Functional cerebral asymmetries, once thought to be exclusively human, are
now accepted to be a widespread principle of brain organization in vertebra
tes [1]. The prevalence of lateralization makes it likely that it has some
major advantage. Until now, however, conclusive evidence has been lacking.
To analyze the relation between the extent of cerebral asymmetry and the de
gree of performance in visual foraging, we studied grain-grit discriminatio
n success in pigeons, a species with a left hemisphere dominance for visual
object processing [2,3]. The birds performed the task under left-eye, righ
t-eye or binocular seeing conditions. In most animals, right-eye seeing was
superior to left-eye seeing performance, and binocular performance was hig
her than each monocular level. The absolute difference between left- and ri
ght-eye levels was defined as a measure for the degree of visual asymmetry.
Animals with higher asymmetries were more successful in discriminating gra
in from grit under binocular conditions. This shows that an increase in vis
ual asymmetry enhances success in visually guided foraging. Possibly, asymm
etries of the pigeon's visual system increase the computational speed of ob
ject recognition processes by concentrating them into one hemisphere while
preventing the other side of the brain from initiating conflicting search s
equences of its own.