Abstract
Primate cerebral cortex is highly convoluted with much of the cortical surface buried in sulcal folds. The origins of cortical folding and its functional relevance have been a major focus of systems and cognitive neuroscience, especially when considering stereotyped patterns of cortical folding that are shared across individuals within a primate species and across multiple species. However, foundational questions regarding organizing principles shared across species remain unanswered. Taking a cross-species comparative approach with a careful consideration of historical observations, we investigate cortical folding relative to primary visual cortex (area V1). We identify two macroanatomical structures—the retrocalcarine and external calcarine sulci—in 24 humans and 6 macaque monkeys. We show that within species, these sulci are identifiable in all individuals, fall on a similar part of the V1 retinotopic map, and thus, serve as anatomical landmarks predictive of functional organization. Yet, across species, the underlying eccentricity representations corresponding to these macroanatomical structures differ strikingly across humans and macaques. Thus, the correspondence between retinotopic representation and cortical folding for an evolutionarily old structure like V1 is species-specific and suggests potential differences in developmental and experiential constraints across primates.
Highlights
A major goal in systems and cognitive neuroscience is to understand the evolution of the human cerebral cortex (Van Essen 2007; Zilles et al 2013)
The retrocalcarine sulcus (rCaS) and external calcarine sulcus (eCaS) were localized to the medial and lateral surfaces of occipital cortex, respectively. In both macaques and humans, the rCaS was located on the most posterior portion of the medial surface with the long axis oriented along the inferior-superior dimension
The macaque eCaS was located in the ventral half of the operculum of the occipital lobe with the long axis oriented along the posterior–anterior axis
Summary
A major goal in systems and cognitive neuroscience is to understand the evolution of the human cerebral cortex (Van Essen 2007; Zilles et al 2013). Despite the widespread interest and a general convergence of conclusions across studies regarding comparisons of primary structures (e.g. the calcarine sulcus, CaS) and primary sensory areas (e.g. visual area V1; for reviews, see Rosa and Tweedale (2005), Van Essen (2007), Zilles et al (2013), Arcaro and Kastner (2015), Van Essen et al (2018), Van Essen and Glasser (2018), Wandell et al (2007) and Wandell and Winawer (2011)), several historical observations have been commonly overlooked, which in turn, has generated modern discrepancies Resolving these discrepancies through focused, cross-species comparative studies is critically necessary to produce accurate insights regarding the evolution of the cerebral cortex. In the late nineteenth and early twentieth centuries, this portion of the CaS was so frequently identified
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