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1. Three-layer model with absorption for conservative estimation of the maximum acoustic transmission coefficient through the human skull for transcranial ultrasound stimulation

Author

Attali, D., Tiennot, T., Schafer, M.E., Fouragnan, E.F., Sallet, J., Caskey, C.F., Chen, R., Darmani, G., Bubrick, E.J., Butler, C., Stagg, C.J., Klein-Flügge, M.C., Verhagen, L., Yoo, S.S., Pauly, K.R.B., Aubry, J.F., Attali, D., Tiennot, T., Schafer, M.E., Fouragnan, E.F., Sallet, J., Caskey, C.F., Chen, R., Darmani, G., Bubrick, E.J., Butler, C., Stagg, C.J., Klein-Flügge, M.C., Verhagen, L., Yoo, S.S., Pauly, K.R.B., and Aubry, J.F.

Abstract

Item does not contain fulltext, Transcranial ultrasound stimulation (TUS) has been shown to be a safe and effective technique for non-invasive superficial and deep brain stimulation. Safe and efficient translation to humans requires estimating the acoustic attenuation of the human skull. Nevertheless, there are no international guidelines for estimating the impact of the skull bone. A tissue independent, arbitrary derating was developed by the U.S. Food and Drug Administration to take into account tissue absorption (0.3 dB/cm-MHz) for diagnostic ultrasound. However, for the case of transcranial ultrasound imaging, the FDA model does not take into account the insertion loss induced by the skull bone, nor the absorption by brain tissue. Therefore, the estimated absorption is overly conservative which could potentially limit TUS applications if the same guidelines were to be adopted. Here we propose a three-layer model including bone absorption to calculate the maximum pressure transmission through the human skull for frequencies ranging between 100 kHz and 1.5 MHz. The calculated pressure transmission decreases with the frequency and the thickness of the bone, with peaks for each thickness corresponding to a multiple of half the wavelength. The 95th percentile maximum transmission was calculated over the accessible surface of 20 human skulls for 12 typical diameters of the ultrasound beam on the skull surface, and varies between 40% and 78%. To facilitate the safe adjustment of the acoustic pressure for short ultrasound pulses, such as transcranial imaging or transcranial ultrasound stimulation, a table summarizes the maximum pressure transmission for each ultrasound beam diameter and each frequency.

Published
2023

2. An open resource combining multi-contrast MRI and microscopy in the macaque brain

Author

Howard, A.F.D., Huszar, I.N., Smart, A., Cottaar, M., Daubney, G., Hanayik, T., Khrapitchev, A.A., Mars, R.B., Mollink, J., Scott, C., Sibson, N.R., Sallet, J., Jbabdi, S., Miller, K.L., Howard, A.F.D., Huszar, I.N., Smart, A., Cottaar, M., Daubney, G., Hanayik, T., Khrapitchev, A.A., Mars, R.B., Mollink, J., Scott, C., Sibson, N.R., Sallet, J., Jbabdi, S., and Miller, K.L.

Abstract

Contains fulltext : 292228.pdf (Publisher’s version ) (Open Access), Understanding brain structure and function often requires combining data across different modalities and scales to link microscale cellular structures to macroscale features of whole brain organisation. Here we introduce the BigMac dataset, a resource combining in vivo MRI, extensive postmortem MRI and multi-contrast microscopy for multimodal characterisation of a single whole macaque brain. The data spans modalities (MRI and microscopy), tissue states (in vivo and postmortem), and four orders of spatial magnitude, from microscopy images with micrometre or sub-micrometre resolution, to MRI signals on the order of millimetres. Crucially, the MRI and microscopy images are carefully co-registered together to facilitate quantitative multimodal analyses. Here we detail the acquisition, curation, and first release of the data, that together make BigMac a unique, openly-disseminated resource available to researchers worldwide. Further, we demonstrate example analyses and opportunities afforded by the data, including improvement of connectivity estimates from ultra-high angular resolution diffusion MRI, neuroanatomical insight provided by polarised light imaging and myelin-stained histology, and the joint analysis of MRI and microscopy data for reconstruction of the microscopy-inspired connectome. All data and code are made openly available.

Published
2023

3. A map of white matter tracts in a lesser ape, the lar gibbon

Author

Bryant, K.L., Manger, P.R., Bertelsen, M.F., Khrapitchev, A.A., Sallet, J., Benn, R.A., Mars, R.B., Bryant, K.L., Manger, P.R., Bertelsen, M.F., Khrapitchev, A.A., Sallet, J., Benn, R.A., and Mars, R.B.

Abstract

Item does not contain fulltext, The recent development of methods for constructing directly comparable white matter atlases in primate brains from diffusion MRI allows us to probe specializations unique to humans, great apes, and other primate taxa. Here, we constructed the first white matter atlas of a lesser ape using an ex vivo diffusion-weighted scan of a brain from a young adult (5.5 years) male lar gibbon. We find that white matter architecture of the gibbon temporal lobe suggests specializations that are reminiscent of those previously reported for great apes, specifically, the expansion of the arcuate fasciculus and the inferior longitudinal fasciculus in the temporal lobe. Our findings suggest these white matter expansions into the temporal lobe were present in the last common ancestor to hominoids approximately 16 million years ago and were further modified in the great ape and human lineages. White matter atlases provide a useful resource for identifying neuroanatomical differences and similarities between humans and other primate species and provide insight into the evolutionary variation and stasis of brain organization., 31 oktober 2023, 16 p.

Published
2023

4. List of Contributors

Author

Ahmed, B., primary, Balleine, B.W., additional, Ballesta, S., additional, Bernardi, S., additional, Blangero, A., additional, Bradfield, L.A., additional, Chaisangmongkon, W., additional, Chierchia, G., additional, Clark, L., additional, Dagher, A., additional, Dalley, J.W., additional, Diaz, J.A., additional, Dreher, J.-C., additional, Duhamel, J.-R., additional, Eshel, N., additional, Fellows, L.K., additional, Fernald, R.D., additional, Fernández, G., additional, Fletcher, P.C., additional, Fuster, J.M., additional, Gherman, S., additional, Glimcher, P.W., additional, Grupe, D.W., additional, Haber, S.N., additional, Han, J.-E., additional, Henckens, M.J.A.G., additional, Hermans, E.J., additional, Izuma, K., additional, Jazayari, M., additional, Joëls, M., additional, Kahnt, T., additional, Krug, K., additional, Lee, D., additional, Lefevre, A., additional, Ligneul, R., additional, Louie, K., additional, Mars, R.B., additional, Murray, G.K., additional, Neseliler, S., additional, Neubert, F.X., additional, Noonan, M.P., additional, Ortner, N., additional, Palminteri, S., additional, Pessiglione, M., additional, Pezawas, L., additional, Philiastides, M.G., additional, Rabl, U., additional, Robbins, T.W., additional, Ruff, C.C., additional, Saga, Y., additional, Sallet, J., additional, Salzman, D., additional, Schultz, W., additional, Seo, H., additional, Singer, T., additional, Sirigu, A., additional, Smith, J., additional, Soltani, A., additional, Summerfield, C., additional, Tian, J., additional, Tobler, P.N., additional, Tremblay, L., additional, Tudor-Sfetea, C., additional, Uchida, N., additional, Ugazio, G., additional, Vaidya, A.R., additional, Voon, V., additional, Wang, X.-J., additional, and Witt, K., additional

Published
2017
Full Text
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7. The Digital Brain Bank, an open access platform for post-mortem datasets

Author

Tendler, B.C., Hanayik, T., Ansorge, O., Bangerter-Christensen, S., Berns, G.S., Bertelsen, M.F., Bryant, K.L., Foxley, S., Howard, A.F.D., Huszar, I., Khrapitchev, A.A., Leonte, A., Manger, P.R., Menke, R.A.L., Mollink, J., Mortimer, D., Pallebage-Gamarallage, M., Roumazeilles, L., Sallet, J., Scott, C., Smart, A., Turner, M.R., Wang, C., Jbabdi, S., Mars, R.B., Miller, K.L., Tendler, B.C., Hanayik, T., Ansorge, O., Bangerter-Christensen, S., Berns, G.S., Bertelsen, M.F., Bryant, K.L., Foxley, S., Howard, A.F.D., Huszar, I., Khrapitchev, A.A., Leonte, A., Manger, P.R., Menke, R.A.L., Mollink, J., Mortimer, D., Pallebage-Gamarallage, M., Roumazeilles, L., Sallet, J., Scott, C., Smart, A., Turner, M.R., Wang, C., Jbabdi, S., Mars, R.B., and Miller, K.L.

