How blind people build a sense of space from sound

New research has revealed insights into the brain processes of human echolocators - blind people who use mouth clicks and the returning echoes from nearby objects to navigate their environment.

Scientists from Cardiff University and the Smith–Kettlewell Eye Research Institute in San Francisco have, for the first time, uncovered how the brain processes auditory information from echoes to give clues about their environment moment by moment, showing how brain activity tracks and accumulates the spatial information and relates to improvements in echolocation skills.

Haydee Garcia Lazaro, Cardiff University Brain Research Imaging Centre, said: “Some blind people can navigate and represent their surroundings using echolocation. By interpreting echoes that bounce back from objects around them, they can work out where objects are, how far away they are, and even their shape and material.

“This ability can be extremely accurate in expert human echolocators – but little is known about how the brain combines information from multiple echoes over time to build a reliable sense of space.”

The researchers asked blind expert echolocators (who regularly use echolocation in their daily life) and sighted people (with no echolocation training) to listen to realistic, computer‑generated mouth clicks and their echoes, which simulated an object placed at a 1-metre distance slightly to the left or right in front of them. During the experiment, they heard sequences ranging from a few clicks to up to eleven clicks in a row. Their task was to decide whether the object was on the left or the right.

During the task, the researchers recorded the participant’s brain activity using an electroencephalogram (EEG). This allowed them to track changes in the brain signals over time at the millisecond level.

The researchers found that blind expert echolocators were significantly better at judging where the object was, with some of the echolocators identifying the position of the object with just two clicks. Novice-sighted participants, however, struggled to solve the task, performing at chance, and showing little improvement even when more clicks were provided.

The researchers also found that among the blind participants, those who had been blind from birth performed better than those who lost their sight later in life, consistent with earlier studies.

The echolocators became more accurate as they heard more clicks, suggesting that the brain ‘adds up’ information across clicks, rather than relying on a single moment of sound.

“Each echo helped them to build up a finer picture of the object and the surrounding space, sharpening that representation,” added Haydee Garcia Lazaro.

The EEG recordings revealed that the expert echolocators’ brains could distinguish left from right after the very first click. Importantly, the strength of this early brain signal predicted how well each person performed overall. People whose brains showed clearer left‑right differences early on tended to be more accurate.

Further clicks didn’t simply trigger the same brain response. Instead, brain activity changed systematically over time, reflecting the brain’s ongoing process of building and refining a spatial representation.

“To better understand this cumulative process, we modelled how information builds across clicks, testing different ways the brain might turn neural signals into decisions – showing that for expert echolocators, while the first click is very important, they don’t only rely on the best single click. Instead, they combine information across clicks in a progressive and cumulative manner, and this differs from person to person,” added Santani Teng, Smith–Kettlewell Eye Research Institute.

The research, Neural and Behavioral Correlates of Evidence Accumulation in Human Click-Based Echolocation, was published in eNeuro.