Oscillatory Activity in Mouse Lemur Primary Motor Cortex During Natural Locomotor Behavior

In arboreal environments, substrate orientation determines the biomechanical strategy for postural maintenance and locomotion. In this study, we investigated possible neuronal correlates of these mechanisms in an ancestral primate model, the gray mouse lemur. We conducted telemetric recordings of electrocorticographic activity in left primary motor cortex of two mouse lemurs moving on a branch-like small-diameter pole, fixed horizontally, or vertically. Analysis of cortical oscillations in high β (25–35 Hz) and low γ (35–50 Hz) bands showed stronger resting power on horizontal than vertical substrate, potentially illustrating sensorimotor processes for postural maintenance. Locomotion on horizontal substrate was associated with stronger event-related desynchronization than vertical substrate, which could relate to locomotor adjustments and/or derive from differences in baseline activity. Spectrograms of cortical activity showed modulation throughout individual locomotor cycles, with higher values in the first than second half cycle. However, substrate orientation did not significantly influence these variations. Overall, these results confirm that specific cortical mechanisms are solicited during arboreal locomotion, whereby mouse lemurs adjust cortical activity to substrate orientation during static posture and locomotion, and modulate this activity throughout locomotor cycles

Saving Bones: a direct comparison of FTIR-ATR, whole bone percent nitrogen, and NIR

89th Annual Meeting of the American-Association-of-Physical-Anthropologists (AAPA), Los Angeles, CA, APR 15-18, 202

The nonhuman primate neuroimaging and neuroanatomy project

Multi-modal neuroimaging projects such as the Human Connectome Project (HCP) and UK Biobank are advancing our understanding of human brain architecture, function, connectivity, and their variability across individuals using high-quality non-invasive data from many subjects. Such efforts depend upon the accuracy of non-invasive brain imaging measures. However, ‘ground truth’ validation of connectivity using invasive tracers is not feasible in humans. Studies using nonhuman primates (NHPs) enable comparisons between invasive and non-invasive measures, including exploration of how “functional connectivity” from fMRI and “tractographic connectivity” from diffusion MRI compare with long-distance connections measured using tract tracing. Our NonHuman Primate Neuroimaging & Neuroanatomy Project (NHP_NNP) is an international effort (6 laboratories in 5 countries) to: (i) acquire and analyze high-quality multi-modal brain imaging data of macaque and marmoset monkeys using protocols and methods adapted from the HCP; (ii) acquire quantitative invasive tract-tracing data for cortical and subcortical projections to cortical areas; and (iii) map the distributions of different brain cell types with immunocytochemical stains to better define brain areal boundaries. We are acquiring high-resolution structural, functional, and diffusion MRI data together with behavioral measures from over 100 individual macaques and marmosets in order to generate non-invasive measures of brain architecture such as myelin and cortical thickness maps, as well as functional and diffusion tractography-based connectomes. We are using classical and next-generation anatomical tracers to generate quantitative connectivity maps based on brain-wide counting of labeled cortical and subcortical neurons, providing ground truth measures of connectivity. Advanced statistical modeling techniques address the consistency of both kinds of data across individuals, allowing comparison of tracer-based and non-invasive MRI-based connectivity measures. We aim to develop improved cortical and subcortical areal atlases by combining histological and imaging methods. Finally, we are collecting genetic and sociality-associated behavioral data in all animals in an effort to understand how genetic variation shapes the connectome and behavior

The role of soft tissues and minor osseous structures in cranial biomechanics

Finite element analysis is now widely recognised as an invaluable technique to investigate and understand cranial biomechanics since it can incorporate the complexity of a skull’s geometry, its construction, different materials and complex loadings. However, while the biofidelity of some aspects of these models is increasing, most still only consider the larger bony structures of the skull. This study examines the role of soft tissues and some smaller bony parts, to determine whether they should also be incorporated in such studies of cranial biomechanics. The structures that have been investigated include: the dura mater, the falx cerebri and the tentorium cerebelli, the periodontal ligament, the nasal turbinates and the osseous nasal septum, the postorbital bars and septa and the bulk tissues that surround the cranial bones. They are considered both in terms of their functional role and as part of the general functioning of the FE model that includes them. For this purpose, two FE models were used: a model of a Felis silvestris catus, which was created specifically for this project, and an adaptation of a previous head model of Homo sapiens.The results reveal that in Felis silvestris catus, the osseous tentorium does play a minor role in reducing stress in the parietal and temporal bones during feeding activities regarding of the biting regime. The causes of ossification and its possible mechanical role in several mammalian lineages, however, remain currently unclear. Moreover, inclusion of the nasal turbinates and the osseous part of the nasal septum is advisable in future FE models, as they impact the pattern of stress in the cranium, but the presence of generic bulk soft tissues in an FE model does not seem to have a meaningful effect on the results. On the other hand, modelling of the periodontal ligament has a localised effect in the alveolar region, but does not alter the general pattern of stress in the cranium.In the Homo sapiens model, the postorbital bars and the postorbital septa not only help reduce strain in various areas of the cranium, but also shelter the contents of the orbit and avoid distortion of the eye. The postorbital septa also reduce strain in the postorbital bars and minimize asymmetrical deformation between the working and balancing sides in unilateral molar bites.Altogether, this thesis offers a body of work which future researchers may find useful when investigating cranial biomechanics, to avoid oversimplification or incorporation of unnecessary complexities

Symmetry in Human Evolution, from Biology to Behaviours

Our knowledge of human evolution has made particular progress recently, due to the discovery of new fossils, the use of new methods and multidisciplinary approaches. Moreover, studies on the departure from symmetry, including variations in fluctuating or directional asymmetries, have contributed to the expansion of this knowledge. This Special Issue brings together articles that deal with symmetry and human evolution. The notion of symmetry is addressed, including whether to reconstruct deformed fossil specimens, study biological variations within hominins or compare them with extant primates, address the shape of the brain or seek possible relationships between biological and behavioural data