Abstract

Contains fulltext : 247684.pdf (Publisher’s version ) (Open Access), Post-mortem MRI provides the opportunity to acquire high-resolution datasets to investigate neuroanatomy, and validate the origins of image contrast through microscopy comparisons. We introduce the Digital Brain Bank (open.win.ox.ac.uk/DigitalBrainBank), a data release platform providing open access to curated, multimodal post-mortem neuroimaging datasets. Datasets span three themes - Digital Neuroanatomist: datasets for detailed neuroanatomical investigations; Digital Brain Zoo: datasets for comparative neuroanatomy; Digital Pathologist: datasets for neuropathology investigations. The first Digital Brain Bank release includes twenty one distinctive whole-brain diffusion MRI datasets for structural connectivity investigations, alongside microscopy and complementary MRI modalities. This includes one of the highest-resolution whole-brain human diffusion MRI datasets ever acquired, whole-brain diffusion MRI in fourteen non-human primate species, and one of the largest post-mortem whole-brain cohort imaging studies in neurodegeneration. The Digital Brain Bank is the culmination of our lab's investment into post-mortem MRI methodology and MRI-microscopy analysis techniques. This manuscript provides a detailed overview of our work with post-mortem imaging to date, including the development of diffusion MRI methods to image large post-mortem samples, including whole, human brains. Taken together, the Digital Brain Bank provides cross-scale, cross-species datasets facilitating the incorporation of post-mortem data into neuroimaging studies.

Published
2022

8. The Digital Brain Bank, an open access platform for post-mortem imaging datasets

Author

Tendler, B.C., Hanayik, T., Ansorge, O., Bangerter-Christensen, S., Berns, G.S., Bertelsen, M.F., Bryant, K.L., Foxley, S., Howard, A.F.D., Huszar, I.N., Khrapitchev, A.A., Leonte, A., Manger, P.R., Menke, R.A.L., Mollink, J., Mortimer, D., Pallebage-Gamarallage, M., Roumazeilles, L., Sallet, J., Scott, C., Smart, A., Turner, M.R., Wang, C., Jbabdi, S., Mars, R.B., Miller, K.L., Tendler, B.C., Hanayik, T., Ansorge, O., Bangerter-Christensen, S., Berns, G.S., Bertelsen, M.F., Bryant, K.L., Foxley, S., Howard, A.F.D., Huszar, I.N., Khrapitchev, A.A., Leonte, A., Manger, P.R., Menke, R.A.L., Mollink, J., Mortimer, D., Pallebage-Gamarallage, M., Roumazeilles, L., Sallet, J., Scott, C., Smart, A., Turner, M.R., Wang, C., Jbabdi, S., Mars, R.B., and Miller, K.L.

Abstract

Contains fulltext : 247684.pdf (Publisher’s version ) (Open Access), Post-mortem MRI provides the opportunity to acquire high-resolution datasets to investigate neuroanatomy, and validate the origins of image contrast through microscopy comparisons. We introduce the Digital Brain Bank (open.win.ox.ac.uk/DigitalBrainBank), a data release platform providing open access to curated, multimodal post-mortem neuroimaging datasets. Datasets span three themes - Digital Neuroanatomist: datasets for detailed neuroanatomical investigations; Digital Brain Zoo: datasets for comparative neuroanatomy; Digital Pathologist: datasets for neuropathology investigations. The first Digital Brain Bank release includes twenty one distinctive whole-brain diffusion MRI datasets for structural connectivity investigations, alongside microscopy and complementary MRI modalities. This includes one of the highest-resolution whole-brain human diffusion MRI datasets ever acquired, whole-brain diffusion MRI in fourteen non-human primate species, and one of the largest post-mortem whole-brain cohort imaging studies in neurodegeneration. The Digital Brain Bank is the culmination of our lab's investment into post-mortem MRI methodology and MRI-microscopy analysis techniques. This manuscript provides a detailed overview of our work with post-mortem imaging to date, including the development of diffusion MRI methods to image large post-mortem samples, including whole, human brains. Taken together, the Digital Brain Bank provides cross-scale, cross-species datasets facilitating the incorporation of post-mortem data into neuroimaging studies.

Published
2022

9. A triple-network organization for the mouse brain

Author

Mandino, F., Vrooman, R.M., Foo, H.E., Yeow, L.Y., Bolton, T.A.W., Salvan, P., Teoh, C.L., Lee, C.Y., Beauchamp, A., Luo, S., Bi, R., Zhang, J., Lim, G.H.T., Low, N., Sallet, J., Gigg, J., Lerch, J.P., Mars, R.B., Olivo, M., Fu, Y., Grandjean, J., Mandino, F., Vrooman, R.M., Foo, H.E., Yeow, L.Y., Bolton, T.A.W., Salvan, P., Teoh, C.L., Lee, C.Y., Beauchamp, A., Luo, S., Bi, R., Zhang, J., Lim, G.H.T., Low, N., Sallet, J., Gigg, J., Lerch, J.P., Mars, R.B., Olivo, M., Fu, Y., and Grandjean, J.

Abstract

Contains fulltext : 239140.pdf (Publisher’s version ) (Open Access), The triple-network model of psychopathology is a framework to explain the functional and structural neuroimaging phenotypes of psychiatric and neurological disorders. It describes the interactions within and between three distributed networks: the salience, default-mode, and central executive networks. These have been associated with brain disorder traits in patients. Homologous networks have been proposed in animal models, but their integration into a triple-network organization has not yet been determined. Using resting-state datasets, we demonstrate conserved spatio-temporal properties between triple-network elements in human, macaque, and mouse. The model predictions were also shown to apply in a mouse model for depression. To validate spatial homologies, we developed a data-driven approach to convert mouse brain maps into human standard coordinates. Finally, using high-resolution viral tracers in the mouse, we refined an anatomical model for these networks and validated this using optogenetics in mice and tractography in humans. Unexpectedly, we find serotonin involvement within the salience rather than the default-mode network. Our results support the existence of a triple-network system in the mouse that shares properties with that of humans along several dimensions, including a disease condition. Finally, we demonstrate a method to humanize mouse brain networks that opens doors to fully data-driven trans-species comparisons.

Published
2022

10. Cortical morphology and white matter tractography of three phylogenetically distant primates: Evidence for a simian elaboration

Author

Roumazeilles, L., Lange, F.J., Benn, R.A., Andersson, J.L.R., Bertelsen, M.F., Manger, P.R., Flach, E., Khrapitchev, A.A., Bryant, K.L., Sallet, J., Mars, R.B., Roumazeilles, L., Lange, F.J., Benn, R.A., Andersson, J.L.R., Bertelsen, M.F., Manger, P.R., Flach, E., Khrapitchev, A.A., Bryant, K.L., Sallet, J., and Mars, R.B.

Abstract

Contains fulltext : 237107.pdf (Publisher’s version ) (Open Access), Comparative neuroimaging has been used to identify changes in white matter architecture across primate species phylogenetically close to humans, but few have compared the phylogenetically distant species. Here, we acquired postmortem diffusion imaging data from ring-tailed lemurs (Lemur catta), black-capped squirrel monkeys (Saimiri boliviensis), and rhesus macaques (Macaca mulatta). We were able to establish templates and surfaces allowing us to investigate sulcal, cortical, and white matter anatomy. The results demonstrate an expansion of the frontal projections of the superior longitudinal fasciculus complex in squirrel monkeys and rhesus macaques compared to ring-tailed lemurs, which correlates with sulcal anatomy and the lemur's smaller prefrontal granular cortex. The connectivity of the ventral pathway in the parietal region is also comparatively reduced in ring-tailed lemurs, with the posterior projections of the inferior longitudinal fasciculus not extending toward parietal cortical areas as in the other species. In the squirrel monkeys we note a very specific occipito-parietal anatomy that is apparent in their surface anatomy and the expansion of the posterior projections of the optical radiation. Our study supports the hypothesis that the connectivity of the prefrontal-parietal regions became relatively elaborated in the simian lineage after divergence from the prosimian lineage.

Published
2022

11. Modelling transcranial ultrasound neuromodulation: An energy-based multiscale framework

Author

Chen, H., Felix, C., Folloni, D., Verhagen, L., Sallet, J., Jerusalem, A., Chen, H., Felix, C., Folloni, D., Verhagen, L., Sallet, J., and Jerusalem, A.

Abstract

Contains fulltext : 283814.pdf (Publisher’s version ) (Open Access), Several animal and human studies have now established the potential of low intensity, low frequency transcranial ultrasound (TUS) for non-invasive neuromodulation. Paradoxically, the underlying mechanisms through which TUS neuromodulation operates are still unclear, and a consensus on the identification of optimal sonication parameters still remains elusive. One emerging hypothesis based on thermodynamical considerations attributes the acoustic-induced nerve activity alterations to the mechanical energy and/or entropy conversions occurring during TUS action. Here, we propose a multiscale modelling framework to examine the energy states of neuromodulation under TUS. First, macroscopic tissue-level acoustic simulations of the sonication of a whole monkey brain are conducted under different sonication protocols. For each one of them, mechanical loading conditions of the received waves in the anterior cingulate cortex region are recorded and exported into a microscopic cell-level 3D viscoelastic finite element model of a neuronal axon embedded in extracellular medium. Pulse-averaged elastically stored and viscously dissipated energy rate densities during axon deformation are finally computed under different sonication incident angles and are mapped against distinct combinations of sonication parameters of the TUS. The proposed multiscale framework allows for the analysis of vibrational patterns of the axons and its comparison against the spectrograms of stimulating ultrasound. The results are in agreement with literature data on neuromodulation, demonstrating the potential of this framework to identify optimised acoustic parameters in TUS neuromodulation. The proposed approach is finally discussed in the context of multiphysics energetic considerations, argued here to be a promising avenue towards a scalable framework for TUS in silico predictions.

Published
2022

12. Intra-Areal Visual Topography in Primate Brains Mapped with Probabilistic Tractography of Diffusion-Weighted Imaging

Author

Tang-Wright, K., Smith, J. E.T., Bridge, H., Miller, K. L., Dyrby, T. B., Ahmed, B., Reislev, N. L., Sallet, J., Parker, A. J., Krug, K., Tang-Wright, K., Smith, J. E.T., Bridge, H., Miller, K. L., Dyrby, T. B., Ahmed, B., Reislev, N. L., Sallet, J., Parker, A. J., and Krug, K.

Abstract

Noninvasive diffusion-weighted magnetic resonance imaging (dMRI) can be used to map the neural connectivity between distinct areas in the intact brain, but the standard resolution achieved fundamentally limits the sensitivity of such maps. We investigated the sensitivity and specificity of high-resolution postmortem dMRI and probabilistic tractography in rhesus macaque brains to produce retinotopic maps of the lateral geniculate nucleus (LGN) and extrastriate cortical visual area V5/MT based on their topographic connections with the previously established functional retinotopic map of primary visual cortex (V1). We also replicated the differential connectivity of magnocellular and parvocellular LGN compartments with V1 across visual field positions. Predicted topographic maps based on dMRI data largely matched the established retinotopy of both LGN and V5/MT. Furthermore, tractography based on in vivo dMRI data from the same macaque brains acquired at standard field strength (3T) yielded comparable topographic maps in many cases. We conclude that tractography based on dMRI is sensitive enough to reveal the intrinsic organization of ordered connections between topographically organized neural structures and their resultant functional organization.

Published
2022

13. Non-invasive transcranial ultrasound stimulation for neuromodulation

Author

Darmani, G., primary, Bergmann, T.O., additional, Butts Pauly, K., additional, Caskey, C.F., additional, de Lecea, L., additional, Fomenko, A., additional, Fouragnan, E., additional, Legon, W., additional, Murphy, K.R., additional, Nandi, T., additional, Phipps, M.A., additional, Pinton, G., additional, Ramezanpour, H., additional, Sallet, J., additional, Yaakub, S.N., additional, Yoo, S.S., additional, and Chen, R., additional

Published
2022
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18. What is special about the human arcuate fasciculus? Lateralization, projections, and expansion

Author

Eichert, N., Verhagen, L., Folloni, D., Jbabdi, S., Khrapitchev, A.A., Sibson, N.R., Mantini, D., Sallet, J., and Mars, R.B.

Subjects
Brain Mapping, Action, intention, and motor control, Diffusion-weighted MRI, Brain, Comparative neuroanatomy, Article, Cortical tract representation, Diffusion Tensor Imaging, Nerve Fibers, Arcuate fasciculus, Neural Pathways, Animals, Humans, Macaca, Neuroecology, Nerve Net, Language
Abstract

Contains fulltext : 215853.pdf (Publisher’s version ) (Open Access) Evolutionary adaptations of the human brain are the basis for our unique abilities such as language. An expansion of the arcuate fasciculus (AF), the dorsal language tract, in the human lineage involving left lateralization is considered canonical, but this hypothesis has not been tested in relation to other architectural adaptations in the human brain. Using diffusion-weighted MRI, we examined AF in the human and macaque and quantified species differences in white matter architecture and surface representations. To compare surface results in the two species, we transformed macaque representations to human space using a landmark-based monkey-to-human cortical expansion model. We found that the human dorsal AF, but not the ventral inferior fronto-occipital fasciculus (IFO), is left-lateralized. In the monkey AF is not lateralized. Moreover, compared to the macaque, human AF is relatively increased with respect to IFO. A comparison of human and transformed macaque surface representations suggests that cortical expansion alone cannot account for the species differences in the surface representation of AF. Our results show that the human AF has undergone critical anatomical modifications in comparison with the macaque AF. More generally, this work demonstrates that studies on the human brain specializations underlying the language connectome can benefit from current methodological advances in comparative neuroanatomy. 9 p.

Published
2019

20. Ultrasound modulation of macaque prefrontal cortex selectively alters credit assignment-related activity and behavior

Author

Folloni, D., Fouragnan, E.F., Wittmann, M.K., Roumazeilles, L., Tankelevitch, L., Verhagen, L., Attali, D., Aubry, J.F., Sallet, J., Rushworth, M.F.S., Folloni, D., Fouragnan, E.F., Wittmann, M.K., Roumazeilles, L., Tankelevitch, L., Verhagen, L., Attali, D., Aubry, J.F., Sallet, J., and Rushworth, M.F.S.

Abstract

Contains fulltext : 242467.pdf (Publisher’s version ) (Open Access), Credit assignment is the association of specific instances of reward to the specific events, such as a particular choice, that caused them. Without credit assignment, choice values reflect an approximate estimate of how good the environment was when the choice was made - the global reward state - rather than exactly which outcome the choice caused. Combined transcranial ultrasound stimulation (TUS) and functional magnetic resonance imaging in macaques demonstrate credit assignment–related activity in prefrontal area 47/12o, and when this signal was disrupted with TUS, choice value representations across the brain were impaired. As a consequence, behavior was no longer guided by choice value, and decision-making was poorer. By contrast, global reward state-related activity in the adjacent anterior insula remained intact and determined decision-making after prefrontal disruption.

Published
2021

21. Comparative connectomics of the primate social brain

Author

Yokoyama, C., Autio, J.A., Ikeda, T., Sallet, J., Mars, R.B., Essen, D.C. van, Glasser, M.F., Sadato, N., Hayashi, T., Yokoyama, C., Autio, J.A., Ikeda, T., Sallet, J., Mars, R.B., Essen, D.C. van, Glasser, M.F., Sadato, N., and Hayashi, T.

Abstract

Contains fulltext : 239571.pdf (Publisher’s version ) (Open Access), Social interaction is thought to provide a selection pressure for human intelligence, yet little is known about its neurobiological basis and evolution throughout the primate lineage. Recent advances in neuroimaging have enabled whole brain investigation of brain structure, function, and connectivity in humans and non-human primates (NHPs), leading to a nascent field of comparative connectomics. However, linking social behavior to brain organization across the primates remains challenging. Here, we review the current understanding of the macroscale neural mechanisms of social behaviors from the viewpoint of system neuroscience. We first demonstrate an association between the number of cortical neurons and the size of social groups across primates, suggesting a link between neural information-processing capacity and social capabilities. Moreover, by capitalizing on recent advances in species-harmonized functional MRI, we demonstrate that portions of the mirror neuron system and default-mode networks, which are thought to be important for representation of the other's actions and sense of self, respectively, exhibit similarities in functional organization in macaque monkeys and humans, suggesting possible homologies. With respect to these two networks, we describe recent developments in the neurobiology of social perception, joint attention, personality and social complexity. Together, the Human Connectome Project (HCP)-style comparative neuroimaging, hyperscanning, behavioral, and other multi-modal investigations are expected to yield important insights into the evolutionary foundations of human social behavior.

