uses a conducting polymer that prevents corrosion, ensuring longevity and functionality in the moist environment of the human body.
  3. Promising Preclinical Results: Initial tests in mice have shown that the implant can effectively stimulate visual perception with minimal current and maintain its functionality over the animal’s lifespan.

Source: Chalmers University of Technology

A group of researchers from Chalmers University of Technology in Sweden, University of Freiburg and the Netherlands Institute for Neuroscience have created an exceptionally small implant, with electrodes the size of a single neuron that can also remain intact in the body over time – a unique combination that holds promise for future vision implants for the blind.

Often when a person is blind, some or part of the eye is damaged, but the visual cortex in the brain is still functioning and waiting for input. When considering brain stimulation for sight restoration, there needs to be thousands of electrodes going into an implant to build up enough information for an image.

This shows an eye.
The polymer forms a protective layer on the metal and makes the electrode much more resilient to corrosion, essentially a protective layer of plastic covering the metal. Credit: Neuroscience News

By sending electrical impulses via an implant to the visual cortex of the brain, an image can be created, and each electrode would represent one pixel.

“This image would not be the world as someone with full vision would be able to see it. The image created by electrical impulses would be like the matrix board on a highway, a dark space and some spots that would light up depending on the information you are given.

The more electrodes that ‘feed’ into it, the better the image would be,” says Maria Asplund, who led the technology development part of the project and is Professor of Bioelectronics at Chalmers University of Technology in Sweden.

The vision implant created in this study can be described as a ‘thread’ with many electrodes placed in a row, one after the other. In the long term you would need several threads with thousands of electrodes connected to each one, and the results of this study are a key step towards such an implant.

The future of vision implants

An electrical implant to improve vision in people with blindness is not a new concept. However, the implant technology currently being explored in human patients is from the 1990s and there are several factors that need to be improved, for example the bulky size, scarring in the brain due to their large size, materials corroding over time and materials being too rigid.

By creating a really small electrode the size of a single neuron, researchers have the potential to fit lots of electrodes onto a single implant and build up a more detailed image for the user. The unique mix of flexible, non-corrosive materials make this a long-term solution for vision implants.

“Miniaturisation of vision implant components is essential. Especially the electrodes, as they need to be small enough to be able to resolve stimulation to large numbers of spots in the ‘brain visual areas’.

The main research question for the team was, ‘can we fit that many electrodes on an implant with the materials we have and make it small enough and also effective?’ and the answer from this study was – yes,” says Professor Asplund.

The smaller the size, the worse the corrosion

To create an electrical implant on such a small scale comes with its challenges, especially in a tough environment, such as the human body. The major obstacle is not to make the electrodes small, but to make such small electrodes last a long time in a moist, humid environment.  

Corrosion of metals in surgical implants is a huge problem, and because the metal is the functional part, as well as the corroding part, the amount of metal is key. The electrical implant that Asplund and her team have created measures in at a miniscule 40 micrometers wide and 10 micrometers thick, like a split hair, with the metal parts being only a few hundred nanometers in thickness 

And since there is so little metal in the super tiny vision electrode, it cannot ‘afford’ to corrode at all, otherwise it would stop working.

In the past, this problem has not been possible to solve. But now, the research team have created a unique mix of materials layered up together that do not corrode. This includes a conducting polymer to transduce the electrical stimulation required for the implant to work, to electrical responses in the neurons.

The polymer forms a protective layer on the metal and makes the electrode much more resilient to corrosion, essentially a protective layer of plastic covering the metal.

“The conducting polymer metal combination we have implemented is revolutionary for vision implants as it would mean they hopefully could remain functional for the entire implant life-time.

“We now know it is possible to make electrodes as small as a neuron (nerve cell) and keep this electrode effectively working in the brain over very long timespans, which is promising since this has been missing until now.

“The next step will be to create an implant that can have connections for 1000s of electrodes,” says Asplund, something that is currently explored within a larger team in the ongoing EU project Neuraviper.

More about: the study method

The method was implemented by the research collaborators at the Netherlands Institute for Neuroscience, where mice were trained to respond to an electrical impulse to the visual cortex of the brain.

The study showed that not only could the mice learn to react to the stimulation applied via the electrodes in just a few sessions, but the minimal current threshold for which mice reported a perception was lower than standard metal-based implants.

The research team further reported that the functionality of the implant stayed stable over time, for one mouse even until the end of its natural lifespan.

About this neurotech and visual neuroscience research news

Author: Emma Fry
Source: Chalmers University of Technology
Contact: Emma Fry – Chalmers University of Technology
Image: The image is credited to Neuroscience News

Original Research: Open access.
Flexible Polymer Electrodes for Stable Prosthetic Visual Perception in Mice” by Maria Asplund et al. Advanced Healthcare Materials


Flexible Polymer Electrodes for Stable Prosthetic Visual Perception in Mice

Brain interfaces that can stimulate neurons, cause minimal damage, and work for a long time will be central for future neuroprosthetics.

Here, the long-term performance of highly flexible, thin polyimide shanks with several small (<15 µm) electrodes during electrical microstimulation of the visual cortex, is reported.

The electrodes exhibit a remarkable stability when several billions of electrical pulses are applied in vitro.

When the devices are implanted in the primary visual cortex (area V1) of mice and the animals are trained to detect electrical microstimulation, it is found that the perceptual thresholds are 2–20 microamperes (µA), which is far below the maximal currents that the electrodes can withstand.

The long-term functionality of the devices in vivo is excellent, with stable performance for up to more than a year and little damage to the brain tissue.

These results demonstrate the potential of thin floating electrodes for the long-term restoration of lost sensory functions.

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