Action on Hearing Loss Logo
    Total results:
      Total results:

      How does the brain change in people who are deaf?

      There are specific parts of the brain that process sound. So what happens to these areas of the brain when someone cannot hear? A new study led by Dr Velia Cardin has looked at how the brain can change in deaf people. In her blog post, Dr Cardin tells us about this exciting study and why it is important.

      By: Dr Velia Cardin | 18 May 2018

      The hearing parts of the brain, known as auditory cortex, are involved in processing and understanding sounds. In our latest study, we show that in deaf people the auditory cortex changes its role: it becomes involved in what we call working memory. Working memory can be thought of as a mental workspace where we mentally store, manipulate and update information to help us with ‘cognitive’ tasks like problem solving and decision making. This is very exciting, because it shows that regions of the brain can change from their usual role of processing sounds (sensory processing) to a new role of storing and updating information (cognitive processing). This means that the brain has a bigger and better ability to change how it works than we previously thought.

      Studying deafness and the brain

      One of the reasons we are interested in studying the deaf brain is that we can contribute evidence to guide and improve health and education for deaf people, and to promote Deaf Awareness. Studying deafness can also tell us a lot about how the brain works, and what the brain has the potential to do. So why is this?

      We use our brain to make sense of all the information that we get through our eyes, ears and through touch. For example, all the images that reach our eyes are processed in what we call the visual cortex. The part of the brain that is involved in understanding sounds is called the auditory cortex. But what happens to the auditory cortex in deaf people? Does is not get used at all? Or does it do something else, and if so what? These are the kinds of questions that the deaf brain can help us to answer.

      “Auditory cortex” and the deaf brain

      Previous research, from our group and others, shows that in deaf people the auditory cortex helps them to process vision and touch. But how does this happen? What changes happen in the brain so that this region (that’s usually involved in hearing) starts to process these other senses?

      One idea is that, well… not much is changed. I know this seems a bit strange, so I’ll give you an example. We know that there are specific parts of the brain that process different aspects of a sensory signal – for example, certain parts of the brain are involved in understanding the location of sounds, others in processing sound movement. Research has shown that, in deaf people, the parts of the brain that usually process the location and movement of sounds are involved in processing the location and movement of visual images. This means that the auditory cortex still keeps its usual role (location and movement), but now it does it for vision instead of hearing. In short, the sense changes (vision instead of hearing), but brain function is preserved (location and movement).

      How could this be the case? An everyday analogy could be that of a food processor. In a food processor, whenever you put in carrots or tomatoes, it will give you slices. A food processor doesn’t care about what food it is, it will treat it as something that needs to be sliced. You could think the same way about nerve cells in the brain (neurons): they do not care what electrical signals or information gets put in (sound or vision), they will see it all as electrical signals and give you information about their location and movement.

      Can the brain change its function?

      So it seems that parts of the brain can maintain their usual role, but change so that they can now use this for different senses. But this may only be part of the story. Our research team want to understand how the deaf brain processes ‘higher-level functions’ or tasks, such as working memory.

      What we did

      In our study, we used a brain scanning technique (functional magnetic resonance imaging, fMRI) to look at how people’s brains responded while they performed some tasks. Twelve deaf people who used British Sign Language to communicate took part, and so did sixteen people who did not have a hearing loss but who could sign. Everyone did a working memory task and we looked at how their brain responded while they were doing this. They also did a colour task so that we could use this as a ‘control’ or comparison.

      What did we find?

      We saw that the auditory cortex responded during the working memory task in deaf people, but not in hearing people. This means that deaf people were using the hearing parts of their brain to perform the working memory task. Interestingly, this did not happen for the control colour task. This is very exciting because it shows that, rather than staying the same, regions of the brain may shift from their usual role of processing sounds (sensory processing) to a new role of storing and updating information (cognitive processing).

      What does this mean?

      Let’s use again our food processor analogy. A change in function means that the food processor makes slices when we put in tomatoes, but when we put carrots, it doesn’t make slices anymore; it makes something else entirely, let’s say soup. The only way this can happen is by either using a different blade or a different processor altogether. In the same way, if a brain region changes what it does from processing sound to working memory, then something has to change – either the way the neurons work, or the type of neurons that are involved.

      These results are exciting because it means that the brain has a bigger and better ability to change how it works than we previously thought. However, these results are just the first step, and we still need to conduct more research to check that these brain areas do indeed change the role that they’re playing.  We are now trying to understand if the hearing parts of the brain really are involved in working memory and other cognitive tasks. We are also looking at whether regions of the brain can maintain, as well as change, their function at the same time, or whether these two things can only happen separately from each other.  Get in touch if you want to volunteer to take part in this research, and stay tuned for further results!

      How to take part

      If you are severely or profoundly deaf from birth or early infancy, and would like to take part in this research, please contact Dr Velia Cardin, or visit her website for details about her research

      Find out more

      We depend on your donations so we can fund the best hearing and tinnitus research around the world. Donate today and help us continue our vital work into hearing treatments, so that people can live life to the full again.

      The original research paper was published recently in the journal Cerebral Cortex. Please visit Dr Cardin’s website (external link, opens in new window).

      You can find out more about the research we’re funding in our biomedical research section.

      If you’re interested in finding out more about our research, sign up to receive our Soundbite e-newsletter. It’s a monthly email, filled with the latest news about hearing and tinnitus research.

      Recent Posts

      Our top products for socialising outdoors

      It’s summertime and the living is easy with our great range of products for deafness, tinnitus and hearing loss. Whether you’re planning a picnic in the park, going to an open-air concert, family barbeque, or simply relaxing in the garden, we’ve everything you need to get the most from socialising outdoors.

      By: Sally Bromham
      20 August 2019

      Could reducing brain inflammation be a way to treat tinnitus?

      Scientists in the US have identified a link between inflammation in sound processing regions of the brain and tinnitus in mice. They have discovered that a molecule called TNF-alpha is key to this link, and that blocking its activity reduced tinnitus in the mice. This research could be the first step towards developing an effective treatment for tinnitus. Tracey from our research team tells us more.

      By: Tracey Pollard
      19 August 2019

      Treat your home to smart tech

      Kevin Taylor reports on how smart home technology will help make life more inclusive.

      By: Kevin Taylor
      01 August 2019

      Our top 10 alarm clocks for hearing loss

      Waking up on time can be difficult if you have trouble hearing the alarm. There are many deaf-friendly alarm clocks available but which should you choose? We’ve selected our top 10 alarm clocks to help you find the right one to suit your hearing needs, lifestyle and budget.

      By: Sally Bromham
      25 July 2019