Published
2021

22. Toward a hierarchical model of social cognition: A neuroimaging meta-analysis and integrative review of empathy and theory of mind

Author

Schurz, M., Radua, J., Tholen, M.G., Maliske, L., Margulies, D.S., Mars, R.B., Sallet, J., Kanske, P., Schurz, M., Radua, J., Tholen, M.G., Maliske, L., Margulies, D.S., Mars, R.B., Sallet, J., and Kanske, P.

Abstract

Contains fulltext : 226714.pdf (Publisher’s version ) (Open Access), Along with the increased interest in and volume of social cognition research, there has been higher awareness of a lack of agreement on the concepts and taxonomy used to study social processes. Two central concepts in the field, empathy and Theory of Mind (ToM), have been identified as overlapping umbrella terms for different processes of limited convergence. Here, we review and integrate evidence of brain activation, brain organization, and behavior into a coherent model of social-cognitive processes. We start with a meta-analytic clustering of neuroimaging data across different social-cognitive tasks. Results show that understanding others' mental states can be described by a multilevel model of hierarchical structure, similar to models in intelligence and personality research. A higher level describes more broad and abstract classes of functioning, whereas a lower one explains how functions are applied to concrete contexts given by particular stimulus and task formats. Specifically, the higher level of our model suggests 3 groups of neurocognitive processes: (a) predominantly cognitive processes, which are engaged when mentalizing requires self-generated cognition decoupled from the physical world; (b) more affective processes, which are engaged when we witness emotions in others based on shared emotional, motor, and somatosensory representations; (c) combined processes, which engage cognitive and affective functions in parallel. We discuss how these processes are explained by an underlying principal gradient of structural brain organization. Finally, we validate the model by a review of empathy and ToM task interrelations found in behavioral studies.

Published
2021

23. Imaging evolution of the primate brain: The next frontier?

Author

Friedrich, P., Forkel, S.J., Amiez, C., Balsters, J.H., Coulon, O., Fan, L., Goulas, A., Hadj-Bouziane, F., Hecht, E.E., Heuer, K., Jiang, T., Latzman, R.D., Liu, X., Loh, K.K., Patil, K.R., Lopez-Persem, A., Procyk, E., Sallet, J., Toro, R., Vickery, S., Weis, S., Wilson, C.R.E., Xu, T., Zerbi, V., Eickoff, S.B., Margulies, D.S., Mars, R.B., Thiebaut de Schotten, M., Friedrich, P., Forkel, S.J., Amiez, C., Balsters, J.H., Coulon, O., Fan, L., Goulas, A., Hadj-Bouziane, F., Hecht, E.E., Heuer, K., Jiang, T., Latzman, R.D., Liu, X., Loh, K.K., Patil, K.R., Lopez-Persem, A., Procyk, E., Sallet, J., Toro, R., Vickery, S., Weis, S., Wilson, C.R.E., Xu, T., Zerbi, V., Eickoff, S.B., Margulies, D.S., Mars, R.B., and Thiebaut de Schotten, M.

Abstract

Contains fulltext : 228176.pdf (publisher's version ) (Open Access), Evolution, as we currently understand it, strikes a delicate balance between animals' ancestral history and adaptations to their current niche. Similarities between species are generally considered inherited from a common ancestor whereas observed differences are considered as more recent evolution. Hence comparing species can provide insights into the evolutionary history. Comparative neuroimaging has recently emerged as a novel subdiscipline, which uses magnetic resonance imaging (MRI) to identify similarities and differences in brain structure and function across species. Whereas invasive histological and molecular techniques are superior in spatial resolution, they are laborious, post-mortem, and oftentimes limited to specific species. Neuroimaging, by comparison, has the advantages of being applicable across species and allows for fast, whole-brain, repeatable, and multi-modal measurements of the structure and function in living brains and post-mortem tissue. In this review, we summarise the current state of the art in comparative anatomy and function of the brain and gather together the main scientific questions to be explored in the future of the fascinating new field of brain evolution derived from comparative neuroimaging.

Published
2021

24. Variability in brain structure and function reflects lack of peer support

Author

Schurz, M., Uddin, L.Q., Kanske, P., Lamm, C., Sallet, J., Bernhardt, B.C., Mars, R.B., Bzdok, D., Schurz, M., Uddin, L.Q., Kanske, P., Lamm, C., Sallet, J., Bernhardt, B.C., Mars, R.B., and Bzdok, D.

Abstract

Contains fulltext : 233698.pdf (Publisher’s version ) (Open Access), Humans are a highly social species. Complex interactions for mutual support range from helping neighbors to building social welfare institutions. During times of distress or crisis, sharing life experiences within one's social circle is critical for well-being. By translating pattern-learning algorithms to the UK Biobank imaging-genetics cohort (n = ~40 000 participants), we have delineated manifestations of regular social support in multimodal whole-brain measurements. In structural brain variation, we identified characteristic volumetric signatures in the salience and limbic networks for high- versus low-social support individuals. In patterns derived from functional coupling, we also located interindividual differences in social support in action-perception circuits related to binding sensory cues and initiating behavioral responses. In line with our demographic profiling analysis, the uncovered neural substrates have potential implications for loneliness, substance misuse, and resilience to stress.

Published
2021

25. Social prediction modulates activity of macaque superior temporal cortex

Author

Roumazeilles, L., Schurz, M., Lojkiewiez, M., Verhagen, L., Schüffelgen, U., Marche, K., Mahmoodi, A., Emberton, A., Simpson, K., Joly, O., Khamassi, M., Rushworth, M.F.S., Mars, R.B., Sallet, J., Roumazeilles, L., Schurz, M., Lojkiewiez, M., Verhagen, L., Schüffelgen, U., Marche, K., Mahmoodi, A., Emberton, A., Simpson, K., Joly, O., Khamassi, M., Rushworth, M.F.S., Mars, R.B., and Sallet, J.

Abstract

Contains fulltext : 237221.pdf (Publisher’s version ) (Open Access), The macaque middle superior temporal sulcus shares functional properties with the human temporoparietal junction supporting mentalizing. The ability to attribute thoughts to others, also called theory of mind (TOM), has been extensively studied in humans; however, its evolutionary origins have been challenged. Computationally, the basis of TOM has been interpreted within the predictive coding framework and associated with activity in the temporoparietal junction (TPJ). Here, we revealed, using a nonlinguistic task and functional magnetic resonance imaging, that activity in a region of the macaque middle superior temporal cortex was specifically modulated by the predictability of social situations. As in human TPJ, this region could be distinguished from other temporal regions involved in face processing. Our result suggests the existence of a precursor for the TOM ability in the last common ancestor of human and Old World monkeys.

Published
2021

26. A triple-network organization for the mouse brain

Author

Mandino, F., Vrooman, R.M., Foo, H.E., Yeow, L.Y., Bolton, T.A.W., Salvan, P., Teoh, C.L., Lee, C.Y., Beauchamp, A., Luo, S., Bi, R., Zhang, J., Lim, G.H.T., Low, N., Sallet, J., Gigg, J., Lerch, J.P., Mars, R.B., Olivo, M., Fu, Y., Grandjean, J., Mandino, F., Vrooman, R.M., Foo, H.E., Yeow, L.Y., Bolton, T.A.W., Salvan, P., Teoh, C.L., Lee, C.Y., Beauchamp, A., Luo, S., Bi, R., Zhang, J., Lim, G.H.T., Low, N., Sallet, J., Gigg, J., Lerch, J.P., Mars, R.B., Olivo, M., Fu, Y., and Grandjean, J.

