Chiandetti, Cinzia; Dissegna, Andrea; Rogers, Lesley J; Turatto, Massimo

Author(s)

Chiandetti, Cinzia

Dissegna, Andrea

Rogers, Lesley J

Turatto, Massimo

Publication Date

2023-10-11

Abstract

<p>Hemispheric specialization influences stimulus processing and behavioural control, affecting responses to relevant stimuli. However, most sensory input is irrelevant and must be filtered out to prevent interference with task-relevant behaviour, a process known as habituation. Despite habituation's vital role, little is known about hemispheric specialization for this brain function. We conducted an experiment with domestic chicks, an elite animal model to study lateralization. They were exposed to distracting visual stimuli while feeding when using binocular or monocular vision. Switching the viewing eye after habituation, we examined if habituation was confined to the stimulated hemisphere or shared across hemispheres. We found that both hemispheres learned equally to ignore distracting stimuli. However, embryonic light stimulation, influencing hemispheric specialization, revealed an asymmetry in interhemispheric transfer of the irrelevant information discarded via habituation. Unstimulated chicks exhibited a directional bias, with the right hemisphere failing to transfer distracting stimulus information to the left hemisphere, while transfer from left to right was possible. Nevertheless, embryonic light stimulation counteracted this asymmetry, enhancing communication from the right to the left hemisphere and reducing the pre-existing imbalance. This sharing extends beyond hemisphere-specific functions and encompasses a broader representation of irrelevant events.</p>

Citation

Biology Letters, v.19 (10)

ISSN

1744-957X

1744-9561

Pubmed ID

37817575

Link

https://hdl.handle.net/1959.11/62048

Publisher

The Royal Society Publishing

Title

Unlocking the symmetric transfer of irrelevant information: gene–environment interplay and enhanced interhemispheric cross-talk

Type of document

Journal Article

Entity Type

Publication

Author(s)	Chiandetti, Cinzia Dissegna, Andrea Rogers, Lesley J Turatto, Massimo
Publication Date	2023-10-11
Abstract	<p>Hemispheric specialization influences stimulus processing and behavioural control, affecting responses to relevant stimuli. However, most sensory input is irrelevant and must be filtered out to prevent interference with task-relevant behaviour, a process known as habituation. Despite habituation's vital role, little is known about hemispheric specialization for this brain function. We conducted an experiment with domestic chicks, an elite animal model to study lateralization. They were exposed to distracting visual stimuli while feeding when using binocular or monocular vision. Switching the viewing eye after habituation, we examined if habituation was confined to the stimulated hemisphere or shared across hemispheres. We found that both hemispheres learned equally to ignore distracting stimuli. However, embryonic light stimulation, influencing hemispheric specialization, revealed an asymmetry in interhemispheric transfer of the irrelevant information discarded via habituation. Unstimulated chicks exhibited a directional bias, with the right hemisphere failing to transfer distracting stimulus information to the left hemisphere, while transfer from left to right was possible. Nevertheless, embryonic light stimulation counteracted this asymmetry, enhancing communication from the right to the left hemisphere and reducing the pre-existing imbalance. This sharing extends beyond hemisphere-specific functions and encompasses a broader representation of irrelevant events.</p>
Citation	Biology Letters, v.19 (10)
ISSN	1744-957X 1744-9561
Pubmed ID	37817575
Link	https://hdl.handle.net/1959.11/62048
Publisher	The Royal Society Publishing
Title	Unlocking the symmetric transfer of irrelevant information: gene–environment interplay and enhanced interhemispheric cross-talk
Type of document	Journal Article
Entity Type	Publication

Unlocking the symmetric transfer of irrelevant information: gene–environment interplay and enhanced interhemispheric cross-talk

Files: