Researchers at the University of Oxford have suggested that ultrasound-repellers could help reduce hedgehog deaths by cars. The proposal is based on new findings, published today (11 March) in Biology Letters , which demonstrate for the first time that hedgehogs can hear high-frequency ultrasound.
The European hedgehog is one of our best-loved mammals, but populations are in grave decline with the species being newly classed as “near threatened” by the International Union for Conservation of Nature in 2024. A major cause of hedgehog deaths is road traffic accidents, which are thought to kill up to one in three hedgehogs in local populations .
A new study now suggests that ultrasound repellers could be used to deter hedgehogs from roads, reducing the number killed by cars. Up to now, it was unknown whether hedgehogs could hear this range.
Lead researcher Assistant Professor Sophie Lund Rasmussen (Wildlife Conservation Research Unit/Department of Biology, University of Oxford and University of Copenhagen) said: “Having discovered that hedgehogs can hear in ultrasound, the next stage will be to find collaborators within the car industry to fund and design sound repellents for cars. If our future research shows that it proves possible to design an effective device to keep hedgehogs away from cars, this could have a significant impact in reducing the threat of road traffic to the declining European hedgehog.”
In the study, researchers at the University of Oxford collaborated with colleagues in Denmark to test the auditory brainstem response of 20 rehabilitated hedgehogs from Danish wildlife rescue centres. This method uses small electrodes placed on the animals to record electrical signals travelling between the inner ear and the brain, while short bursts of sounds are played through a small loudspeaker.
The electrodes detected that the brainstem fired when signals were played across a range of 4-85 kHz, with a peak sensitivity around 40 kHz. This demonstrates that hedgehogs can hear in the ultrasound range (which starts at frequencies greater than 20 kHz), up to at least 85 kHz. After being checked by a veterinarian after the experiments, the hedgehogs were released back into the wild on the following night.
The team also carried out high-resolution micro-CT scans of a dead hedgehog (which had been euthanised after being critically injured by a rat trap). The scans were used to build an interactive 3D model of the hedgehog’s ear, revealing features never seen before. The model showed that hedgehogs have very small, dense middle-ear bones and a partly fused joint between the eardrum and the first of these bones. This makes the whole chain of bones stiffer, helping it pass very high-pitched sounds efficiently – a hallmark of animals, such as echolocating bats, that can hear ultrasound.
The scans also revealed that hedgehogs have a small stapes (the smallest middle-ear bone that connects the chain of ear bones to the inner ear’s fluid-filled cochlea). A smaller, lighter stapes can vibrate more quickly, enabling it to transmit high-frequency sound waves. The cochlea was also found to be relatively short and compact, enabling it to better process ultrasonic vibrations.
The results suggest that it would be possible to design ultrasonic repellents that can be heard by hedgehogs, but not humans or pets.* If proved effective, these could potentially be used to deter hedgehogs from roads and other potential threats, such as robotic lawnmowers and garden strimmers.
Co-author Professor David Macdonald (Wildlife Conservation Research Unit/Department of Biology, University of Oxford) said: “It is especially exciting when research motivated by conservation leads to a fundamental new discovery about a species biology which, full circle, in turn offers a new avenue for conservation. The critical question now is whether the hedgehogs respond to ultrasound in ways that might reduce the risks of collisions with robotic lawnmowers or even cars”.
The study was a collaboration between the University of Oxford, The Natural History Museum Denmark at University of Copenhagen, City Dyreklinik (Copenhagen), Aarhus University, Aarhus University Hospital, University of Southern Denmark.
*Humans hear in the range of 20-20,000 Hz, dogs 67- 45,000 Hz, and cats 45-65,000 Hz.
Notes to editors:
For media enquiries and interview requests, contact Dr Sophie Lund Rasmussen: sophie.rasmussen@biology.ox.ac.uk UK mobile phone: +44 7871837510
For Danish press - Danish mobile phone: +45 22117268
The study ‘Hearing and anatomy of the ear of the European hedgehog Erinaceus europaeus ’ will be published in Biology Letters at 00:05 GMT Wednesday 11 March 2026 at https://doi.org/10.1098/rsbl.2025.0535
To view a copy of the study before this under embargo contact Caroline Wood: caroline.wood@admin.ox.ac.uk
Images and video related to this study that can be used to illustrate articles can be found here https://drive.google.com/drive/folders/1JAK49PJX004CuigsTKVsCqDtBFoJaL_9?usp=sharing These are for editorial purposes relating to this press release ONLY and MUST be credited (see caption in filename). They MUST NOT be sold on to third parties.
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Biology Letters
Hearing and anatomy of the ear of the European hedgehog Erinaceus europaeus