Denise Foresteire's Outputs (5)

6-hour Training in click-based echolocation changes practice in visual impairment professionals (2023)
Journal Article
Thaler, L., Di Gregorio, G., & Foresteire, D. (online). 6-hour Training in click-based echolocation changes practice in visual impairment professionals. Frontiers in Rehabilitation Sciences, 4, https://doi.org/10.3389/fresc.2023.1098624

Click-based echolocation can support mobility and orientation in people with vision impairments (VI) when used alongside other mobility methods. Only a small number of people with VI use click-based echolocation. Previous research about echolocation... Read More about 6-hour Training in click-based echolocation changes practice in visual impairment professionals.

Human click-based echolocation: Effects of blindness and age, and real-life implications in a 10-week training program (2021)
Journal Article
Norman, L. J., Dodsworth, C., Foresteire, D., & Thaler, L. (2021). Human click-based echolocation: Effects of blindness and age, and real-life implications in a 10-week training program. PLoS ONE, 16(6), Article e0252330. https://doi.org/10.1371/journal.pone.0252330

Understanding the factors that determine if a person can successfully learn a novel sensory skill is essential for understanding how the brain adapts to change, and for providing rehabilitative support for people with sensory loss. We report a traini... Read More about Human click-based echolocation: Effects of blindness and age, and real-life implications in a 10-week training program.

Increased emission intensity can compensate for the presence of noise in human click-based echolocation (2021)
Journal Article
Castillo-Serrano, J., Norman, L., Foresteire, D., & Thaler, L. (2021). Increased emission intensity can compensate for the presence of noise in human click-based echolocation. Scientific Reports, 11(1), Article 1750. https://doi.org/10.1038/s41598-021-81220-9

Echolocating bats adapt their emissions to succeed in noisy environments. In the present study we investigated if echolocating humans can detect a sound-refecting surface in the presence of noise and if intensity of echolocation emissions (i.e. click... Read More about Increased emission intensity can compensate for the presence of noise in human click-based echolocation.

Insoluble Aβ overexpression in an App knock-in mouse model alters microstructure and gamma oscillations in the prefrontal cortex, and impacts on anxiety-related behaviours (2019)
Journal Article
Pervolaraki, E., Hall, S., Foresteire, D., Saito, T., Saido, T., Whittington, M., …Dachtler, J. (2019). Insoluble Aβ overexpression in an App knock-in mouse model alters microstructure and gamma oscillations in the prefrontal cortex, and impacts on anxiety-related behaviours. Disease Models and Mechanisms, 12(9), Article dmm040550. https://doi.org/10.1242/dmm.040550

We studied a new App knock-in mice model of Alzheimer’s disease (AppNL-G-F), containing the Swedish KM670/671NL mutation, the Iberian I716F mutation and the Artic E693G mutation, which generates elevated levels of Aβ40 and Aβ42 without the confounds... Read More about Insoluble Aβ overexpression in an App knock-in mouse model alters microstructure and gamma oscillations in the prefrontal cortex, and impacts on anxiety-related behaviours.

Visual sensory stimulation interferes with people’s ability to echolocate object size (2017)
Journal Article
Thaler, L., & Foresteire, D. (2017). Visual sensory stimulation interferes with people’s ability to echolocate object size. Scientific Reports, 7, Article 13069. https://doi.org/10.1038/s41598-017-12967-3

Echolocation is the ability to use sound-echoes to infer spatial information about the environment. People can echolocate for example by making mouth clicks. Previous research suggests that echolocation in blind people activates brain areas that proc... Read More about Visual sensory stimulation interferes with people’s ability to echolocate object size.