Abstract

14 oktober 2021, Item does not contain fulltext, The triple-network model of psychopathology is a framework to explain the functional and structural neuroimaging phenotypes of psychiatric and neurological disorders. It describes the interactions within and between three distributed networks: the salience, default-mode, and central executive networks. These have been associated with brain disorder traits in patients. Homologous networks have been proposed in animal models, but their integration into a triple-network organization has not yet been determined. Using resting-state datasets, we demonstrate conserved spatio-temporal properties between triple-network elements in human, macaque, and mouse. The model predictions were also shown to apply in a mouse model for depression. To validate spatial homologies, we developed a data-driven approach to convert mouse brain maps into human standard coordinates. Finally, using high-resolution viral tracers in the mouse, we refined an anatomical model for these networks and validated this using optogenetics in mice and tractography in humans. Unexpectedly, we find serotonin involvement within the salience rather than the default-mode network. Our results support the existence of a triple-network system in the mouse that shares properties with that of humans along several dimensions, including a disease condition. Finally, we demonstrate a method to humanize mouse brain networks that opens doors to fully data-driven trans-species comparisons.

Published
2021

27. Cortical morphology and white matter tractography of three phylogenetically distant primates: Evidence for a simian elaboration

Author

Roumazeilles, L., Lange, F.J., Benn, R.A., Andersson, J.L.R., Bertelsen, M.F., Manger, P.R., Flach, E., Khrapitchev, A.A., Bryant, K.L., Sallet, J., Mars, R.B., Roumazeilles, L., Lange, F.J., Benn, R.A., Andersson, J.L.R., Bertelsen, M.F., Manger, P.R., Flach, E., Khrapitchev, A.A., Bryant, K.L., Sallet, J., and Mars, R.B.

Abstract

13 september 2021, Contains fulltext : 237107.pdf (Publisher’s version ) (Open Access), Comparative neuroimaging has been used to identify changes in white matter architecture across primate species phylogenetically close to humans, but few have compared the phylogenetically distant species. Here, we acquired postmortem diffusion imaging data from ring-tailed lemurs (Lemur catta), black-capped squirrel monkeys (Saimiri boliviensis), and rhesus macaques (Macaca mulatta). We were able to establish templates and surfaces allowing us to investigate sulcal, cortical, and white matter anatomy. The results demonstrate an expansion of the frontal projections of the superior longitudinal fasciculus complex in squirrel monkeys and rhesus macaques compared to ring-tailed lemurs, which correlates with sulcal anatomy and the lemur's smaller prefrontal granular cortex. The connectivity of the ventral pathway in the parietal region is also comparatively reduced in ring-tailed lemurs, with the posterior projections of the inferior longitudinal fasciculus not extending toward parietal cortical areas as in the other species. In the squirrel monkeys we note a very specific occipito-parietal anatomy that is apparent in their surface anatomy and the expansion of the posterior projections of the optical radiation. Our study supports the hypothesis that the connectivity of the prefrontal-parietal regions became relatively elaborated in the simian lineage after divergence from the prosimian lineage.

Published
2021

28. Activation and disruption of a neural mechanism for novel choice in monkeys

Author

Bongioanni, A., Folloni, D., Verhagen, L., Sallet, J., Klein-Flügge, M.C., Rushworth, M.F.S., Bongioanni, A., Folloni, D., Verhagen, L., Sallet, J., Klein-Flügge, M.C., and Rushworth, M.F.S.

Abstract

Contains fulltext : 228321.pdf (publisher's version ) (Closed access), Neural mechanisms that mediate the ability to make value-guided decisions have received substantial attention in humans and animals. Experiments in animals typically involve long training periods. By contrast, choices in the real world often need to be made between new options spontaneously. It is therefore possible that the neural mechanisms targeted in animal studies differ from those required for new decisions, which are typical of human imaging studies. Here we show that the primate medial frontal cortex (MFC) is involved in making new inferential choices when the options have not been previously experienced. Macaques spontaneously inferred the values of new options via similarities with the component parts of previously encountered options. Functional magnetic resonance imaging (fMRI) suggested that this ability was mediated by the MFC, which is rarely investigated in monkeys; MFC activity reflected different processes of comparison for unfamiliar and familiar options. Multidimensional representations of options in the MFC used a coding scheme resembling that of grid cells, which is well known in spatial navigation, to integrate dimensions in this non-physical space during novel decision-making. By contrast, the orbitofrontal cortex held specific object-based value representations. In addition, minimally invasive ultrasonic disruption of MFC, but not adjacent tissue, altered the estimation of novel choice values.

Published
2021

29. Diffusion MRI data, sulcal anatomy, and tractography for eight species from the Primate Brain Bank

Author

Bryant, K.L., Ardesch, D.J., Roumazeilles, L., Scholtens, L.H., Khrapitchev, A.A., Tendler, B.C., Wu, W., Miller, K.L., Sallet, J., Heuvel, M.P. van den, Mars, R.B., Bryant, K.L., Ardesch, D.J., Roumazeilles, L., Scholtens, L.H., Khrapitchev, A.A., Tendler, B.C., Wu, W., Miller, K.L., Sallet, J., Heuvel, M.P. van den, and Mars, R.B.

Abstract

Contains fulltext : 235111.pdf (Publisher’s version ) (Open Access), Large-scale comparative neuroscience requires data from many species and, ideally, at multiple levels of description. Here, we contribute to this endeavor by presenting diffusion and structural MRI data from eight primate species that have not or rarely been described in the literature. The selected samples from the Primate Brain Bank cover a prosimian, New and Old World monkeys, and a great ape. We present preliminary labelling of the cortical sulci and tractography of the optic radiation, dorsal part of the cingulum bundle, and dorsal parietal–frontal and ventral temporal-frontal longitudinal white matter tracts. Both dorsal and ventral association fiber systems could be observed in all samples, with the dorsal tracts occupying much less relative volume in the prosimian than in other species. We discuss the results in the context of known primate specializations and present hypotheses for further research. All data and results presented here are available online as a resource for the scientific community.

Published
2021

32. Toward a hierarchical model of social cognition: A neuroimaging meta-analysis and integrative review of empathy and theory of mind

Author

Schurz, M, Radua, J, Tholen, MG, Maliske, L, Margulies, DS, Mars, RB, Sallet, J, Kanske, P, Wellcome Trust Centre for Integrative Neuroimaging (WIN - FMRIB), and University of Oxford [Oxford]

Subjects
Social Cognition, media_common.quotation_subject, Theory of Mind, Neuroimaging, 050109 social psychology, Empathy, Mentalization, History and Philosophy of Science, Social cognition, Theory of mind, Cluster Analysis, Humans, 0501 psychology and cognitive sciences, ComputingMilieux_MISCELLANEOUS, General Psychology, Mirror neuron, media_common, Action, intention, and motor control, [SCCO.NEUR]Cognitive science/Neuroscience, 05 social sciences, Multilevel model, Cognition, Models, Theoretical, Psychology, Neurocognitive, Cognitive psychology
Abstract

Contains fulltext : 226714.pdf (Publisher’s version ) (Open Access) Along with the increased interest in and volume of social cognition research, there has been higher awareness of a lack of agreement on the concepts and taxonomy used to study social processes. Two central concepts in the field, empathy and Theory of Mind (ToM), have been identified as overlapping umbrella terms for different processes of limited convergence. Here, we review and integrate evidence of brain activation, brain organization, and behavior into a coherent model of social-cognitive processes. We start with a meta-analytic clustering of neuroimaging data across different social-cognitive tasks. Results show that understanding others' mental states can be described by a multilevel model of hierarchical structure, similar to models in intelligence and personality research. A higher level describes more broad and abstract classes of functioning, whereas a lower one explains how functions are applied to concrete contexts given by particular stimulus and task formats. Specifically, the higher level of our model suggests 3 groups of neurocognitive processes: (a) predominantly cognitive processes, which are engaged when mentalizing requires self-generated cognition decoupled from the physical world; (b) more affective processes, which are engaged when we witness emotions in others based on shared emotional, motor, and somatosensory representations; (c) combined processes, which engage cognitive and affective functions in parallel. We discuss how these processes are explained by an underlying principal gradient of structural brain organization. Finally, we validate the model by a review of empathy and ToM task interrelations found in behavioral studies. 35 p.

Published
2020
Full Text
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33. Estimating intra-axonal axial diffusivity with diffusion MRI in the presence of fibre orientation dispersion

Author

Howard, A.F.D., Khrapitchev, A.A., Mollink, J., Mars, R.B., Sibson, N.R., Sallet, J., Jbabdi, S., and Miller, K.L.

