The Department of Biopsychology reports:The visual system of the pigeon

In a study published in the journal “Behavioural Brain Research” Martin Stacho and his colleagues from the Department of Biopsychology investigate how pigeons process visual input. Their results provide an insight into the workings of the pigeon brain and show some functional similarities to mammals. Their work is part of the efforts of project B5 of Collaborative Research Center 874.

Functional organisation of telencephalic visual association fields in pigeons

Birds show remarkable visual abilities that surpass most of our visual psychophysiological abilities. In this study, scientists from the biopsychology investigated visual associative areas of the tectofugal visual system in pigeons. Similar to the condition in mammals, ascending visual pathways in birds are subdivided into parallel form/color vs. motion streams at the thalamic and primary telencephalic level. However, we know practically nothing about the functional organization of those telencephalic areas that receive input from the primary visual telencephalic fields. The current study therefore had two objectives: first, to reveal whether these visual associative areas of the tectofugal system are activated during visual discrimination tasks; second, to test whether separated form/color vs. motion pathways can be discerned among these association fields. To this end, pigeons were trained to discriminate either form/color or motion stimuli. The immediate early gene protein ZENK was used to capture the activity of the visual associative areas during the task. Indeed, several visual associative telencephalic structures could be identified by activity pattern changes during discriminations. However, none of these areas displayed a difference between form/color vs. motion sessions. The presence of such a distinction in thalamo-telencephalic, but not in further downstream visual association areas opens the possibility that these separate streams converge very early in birds, which possibly minimizes long-range connections due to the evolutionary pressure toward miniaturized brains.