We proposed to unravel how fine-grain representational content is represented in the brain by a) uncovering object-related dimensions that drive the fine-grain topography of object-related areas; and b) testing how these dimensions shape our interactions with objects. We first focused on finding object-related dimensions, and exploring the representational content of object knowledge. We show that object representation follows multidimensionality. Almeida et al. (2023; CommsBio) obtained a series of dimensions, extracted from how individuals mentally structure manipulable object knowledge through a dimensionality reduction technique. Specifically, we show that dimensions such as object material, object elongation, or grasp type, among others, structure our mental reasoning about (manipulable) objects. Importantly, here we also show that these dimensions are able to predict neural response to the presentations of the objects themselves. We further explore this aspect of object related dimensionality in several other papers. For instance, in Bergstrom et al. (2021; Cortex) and Hussain et al., (2024; Neuropsychologia) we demonstrate the importance of the dimension “grasp type” in how information about objects is stored and represented in the brain. We also showed that the extracted dimensions can predict behavioral responses (Almeida et al., 2023; CommsBio), even for items that were not used to extract those dimensions (Walbrin et al., 2024; iSCIENCE).
We then showed that the different object-related dimensions obtained previously governed the topography of object knowledge in the brain. Importantly, and for the first time, we showed topographical maps for object-related dimensions in dorsal and ventral occipital cortex that code for the score of each object on each target dimension in a linear progression following a particular direction along the cortical surface. Maps for each dimension are distinct, are consistent across individuals, and are not exhausted by eccentricity (i.e. major low-level visual confounds). Thus, object information is coded in multiple topographical maps – i.e. contentopic maps. These contentopic maps refer to intermediate level visual and visuomotor representations.