Subjects
nervous system, Quantitative Biology::Neurons and Cognition, Action, intention, and motor control, Physics::Medical Physics
Abstract

Item does not contain fulltext Intra-axonal axial diffusivity could be interesting biomarker of disease, yet it is often assumed constant across the white matter. Furthermore, when intra-axonal diffusivity is estimated, few models account for fibre orientation dispersion which (when not explicitly modelled) will greatly affect the estimates of axial diffusion. Here we combine the stick model of intra-axonal diffusion with a simple model of fibre dispersion to simultaneously estimate intra-axonal axial diffusivity and fibre dispersion on a voxel-wise basis in high b-value data. Our results demonstrate considerable variability in the intra-axonal axial diffusivity across the white matter. 28th Annual Meeting of the International Society for Magnetic Resonance in Medicine (Paris, France, 8-13 August)

Published
2020

34. XTRACT - Standardised protocols for automated tractography in the human and macaque brain

Author

Warrington, S., Bryant, K.L., Khrapitchev, A.A., Sallet, J., Charquero-Ballester, M., Douaud, G., Jbabdi, S., Mars, R.B., Sotiropoulos, S.N., Warrington, S., Bryant, K.L., Khrapitchev, A.A., Sallet, J., Charquero-Ballester, M., Douaud, G., Jbabdi, S., Mars, R.B., and Sotiropoulos, S.N.

Abstract

Contains fulltext : 219008.pdf (publisher's version ) (Open Access), We present a new software package with a library of standardised tractography protocols devised for the robust automated extraction of white matter tracts both in the human and the macaque brain. Using in vivo data from the Human Connectome Project (HCP) and the UK Biobank and ex vivo data for the macaque brain datasets, we obtain white matter atlases, as well as atlases for tract endpoints on the white-grey matter boundary, for both species. We illustrate that our protocols are robust against data quality, generalisable across two species and reflect the known anatomy. We further demonstrate that they capture inter-subject variability by preserving tract lateralisation in humans and tract similarities stemming from twinship in the HCP cohort. Our results demonstrate that the presented toolbox will be useful for generating imaging-derived features in large cohorts, and in facilitating comparative neuroanatomy studies. The software, tractography protocols, and atlases are publicly released through FSL, allowing users to define their own tractography protocols in a standardised manner, further contributing to open science.

Published
2020

35. Multiple systems in macaques for tracking prediction errors and other types of surprise

Author

Grohn, J., Schüffelgen, U., Neubert, F.X., Bongioanni, A., Verhagen, L., Sallet, J., Kolling, N., Rushworth, M.F.S., Grohn, J., Schüffelgen, U., Neubert, F.X., Bongioanni, A., Verhagen, L., Sallet, J., Kolling, N., and Rushworth, M.F.S.

Abstract

Contains fulltext : 226669.pdf (publisher's version ) (Open Access), Animals learn from the past to make predictions. These predictions are adjusted after prediction errors, i.e., after surprising events. Generally, most reward prediction errors models learn the average expected amount of reward. However, here we demonstrate the existence of distinct mechanisms for detecting other types of surprising events. Six macaques learned to respond to visual stimuli to receive varying amounts of juice rewards. Most trials ended with the delivery of either 1 or 3 juice drops so that animals learned to expect 2 juice drops on average even though instances of precisely 2 drops were rare. To encourage learning, we also included sessions during which the ratio between 1 and 3 drops changed. Additionally, in all sessions, the stimulus sometimes appeared in an unexpected location. Thus, 3 types of surprising events could occur: reward amount surprise (i.e., a scalar reward prediction error), rare reward surprise, and visuospatial surprise. Importantly, we can dissociate scalar reward prediction errors - rewards that deviated from the average reward amount expected - and rare reward events - rewards that accorded with the average reward expectation but that rarely occurred. We linked each type of surprise to a distinct pattern of neural activity using functional magnetic resonance imaging. Activity in the vicinity of the dopaminergic midbrain only reflected surprise about the amount of reward. Lateral prefrontal cortex had a more general role in detecting surprising events. Posterior lateral orbitofrontal cortex specifically detected rare reward events regardless of whether they followed average reward amount expectations, but only in learnable reward environments.

Published
2020

36. A basal forebrain-cingulate circuit in macaques decides it Is time to act

Author

Khalighinejad, N., Bongioanni, A., Verhagen, L., Folloni, D., Attali, D., Aubry, J.F., Sallet, J., Rushworth, M.F.S., Khalighinejad, N., Bongioanni, A., Verhagen, L., Folloni, D., Attali, D., Aubry, J.F., Sallet, J., and Rushworth, M.F.S.

Abstract

Contains fulltext : 216113.pdf (publisher's version ) (Open Access), The medial frontal cortex has been linked to voluntary action, but an explanation of why decisions to act emerge at particular points in time has been lacking. We show that, in macaques, decisions about whether and when to act are predicted by a set of features defining the animal’s current and past context; for example, respectively, cues indicating the current average rate of reward and recent previous voluntary action decisions. We show that activity in two brain areas—the anterior cingulate cortex and basal forebrain—tracks these contextual factors and mediates their effects on behavior in distinct ways. We use focused transcranial ultrasound to selectively and effectively stimulate deep in the brain, even as deep as the basal forebrain, and demonstrate that alteration of activity in the two areas changes decisions about when to act.

Published
2020

37. Behavioral flexibility is associated with changes in structure and function distributed across a frontal cortical network in macaques

Author

Sallet, J., Noonan, M.P., Thomas, A.G., O'Reilly, J.X., Anderson, J.L.R., Papageorgiou, G.K., Neubert, F.X., Ahmed, B., Smith, J., Bell, A.H., Buckley, M.J., Roumazeilles, L., Cuell, S., Walton, M.E., Krug, K., Mars, R.B., Rushworth, M.F.S., Sallet, J., Noonan, M.P., Thomas, A.G., O'Reilly, J.X., Anderson, J.L.R., Papageorgiou, G.K., Neubert, F.X., Ahmed, B., Smith, J., Bell, A.H., Buckley, M.J., Roumazeilles, L., Cuell, S., Walton, M.E., Krug, K., Mars, R.B., and Rushworth, M.F.S.

Abstract

Contains fulltext : 219013.pdf (publisher's version ) (Open Access), One of the most influential accounts of central orbitofrontal cortex - that it mediates behavioral flexibility - has been challenged by the finding that discrimination reversal in macaques, the classic test of behavioral flexibility, is unaffected when lesions are made by excitotoxin injection rather than aspiration. This suggests that the critical brain circuit mediating behavioral flexibility in reversal tasks lies beyond the central orbitofrontal cortex. To determine its identity, a group of nine macaques were taught discrimination reversal learning tasks, and its impact on gray matter was measured. Magnetic resonance imaging scans were taken before and after learning and compared with scans from two control groups, each comprising 10 animals. One control group learned discrimination tasks that were similar but lacked any reversal component, and the other control group engaged in no learning. Gray matter changes were prominent in posterior orbitofrontal cortex/anterior insula but were also found in three other frontal cortical regions: lateral orbitofrontal cortex (orbital part of area 12 [12o]), cingulate cortex, and lateral prefrontal cortex. In a second analysis, neural activity in posterior orbitofrontal cortex/anterior insula was measured at rest, and its pattern of coupling with the other frontal cortical regions was assessed. Activity coupling increased significantly in the reversal learning group in comparison with controls. In a final set of experiments, we used similar structural imaging procedures and analyses to demonstrate that aspiration lesion of central orbitofrontal cortex, of the type known to affect discrimination learning, affected structure and activity in the same frontal cortical circuit. The results identify a distributed frontal cortical circuit associated with behavioral flexibility.

Published
2020

38. Primate homologs of mouse cortico-striatal circuits

Author

Balsters, J.H., Zerbi, V., Sallet, J., Wenderoth, N., Mars, R.B., Balsters, J.H., Zerbi, V., Sallet, J., Wenderoth, N., and Mars, R.B.

