Intrinsic Functional Boundaries of Lateral Frontal Cortex in the Common Marmoset Monkey

The common marmoset ( Callithrix jacchus ) is a small New World primate species that has been recently targeted as a potentially powerful preclinical model of human prefrontal cortex dysfunction. Although the structural boundaries of frontal cortex were described in marmosets at the start of the 20 th century (Brodmann, 1909) and refined more recently (e.g., Paxinos et al., 2012), the broad functional boundaries of marmoset frontal cortex have yet to be established. In this study, we sought to functionally derive boundaries of marmoset lateral frontal cortex (LFC) using ultra-high field (9.4 T) resting state functional magnetic resonance imaging (RS-fMRI). We collected RS-fMRI in seven (4 females, 3 males) lightly anesthetized marmosets and employed a data-driven hierarchical clustering approach to derive subdivisions of LFC based on intrinsic functional connectivity. We then conducted seed-based analyses to assess the functional connectivity between these clusters and the rest of the brain. The results demonstrated seven distinct functional clusters within LFC. The functional connectivity patterns of these clusters with the rest of the brain were also found to be distinct and organized along a rostro-caudal gradient, consonant to that found in humans and macaques. Overall, these results support the view that marmosets are a promising preclinical modelling species for studying LFC dysfunction related to neuropsychiatric or neurodegenerative human brain diseases. SIGNIFICANCE STATEMENT The common marmoset is a New World primate that has garnered recent attention as a powerful complement to canonical Old World primate (e.g., macaques) and rodent models (e.g., rats, mice) for preclinical modelling of the human brain in healthy and diseased states. A critical step in the development of marmosets for such models is to characterize functional network topologies of frontal cortex in healthy, normally functioning marmosets -- i.e., how these circuitries are functionally divided, and how those topologies compare to human circuitry. To our knowledge, this is the first study to demonstrate functional boundaries of LFC and the corresponding network topologies in marmoset monkeys.