Abstract
Integration of multiple properties of an object is a fundamental function of the visual cortex in object recognition. For instance, surface patterns and contour shapes are thought to be crucial characteristics that jointly contribute to recognition. However, the mechanisms of integration and corresponding cortical representations have not been fully clarified. We investigated the integration of surfaces and shapes by examining the tilt after effects (TAEs) evoked by the symmetry of patterns and contours. As symmetry in both pattern and contour evokes TAEs, we can directly measure the interaction between the two. The measured TAEs exhibited mutual transfer between the symmetry of the pattern (SP) and that of the contour shape (SS), i.e., adaptation by SP (SS) evoked TAEs when tested by SS (SP), suggesting the existence of an integrated representation. Next, we examined the interaction between SP and SS when both were simultaneously presented in adaptation. Congruent adaptors wherein their symmetry axes aligned evoked compressive interaction, whereas incongruent adaptors wherein the axes of SP and SS tilted to the opposite directions evoked subtractive interaction. These results suggest the existence of a cortical representation that integrates the properties of the surface and shape with suppressive interactions, which can provide crucial insights into the formation of object representation as well as the integration of visual information in the cortex.
Highlights
Integration of multiple properties of an object is a fundamental function of the visual cortex in object recognition
The results revealed the partial mutual transfer of tilt after effects (TAEs) between symmetry of pattern (SP) and symmetry of shape (SS); that is, TAEs were observed when participants were adapted to SS and tested by SP, and vice versa, suggesting the existence of an integrated representation that combines the properties of surface and shape
We further investigated the interactions between SP and SS in the adaptation
Summary
Integration of multiple properties of an object is a fundamental function of the visual cortex in object recognition. Congruent adaptors wherein their symmetry axes aligned evoked compressive interaction, whereas incongruent adaptors wherein the axes of SP and SS tilted to the opposite directions evoked subtractive interaction These results suggest the existence of a cortical representation that integrates the properties of the surface and shape with suppressive interactions, which can provide crucial insights into the formation of object representation as well as the integration of visual information in the cortex. The visual system takes advantage of integrating multiple attributes to establish robustness and reliability Surface properties such as color, texture, and glossiness and object shapes such as contours of the whole and parts are key features for object recognition. Recent studies have investigated various properties of symmetry based on the detection of symmetry axes and TAEs35,36,38–40 As symmetry in both pattern and contour shape evokes adaptation to symmetry axes, TAEs are expected to be a good measure to examine the interaction and integration of surface patterns and contour shapes. The results revealed the partial mutual transfer of TAEs between SP and SS; that is, TAEs were observed when participants were adapted to SS and tested by SP, and vice versa, suggesting the existence of an integrated representation that combines the properties of surface and shape
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