Abstract

Contains fulltext : 217753.pdf (publisher's version ) (Open Access), With the increasing necessity of animal models in biomedical research, there is a vital need to harmonise findings across species by establishing similarities and differences in rodent and primate neuroanatomy. Using connectivity fingerprint matching, we compared cortico-striatal circuits across humans, non-human primates, and mice using resting-state fMRI data in all species. Our results suggest that the connectivity patterns for the nucleus accumbens and cortico-striatal motor circuits (posterior/lateral putamen) were conserved across species, making them reliable targets for cross-species comparisons. However, a large number of human and macaque striatal voxels were not matched to any mouse cortico-striatal circuit (mouse->human: 85% unassigned; mouse->macaque 69% unassigned; macaque->human; 31% unassigned). These unassigned voxels were localised to the caudate nucleus and anterior putamen, overlapping with executive function and social/language regions of the striatum and connected to prefrontal-projecting cerebellar lobules and anterior prefrontal cortex, forming circuits that seem to be unique for non-human primates and humans.

Published
2020

39. Longitudinal connections and the organization of the temporal cortex in macaques, great apes, and humans

Author

Roumazeilles, L., Eichert, N., Bryant, K.L., Folloni, D., Sallet, J., Vijayakumar, S., Foxley, S., Tendler, B.C., Jbabdi, S., Reveley, C., Verhagen, L., Dershowitz, L.B., Guthrie, M.J., Flach, E., Miller, K.L., Mars, R.B., Roumazeilles, L., Eichert, N., Bryant, K.L., Folloni, D., Sallet, J., Vijayakumar, S., Foxley, S., Tendler, B.C., Jbabdi, S., Reveley, C., Verhagen, L., Dershowitz, L.B., Guthrie, M.J., Flach, E., Miller, K.L., and Mars, R.B.

Abstract

Contains fulltext : 221398.pdf (publisher's version ) (Open Access), The temporal association cortex is considered a primate specialization and is involved in complex behaviors, with some, such as language, particularly characteristic of humans. The emergence of these behaviors has been linked to major differences in temporal lobe white matter in humans compared with monkeys. It is unknown, however, how the organization of the temporal lobe differs across several anthropoid primates. Therefore, we systematically compared the organization of the major temporal lobe white matter tracts in the human, gorilla, and chimpanzee great apes and in the macaque monkey. We show that humans and great apes, in particular the chimpanzee, exhibit an expanded and more complex occipital-temporal white matter system; additionally, in humans, the invasion of dorsal tracts into the temporal lobe provides a further specialization. We demonstrate the reorganization of different tracts along the primate evolutionary tree, including distinctive connectivity of human temporal gray matter.

Published
2020

40. The structural and functional brain networks that support human social networks

Author

Noonan, M.P., Mars, R.B., Sallet, J., Dunbar, R.I.M., and Fellows, L.K.

Subjects
Male, MELODIC, Multivariate Exploratory Linear Optimized Decomposition into Independent Components, SM, sensory motor, ROI, region of interest, UF, Uncinate Fasciculus, OR, Optic Radiations, DMRI, diffusion magnetic resonance imaging, Social Networking, Neural Pathways, dlPFC, dorsolateral prefrontal cortex, EPI, echo planer imaging, FA, fractional anisotropy, ILF, inferior longitudinal fasciculus, Gray Matter, rsfMRI, resting-state functional magnetic resonance imaging, ACC, anterior cingulate cortex, Brain, RSN, resting-state networks, Social network size, Organ Size, Middle Aged, Magnetic Resonance Imaging, White Matter, ICA, independent component analysis, IFOF, Inferior Fronto-occipital Fasciculus, MLF, middle longitudinal fasciculus, Female, PreC, precuneus, MNI, Montreal Neurological Institute, SNS, social network size, Rest, CC, corpus callosum, vmPFC, ventromedial prefrontal cortex, Article, AF, arcuate fasciculus, DAS, left dorsal attention stream (r=right, l=left), Anterior cingulate cortex, CB, cingulum bundle, FWHM, full width half maximum, CSF, cerebral spinal fluid, Humans, WM, white matter, Social Behavior, FNIRT, FMRIBs non-linear registration tool, Action, intention, and motor control, Structural connectivity, Fx, Fornix, Perception, Action and Control [DI-BCB_DCC_Theme 2], GLM, General linear model, Diffusion weighted imaging, PCC, posterior cingulate cortex, TBSS, tract based spatial statistics, VBM, voxel based morphometry, ATC, anterior temporal complex, BET, brain extraction tool, EmC, Extreme Capsule, Default mode network, GM, gray matter, DMN, default mode network (a=anterior, p=posterior)
Abstract

Highlights • Fronto-temporal white matter tracts relate to social network size. • Specific limbic and temporal regions are larger in people with larger social networks. • Functional coupling of the default mode network varies with social network size., Social skills rely on a specific set of cognitive processes, raising the possibility that individual differences in social networks are related to differences in specific brain structural and functional networks. Here, we tested this hypothesis with multimodality neuroimaging. With diffusion MRI (DMRI), we showed that differences in structural integrity of particular white matter (WM) tracts, including cingulum bundle, extreme capsule and arcuate fasciculus were associated with an individual’s social network size (SNS). A voxel-based morphology analysis demonstrated correlations between gray matter (GM) volume and SNS in limbic and temporal lobe regions. These structural changes co-occured with functional network differences. As a function of SNS, dorsomedial and dorsolateral prefrontal cortex showed altered resting-state functional connectivity with the default mode network (DMN). Finally, we integrated these three complementary methods, interrogating the relationship between social GM clusters and specific WM and resting-state networks (RSNs). Probabilistic tractography seeded in these GM nodes utilized the SNS-related WM pathways. Further, the spatial and functional overlap between the social GM clusters and the DMN was significantly closer than other control RSNs. These integrative analyses provide convergent evidence of the role of specific circuits in SNS, likely supporting the adaptive behavior necessary for success in extensive social environments.

Published
2018

42. XTRACT - Standardised protocols for automated tractography and connectivity blueprints in the human and macaque brain

Author

Warrington, S, Bryant, KL, Khrapitchev, AA, Sallet, J, Charquero-Ballester, M, Douaud, G, Jbabdi, S, Mars, RB, and Sotiropoulos, SN

Abstract

We present a new toolbox and library of standardised tractography protocols devised for the robust automated extraction of white matter tracts both in the human and the macaque brain. Using in vivo data from the Human Connectome Project (HCP) and the UK Biobank and ex vivo data for the macaque brain datasets, we obtain white matter atlases, as well as atlases for tract endpoints on the white-grey matter boundary, for both species. We illustrate that our protocols are robust against data quality, generalisable across two species and reflect the known anatomy. We further demonstrate that they capture inter-subject variability by preserving tract lateralisation in humans and tract similarities stemming from twinship in the HCP cohort. Our results demonstrate that the presented toolbox will be useful for generating imaging-derived features in large cohorts, and in facilitating comparative neuroanatomy studies. The software, tractography protocols, and atlases are publicly released through FSL, allowing users to define their own tractography protocols in a standardised manner, further contributing to open science.

Published
2019
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44. The human ventromedial prefrontal cortex: Sulcal morphology and its influence on its functional organization

Author

Lopez-Persem, A., Verhagen, L., Amiez, C., Petrides, M., and Sallet, J.

Subjects
stomatognathic diseases, nervous system, Action, intention, and motor control
Abstract

Contains fulltext : 212292pub.pdf (Publisher’s version ) (Open Access) The ventromedial prefrontal cortex (vmPFC), which comprises several distinct cytoarchitectonic areas, is a key brain region supporting decision-making processes, and it has been shown to be one of the main hubs of the Default Mode Network, a network classically activated during resting state. We here examined the interindividual variability in the vmPFC sulcal morphology in 57 humans (37 females) and demonstrated that the presence/absence of the inferior rostral sulcus and the subgenual intralimbic sulcus influences significantly the sulcal organization of this region. Furthermore, the sulcal organization influences the location of the vmPFC peak of the Default Mode Network, demonstrating that the location of functional activity can be affected by local sulcal patterns. These results are critical for the investigation of the function of the vmPFC and show that taking into account the sulcal variability might be essential to guide the interpretation of neuroimaging studies. 08 mei 2019 14 p.

Published
2019

45. Dichotomous organization of amygdala/temporal-prefrontal bundles in both humans and monkeys

Author

Folloni, D., Sallet, J., Khrapitchev, A.A., Sibson, N.R., Verhagen, L., and Mars, R.B.

