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Brain aging even in healthy older adults is characterized by a decline in cognitive functions including memory, learning and attention. Among others, memory is one of the major cognitive functions affected by aging. Understanding the mechanisms underlying age-related memory decline may help pave the road for novel treatment strategies. Here, we tried to elucidate the neural correlates associated with memory decline using structural and functional neuroimaging and neuromodulation with transcranial direct current stimulation (tDCS).
Over the course of three studies, we investigated 1) the influence of white matter integrity and grey matter volume on memory performance in healthy older adults, 2) the role of functional coupling within the memory network in predicting memory performance and the impact of tDCS in modulating retrieval performance in healthy older adults, 3) the effect of tDCS over the sensorimotor cortex on cognitive performance in young adults.
MRI was used to study associations of cognitive performance with white matter integrity and grey matter volume, and examine their causal relationship in the course of aging. White matter integrity was assessed by acquiring diffusion tensor imaging (DTI) and performing deterministic tractography based on constrained spherical deconvolution. Grey matter volume was estimated using fully automated segmentation. Both white matter integrity and grey matter volume were correlated with behavioral data of a verbal episodic memory task. Percentage of correct answers at retrieval was used to measure memory performance (Manuscript 1). In addition, anodal tDCS (atDCS) (1 mA, 20 min) was applied over CP5 (left temporoparietal cortex) to modulate memory formation in healthy older adults. Participants underwent resting-state fMRI before the stimulation. Functional connectivity analysis was performed to determine whether functional coupling within the memory network predicted initial memory performance, and to examine its association to tDCS-induced enhancement effect (Manuscript 2). Finally, atDCS (1 mA, 20 min) was applied over C3 (left sensorimotor cortex) to explore the effect of tDCS over the sensorimotor cortex on cognitive performance in young adults. During the stimulation, participants performed three tasks; gestural task, attentional load task and simple reaction time task (Manuscript 3).
Results showed that volumes of the left dentate gyrus (DG) and tractography-based fractional anisotropy (FA) of individual fornix pathways were positively related to memory retrieval in older adults. Brain-behavior associations were observed for correct rejections rather than hits of memory performance, indicating specificity of memory network functioning for detecting false associations. Thus, the data suggested a particular role of neural integrity that promotes successful memory retrieval in older adults. Subsequent mediation analysis showed that left DG volume mediated the effect of fornix FA on memory performance (48%), corrected for age, revealing a crucial role of hippocampal pathway microstructure in modulating memory performance in older adults (Manuscript 1). tDCS results showed that atDCS led to better retrieval performance and increasing learning curves, indicating that brain stimulation can induce plasticity of episodic memory processes in older adults. Combining tDCS and fMRI, hippocampo-temporoparietal functional connectivity was positively associated with initial memory performance in healthy older adults and was positively correlated with the magnitude of individual tDCS-induced enhancement, suggesting that individual tDCS responsiveness may be determined by intrinsic network coupling (Manuscript 2). Finally, our findings suggested that atDCS over left sensorimotor cortex reduced reaction times in the gestural-verbal integration task, specifically for incongruent pairs of gestures and verbal expressions, indicating the role of sensorimotor cortex in gestural-verbal integration in young adults (Manuscript 3).
The results of all three studies may help to elucidate age-related structural deterioration and functional coupling network underlying cognitive processes in healthy adults. Furthermore, these studies emphasized the importance of interventions like tDCS in modulating cognitive performance, specifically episodic verbal memory and gestural-verbal integration. By unveiling the specific role of brain structures and functional network coupling as well as the role of tDCS in modulating cognitive performance, our results contribute to a better understanding of brain-behavior associations, and may help to develop clinical interventional approaches, tailored for specific cognitive functions in aging.
Bats spend half of their life at roosting sites. Hence, exploring for potential roosts is an essential task for their survival, especially for those species which switch roosts regularly, such as several temperate bat species. However, localizing new roosts is a difficult task due to bats’ sensory limitations (e.g., vision, echolocation range). To compensate such constrains, it has been hypothesized that bats rely on cognitive processes like associative learning, spatial memory, social information use and memory retention for an efficient roost localization. However, no previous study has assessed these cognitive skills under natural conditions.
The aim of my thesis was to assess how individually RFID-marked, free-ranging bats use different cognitive processes when localizing suitable day roosts. For this purpose, I used a pairwise roost-quality (suitable vs. unsuitable) choice experiment with automatic monitoring and assessed bats’ cognitive processes according to different cues available. Cues were echo-reflective (spectral signature of boxes), spatial (position of the box within the experimental pair) and social (presence of conspecific at roosts), each one linked to a different cognitive process.
I found that Bechstein’s bats (Myotis bechsteinii) used associative learning to discriminate between suitable and unsuitable newly placed boxes according to their echo-reflective cues. However, when individuals returned to known suitable roosts, they relied more on spatial memory to localize them. This was evidenced by the higher proportion of visits to the unsuitable boxes after swapping box positions within the same experimental pairs. When social cues were available, bats discovered a higher number of suitable roosts and re-localized previously occupied roosts more accurately. Taken together, Bechstein’s bats used multiple cognitive processes and prioritized one process over another depending on the relevance of the cues and search context.
Memory retention of the learned association was analyzed one year later, after the bats had returned to their breeding sites from their hibernacula. I found no evidence that individuals remembered the association between roosts’ suitability and their respective echo-reflective cue. The lack of memory retention could be attributed to hibernation or the duration of the period that the bats spent away from their summer habitat without the opportunity to reinforce the association contingencies. Nevertheless, bats quickly relearned the same association in a short period of time. This emphasizes the high behavioral flexibility of the bats.
Given the ability of Bechstein’s bats to quickly learn to discriminate roosts based on their external echo-reflective cue via associative learning, I investigated whether the use of echo-reflective cues improves box detectability and further occupancy. This was also assessed in free-ranging Natterer’s (Myotis nattereri) bats and the brown long-eared bats (Plecotus auritus). I found that the use of echo-reflective cues did not improve the detectability and occupancy of newly placed boxes despite the previous experience of the colonies with such cues. There were differences among species in the number of discovered boxes, visits and roosting days. These differences could be related to the species-specific explorative behavior and roost-switching behavior. Box supplementations programs aimed to conserve or relocate bat colonies should consider these behaviors to increase their likelihood of success even when bat colonies are used to roosting in artificial shelters.
My research underlined the importance of evaluating multiple cues under natural conditions to understand how natural selection has shaped the cognitive process used for localizing resources. Cognitive field studies are logistically challenging given the number of factors to control. However, automatic monitoring techniques like the one used in this study give the possibility to deepen the understanding of the cognitive ecology of animals. I finally discuss two venues of further research to understand the spread of information within colony members about novel roosts and the recruitment dynamic to novel roosts.