New Research Finds Mild-to-Moderate Hearing Loss in Childhood Changes How Brain Processes Sound

CAMBRIDGE, UNITED KINGDOM — Deafness in early childhood is known to lead to lasting changes in how sounds are processed in the brain, but newly published research shows that even mild-to-moderate levels of hearing loss in young children can lead to similar changes.

Researchers say that the findings may have implications for how babies are screened for hearing loss and how mild-to-moderate hearing loss in children is managed by healthcare providers.


The Auditory System and the Brain


The structure and function of the auditory system, which processes sounds in the brain, develops throughout childhood in response to exposure to sounds. In profoundly deaf children, the auditory system undergoes a functional re-organization, repurposing itself to respond more to visual stimuli, for example. However, until now relatively little was known about the effects of mild-to-moderate hearing loss during childhood.

A research team led by Dr Lorna Halliday, now at the MRC Cognition and Brain Sciences Unit, University of Cambridge, used an electroencephalogram (EEG) technique to measure the brain responses of 46 children who had been diagnosed with permanent mild-to-moderate hearing loss while they were listening to sounds.

Dividing the children into two groups – younger children (8-12 years) and older children (12-16 years) – the team found that the younger children with hearing loss showed relatively typical brain responses – in other words, similar to those of children with normal hearing. However, the brain responses of older children with hearing loss were smaller than those of their normally hearing peers.

To confirm these findings, the researchers re-tested a subset of the group of younger children from the original study, six years later. In the follow-up study, the researchers confirmed that as the children with hearing loss grew older, their brain responses changed. Responses that were present when the children were younger had either disappeared or grown smaller by the time the children were older.

There was no evidence that the children’s hearing loss had worsened over this time, suggesting instead that a functional reorganization was occurring.

“We know that children’s brains develop in response to exposure to sounds, so it should not be too surprising that even mild-to-moderate levels of hearing loss can lead to changes in the brain,” says Dr Axelle Calcus, lead author of the paper, from PSL University, Paris. “However, this does suggest that we need to identify these problems at an earlier stage than is currently the case.”

“Current screening programmes for newborn babies are good at picking up moderate-to-profound levels of hearing loss, but not at detecting mild hearing loss. This means that children with mild hearing impairment might not be detected until later in childhood, if at all,” says Dr Lorna Halliday from the University of Cambridge.

“Children with hearing problems tend to do less well than their peers in terms of language development and academic performance. Detecting even mild degrees of hearing impairment earlier could lead to earlier intervention that would limit these brain changes, and improve children’s chances of developing normal language.”

The research was funded by the Economic and Social Research Council and the European Union Horizon 2020 Programme. The research was carried out at University College London (UCL).


Calcus, A et al. Functional Brain Alterations Following Mild-to-Moderate Sensorineural Hearing Loss in Children. eLife; 1 October 2019; DOI: 10.7554/eLife.46965


Researcher Profile: Dr Lorna Halliday

Dr Lorna Halliday was recently awarded one of three MRC Senior Fellowships in Hearing Research, enabling her to undertake a programme of research into childhood hearing loss at the MRC Cognition and Brain Sciences Unit (CBU).

She has been interested in hearing loss ever since studying Experimental Psychology at the University of Bristol. She is particularly interested in how hearing difficulties impact upon the development of language and literacy in children, studying what aspects of hearing are important for language acquisition, and also those factors that contribute to the poor language outcomes that some children with hearing loss experience.

“I work with children with normal hearing, as well as those with a range of different hearing and language difficulties,” she explains. “Ultimately, the goal is to find out how we might improve outcomes for children with hearing difficulties, so that they no longer experience barriers to achieving their full potential.”

Lorna will shortly begin a longitudinal cohort study looking at outcomes of children with hearing loss who were identified as part of the NHS Newborn Hearing Screening Programme. This will involve visiting over 100 children with early-identified hearing loss in their schools and homes, in and around Cambridgeshire and the South-East of England.

“I hope that my research will lead to changes to the way in which we detect, diagnose, and treat hearing loss in children in the future. This could be through changes to the NHS Newborn Hearing Screening Programme or the school-entry hearing screen, improvements in hearing aid and cochlear implant technology, and the introduction of targeted interventions for those at risk of future difficulties, ideally before those difficulties occur.”

Cambridge is the ideal place to carry out such research, she explains, as it is rapidly becoming a centre for research into hearing with links across the university, Cambridge University Hospitals, and beyond. “It is a particularly exciting time to be part of the research community here, with lots of opportunities for collaborations and new ideas.”

Lorna has two children of her own, and describes herself as “one of a rare but growing breed of part-time scientists, full-time parents”. She is passionate about promoting equality within the sciences, and addressing issues relating to the “leaky pipeline” within STEM subjects, which sees the number of women in STEM fall dramatically at more senior levels.


Source: University of Cambridge

1 Comment

  1. That’s a no brainer !
    We are born with more long axons in the brain, and as the development continues, these long axons are plastically changed to shorter one to generate more synapses within the gray matter. If a mild to moderate hearing loss is already occurring, then, the synaptical changes within the gray matter will be affected that lead to speech and language developmental diversions that can be seen as nasal type twangy overlaps in speech. This will go away once the neuronal explosion continues and there are adequate synapses created , and speech sounds will be better regulated. and memorized!
    Glad to know that someone else besides me has looked into it!

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