Subjects
Action, intention, and motor control
Abstract

Contains fulltext : 209490.pdf (Publisher’s version ) (Open Access) The interactions of anterior temporal structures, and especially the amygdala, with the prefrontal cortex are pivotal to learning, decision-making, and socio-emotional regulation. A clear anatomical description of the organization and dissociation of fiber bundles linking anterior temporal cortex/amygdala and prefrontal cortex in humans is still lacking. Using diffusion imaging techniques, we reconstructed fiber bundles between these anatomical regions in human and macaque brains. First, by studying macaques, we assessed which aspects of connectivity known from tracer studies could be identified with diffusion imaging. Second, by comparing diffusion imaging results in humans and macaques, we estimated the patterns of fibers coursing between human amygdala and prefrontal cortex and compared them with those in the monkey. In posterior prefrontal cortex, we observed a prominent and well-preserved bifurcation of bundles into primarily two fiber systems-an amygdalofugal path and an uncinate path-in both species. This dissociation fades away in more rostral prefrontal regions. 23 p.

Published
2019

46. Mapping multiple principles of parietal-frontal cortical organization using functional connectivity

Author

Vijayakumar, S., Sallet, J., Verhagen, L., Folloni, D., Medendorp, W.P., Mars, R.B., Vijayakumar, S., Sallet, J., Verhagen, L., Folloni, D., Medendorp, W.P., and Mars, R.B.

Abstract

Contains fulltext : 201922.pdf (publisher's version ) (Open Access), Resting state functional connectivity has been promoted as a promising tool for creating cortical maps that show remarkable similarity to those established by invasive histological methods. While this tool has been largely used to identify and map cortical areas, its true potential in the context of studying connectional architecture and in conducting comparative neuroscience has remained unexplored. Here, we employ widely used resting state connectivity and data-driven clustering methods to extend this approach for the study of the organizational principles of the macaque parietal-frontal system. We show multiple, overlapping principles of organization, including a dissociation between dorsomedial and dorsolateral pathways and separate parietal-premotor and parietal-frontal pathways. These results demonstrate the suitability of this approach for understanding the complex organizational principles of the brain and for large-scale comparative neuroscience.

Published
2019

47. Preserved extrastriate visual network in a monkey with substantial, naturally occurring damage to primary visual cortex

Author

Bridge, H., Bell, A.H., Ainsworth, M., Sallet, J., Premereur, E., Ahmed, B., Mitchell, A.S., Schüffelgen, U., Buckley, M.J., Tendler, B.C., Miller, K.L., Mars, R.B., Parker, A.J., Krug, K., Bridge, H., Bell, A.H., Ainsworth, M., Sallet, J., Premereur, E., Ahmed, B., Mitchell, A.S., Schüffelgen, U., Buckley, M.J., Tendler, B.C., Miller, K.L., Mars, R.B., Parker, A.J., and Krug, K.

Abstract

Contains fulltext : 203670.pdf (publisher's version ) (Open Access), Lesions of primary visual cortex (V1) lead to loss of conscious visual perception with significant impact on human patients. Understanding the neural consequences of such damage may aid the development of rehabilitation methods. In this rare case of a Rhesus macaque (monkey S), likely born without V1, the animal’s in-group behaviour was unremarkable, but visual task training was impaired. With multi-modal magnetic resonance imaging, visual structures outside of the lesion appeared normal. Visual stimulation under anaesthesia with checkerboards activated lateral geniculate nucleus of monkey S, while full-field moving dots activated pulvinar. Visual cortical activation was sparse but included face patches. Consistently across lesion and control monkeys, functional connectivity analysis revealed an intact network of bilateral dorsal visual areas temporally correlated with V5/MT activation, even without V1. Despite robust subcortical responses to visual stimulation, we found little evidence for strengthened subcortical input to V5/MT supporting residual visual function or blindsight-like phenomena.

Published
2019

48. The macaque anterior cingulate cortex translates counterfactual choice value into actual behavioral change

Author

Fouragnan, E.F., Chau, B.K.H., Folloni, D., Kolling, N., Verhagen, L., Klein-Flügge, M.C., Tankelevitch, L., Papageorgiou, G.K., Aubry, J.F., Sallet, J., Rushworth, M.F.S., Fouragnan, E.F., Chau, B.K.H., Folloni, D., Kolling, N., Verhagen, L., Klein-Flügge, M.C., Tankelevitch, L., Papageorgiou, G.K., Aubry, J.F., Sallet, J., and Rushworth, M.F.S.

Abstract

15 april 2019, Contains fulltext : 212295pub.pdf (publisher's version ) (Closed access), The neural mechanisms mediating sensory-guided decision-making have received considerable attention, but animals often pursue behaviors for which there is currently no sensory evidence. Such behaviors are guided by internal representations of choice values that have to be maintained even when these choices are unavailable. We investigated how four macaque monkeys maintained representations of the value of counterfactual choices - choices that could not be taken at the current moment but which could be taken in the future. Using functional magnetic resonance imaging, we found two different patterns of activity co-varying with values of counterfactual choices in a circuit spanning the hippocampus, the anterior lateral prefrontal cortex and the anterior cingulate cortex. Anterior cingulate cortex activity also reflected whether the internal value representations would be translated into actual behavioral change. To establish the causal importance of the anterior cingulate cortex for this translation process, we used a novel technique, transcranial focused ultrasound stimulation, to reversibly disrupt anterior cingulate cortex activity.

Published
2019

49. Manipulation of subcortical and deep cortical activity in the primate brain using transcranial focused ultrasound stimulation

Author

Folloni, D., Verhagen, L., Mars, R.B., Fouragnan, E.F., Constans, C., Aubry, J.F., Rushworth, M.F.S., Sallet, J., Folloni, D., Verhagen, L., Mars, R.B., Fouragnan, E.F., Constans, C., Aubry, J.F., Rushworth, M.F.S., and Sallet, J.

Abstract

Contains fulltext : 201971.pdf (publisher's version ) (Open Access), The causal role of an area within a neural network can be determined by interfering with its activity and measuring the impact. Many current reversible manipulation techniques have limitations preventing their application, particularly in deep areas of the primate brain. Here, we demonstrate that a focused transcranial ultrasound stimulation (TUS) protocol impacts activity even in deep brain areas: a subcortical brain structure, the amygdala (experiment 1), and a deep cortical region, the anterior cingulate cortex (ACC, experiment 2), in macaques. TUS neuromodulatory effects were measured by examining relationships between activity in each area and the rest of the brain using functional magnetic resonance imaging (fMRI). In control conditions without sonication, activity in a given area is related to activity in interconnected regions, but such relationships are reduced after sonication, specifically for the targeted areas. Dissociable and focal effects on neural activity could not be explained by auditory confounds.

Published
2019

50. Offline impact of transcranial focused ultrasound on cortical activation in primates

Author

Verhagen, L., Gallea, C., Folloni, D., Constans, C., Jensen, D.E.A., Ahnine, H., Roumazeilles, L., Santin, M., Ahmed, B., Lehericy, S., Klein-Flügge, M.C., Krug, K., Mars, R.B., Rushworth, M.F.S., Pouget, P., Aubry, J.F., Sallet, J., Verhagen, L., Gallea, C., Folloni, D., Constans, C., Jensen, D.E.A., Ahnine, H., Roumazeilles, L., Santin, M., Ahmed, B., Lehericy, S., Klein-Flügge, M.C., Krug, K., Mars, R.B., Rushworth, M.F.S., Pouget, P., Aubry, J.F., and Sallet, J.

Abstract

Contains fulltext : 201022.pdf (publisher's version ) (Open Access), To understand brain circuits it is necessary both to record and manipulate their activity. Transcranial ultrasound stimulation (TUS) is a promising non-invasive brain stimulation technique. To date, investigations report short-lived neuromodulatory effects, but to deliver on its full potential for research and therapy, ultrasound protocols are required that induce longer-lasting 'offline' changes. Here, we present a TUS protocol that modulates brain activation in macaques for more than one hour after 40 s of stimulation, while circumventing auditory confounds. Normally activity in brain areas reflects activity in interconnected regions but TUS caused stimulated areas to interact more selectively with the rest of the brain. In a within-subject design, we observe regionally specific TUS effects for two medial frontal brain regions - supplementary motor area and frontal polar cortex. Independently of these site-specific effects, TUS also induced signal changes in the meningeal compartment. TUS effects were temporary and not associated with microstructural changes.

Published
2019

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