Richard Levy

Coupled Temporal Memories in Parkinson's Disease: A Dopamine-Related Dysfunction

Dysfunction of the basal ganglia and the brain nuclei interconnected with them leads to disturbances of movement and cognition, including disordered timing of movement and perceptual timing deflcits. Patients with Parkinsons disease (PD) were studied in temporal reproduction tasks. We examined PD patients when brain dopamine (DA) transmission was impaired (OFF state) and when DA transmission was reestablished, at the time of maximal clinical beneflt following administration of levodopa + apomorphine (ON state). Patients reproduced target times of 8 and 21 sec trained in blocked trials with the peak interval procedure, which were veridical in the ON state, comparable to normative performance by healthy young and aged controls (Experiment 1). In the OFF state, temporal reproduction was impaired in both accuracy and precision (variance). The 8-sec signal was reproduced as longer and the 21-sec signal was reproduced as shorter than they actually were (Experiment 1). This fimigrationfl effect was dependent upon training of two different durations. When PD patients were trained on 21 sec only (Experiment 2), they showed a reproduction error in the long direction, opposite to the error produced under the dual training condition of Experiment 1. The results are discussed as a mutual attraction between temporal processing systems, in memory and clock stages, when dopaminergic regulation in the striatum is dysfunctional.

Rostral and caudal prefrontal contribution to creativity: a meta-analysis of functional imaging data

Creativity is of central importance for human civilization, yet its neurocognitive bases are poorly understood. The aim of the present study was to integrate existing functional imaging data by using the meta-analysis approach. We reviewed 34 functional imaging studies that reported activation foci during tasks assumed to engage creative thinking in healthy adults. A coordinate-based meta-analysis using Activation Likelihood Estimation (ALE) first showed a set of predominantly left-hemispheric regions shared by the various creativity tasks examined. These regions included the caudal lateral prefrontal cortex (PFC), the medial and lateral rostral PFC, and the inferior parietal and posterior temporal cortices. Further analyses showed that tasks involving the combination of remote information (combination tasks) activated more anterior areas of the lateral PFC than tasks involving the free generation of unusual responses (unusual generation tasks), although both types of tasks shared caudal prefrontal areas. In addition, verbal and non-verbal tasks involved the same regions in the left caudal prefrontal, temporal, and parietal areas, but also distinct domain-oriented areas. Taken together, these findings suggest that several frontal and parieto-temporal regions may support cognitive processes shared by diverse creativity tasks, and that some regions may be specialized for distinct types of processes. In particular, the lateral PFC appeared to be organized along a rostro-caudal axis, with rostral regions involved in combining ideas creatively and more posterior regions involved in freely generating novel ideas.

Cognitive mapping in humans and its relationship to other orientation skills

Human orientation in novel and familiar environments is a complex skill that can involve numerous different strategies. To date, a comprehensive account of how these strategies interrelate at the behavioural level has not been documented, impeding the development of elaborate systems neuroscience models of spatial orientation. Here, we describe a virtual environment test battery designed to assess five of the core strategies used by humans to orient. Our results indicate that the ability to form a cognitive map is highly related to more basic orientation strategies, supporting previous proposals that encoding a cognitive map requires inputs from multiple domains of spatial processing. These findings provide a topology of numerous primary orientation strategies used by humans during orientation and will allow researchers to elaborate on neural models of spatial cognition that currently do not account for how different orientation strategies integrate over time based on environmental conditions.

Visualization of urban alternatives

Advances in computer graphics technology have made it possible for planners to model urban environments in three-dimensional electronic space. Lower platform costs, higher performance, and better software applications have brought modeling within the reach of most planning departments and urban design consultants. In this paper, examples are given of the critical role played by computer aided design (CAD) as a visualization tool in the planning process. The images presented have all been generated using AutoCAD and ArchiCAD, off-the-shelf CAD programs available on both PC and MAC platforms. Highlighted in this paper are two projects which use CAD to assess the impact of large-scale development. In both case studies, computer visualization expanded the range of alternative proposals under consideration. Community participation, historical context, and private participation are factors which influence the ultimate acceptance of visualized proposals. These actual cases studies are examples of the new opportunities CAD offers in urban planning.

TBK1 mutation frequencies in French frontotemporal dementia and amyotrophic lateral sclerosis cohorts.

TANK1-binding kinase 1 (TBK1) has been recently identified as a new amyotrophic lateral sclerosis (ALS) gene. Loss-of-function (LoF) mutations in TBK1 could be responsible for 0.4%-4% of ALS. Considering the strong genetic overlap existing between frontotemporal dementia (FTD) and ALS, we have evaluated the frequencies of TBK1 mutations in a cohort of French FTD and of ALS patients. We identified 5 LoF mutations, in 4 FTD-ALS and 1 ALS patients. We also identified 5 heterozygous missense variants, predicted to be deleterious, in 1 isolated FTD, 1 FTD-ALS, and 3 ALS cases. Our results demonstrate that TBK1 loss-of-function mutations are more frequent in patients with FTD-ALS (10.8%) than in isolated ALS. TBK1 should thus also be sequenced, after exclusion of C9orf72 mutation, in patients presenting FTD, particularly in cases secondarily associated with ALS.

Spatial and temporal functional connectivity changes between resting and attentive states

Remote brain regions show correlated spontaneous activity at rest within well described intrinsic connectivity networks (ICNs). Meta‐analytic coactivation studies have uncovered networks similar to resting ICNs, suggesting that in task states connectivity modulations may occur principally within ICNs. However, it has also been suggested that specific “hub” regions dynamically link networks under different task conditions. Here, we used functional magnetic resonance imaging at rest and a continuous visual attention task in 16 participants to investigate whether a shift from rest to attention was reflected by within‐network connectivity modulation, or changes in network topography. Our analyses revealed evidence for both modulation of connectivity within the default‐mode (DMN) and dorsal attention networks (DAN) between conditions, and identified a set of regions including the temporoparietal junction (TPJ) and posterior middle frontal gyrus (MFG) that switched between the DMN and DAN depending on the task. We further investigated the temporal nonstationarity of flexible (TPJ and MFG) regions during both attention and rest. This showed that moment‐to‐moment differences in connectivity at rest mirrored the variation in connectivity between tasks. Task‐dependent changes in functional connectivity of flexible regions may, therefore, be understood as shifts in the proportion of time specific connections are engaged, rather than a switch between networks per se. This ability of specific regions to dynamically link ICNs under different task conditions may play an important role in behavioral flexibility. Hum Brain Mapp 36:549–565, 2015.

Neural network configuration and efficiency underlies individual differences in spatial orientation ability

Spatial orientation is a complex cognitive process requiring the integration of information processed in a distributed system of brain regions. Current models on the neural basis of spatial orientation are based primarily on the functional role of single brain regions, with limited understanding of how interaction among these brain regions relates to behavior. In this study, we investigated two sources of variability in the neural networks that support spatial orientation—network configuration and efficiency—and assessed whether variability in these topological properties relates to individual differences in orientation accuracy. Participants with higher accuracy were shown to express greater activity in the right supramarginal gyrus, the right precentral cortex, and the left hippocampus, over and above a core network engaged by the whole group. Additionally, high-performing individuals had increased levels of global efficiency within a resting-state network composed of brain regions engaged during orientation and increased levels of node centrality in the right supramarginal gyrus, the right primary motor cortex, and the left hippocampus. These results indicate that individual differences in the configuration of task-related networks and their efficiency measured at rest relate to the ability to spatially orient. Our findings advance systems neuroscience models of orientation and navigation by providing insight into the role of functional integration in shaping orientation behavior.

‘Breaking the fourth wall’: 3D virtual worlds as tools for knowledge repatriation in archaeology

Interactive 3-dimensional worlds and computer modeling can be used to excite interest in archaeology among indigenous groups such as the Inuit of the North American Arctic and Greenland. Using two case studies – a recently completed exhibition for the Virtual Museum of Canada on Thule Inuit whalebone houses and an interactive virtual world structured around the Siglit-Inuvialuit sod house – we explore how digital replicas might be used in the repatriation of traditional knowledge. This idea is examined through theexperiences of nine Inuit Elders who explored our digital reconstructions of Thule and Siglit-Inuvialuit dwellings in 3D. Discussions with the Elders suggest that the generic sense of ‘presence’ generated by 3D viewing enhanced their feelings of connectedness to their past. This would imply that virtual reality and 3D technology might be useful in establishing new discourses in archaeological interpretation, as well as assisting in the exploration, construction, and maintenance of cultural identities through knowledge repatriation.

Developmental topographical disorientation and decreased hippocampal functional connectivity

Developmental topographical disorientation (DTD) is a newly discovered cognitive disorder in which individuals experience a lifelong history of getting lost in both novel and familiar surroundings. Recent studies have shown that such a selective orientation defect relies primarily on the inability of the individuals to form cognitive maps, i.e., mental representations of the surrounding that allow individuals to get anywhere from any location in the environment, although other orientation skills are additionally affected. To date, the neural correlates of this developmental condition are unknown. Here, we tested the hypothesis that DTD may be related to ineffective functional connectivity between the hippocampus (HC; known to be critical for cognitive maps) and other brain regions critical for spatial orientation. A group of individuals with DTD and a group of control subjects underwent a resting‐state functional magnetic resonance imaging (rsfMRI) scan. In addition, we performed voxel‐based morphometry to investigate potential structural differences between individuals with DTD and controls. The results of the rsfMRI study revealed a decreased functional connectivity between the right HC and the prefrontal cortex (PFC) in individuals with DTD. No structural differences were detected between groups. These findings provide evidence that ineffective functional connectivity between HC and PFC may affect the monitoring and processing of spatial information while moving within an environment, resulting in the lifelong selective inability of individuals with DTD to form cognitive maps that are critical for orienting in both familiar and unfamiliar surroundings.

Simulating the behaviour of light inside Arctic dwellings: implications for assessing the role of vision in task performance

Abstract Visibility studies in archaeology have been criticized because they tend to emphasize the importance of vision over other senses. The burgeoning field of sensory anthropology argues that the relative significance of visual, olfactory, acoustic and haptic (touch) senses varies cross-culturally, and is a function of how human beings interact with their particular environments. The Canadian Arctic is a unique sensory environment because prolonged periods of winter darkness make artificial light essential for everyday tasks. In this paper, we use 3D computer modelling to simulate the levels of light produced by the small stone lamps used inside pre-contact Thule Inuit winter dwellings. The results demonstrate that interior light levels fall well below those recommended by Western architectural standards for tasks requiring high levels of visual acuity. We conclude that this may have influenced where activities were situated inside the dwelling and encouraged greater use of touch relative to vision when performing tasks such as sewing and carving.