Individual differences in neurocognitive aging in outbred male and female long-evans rats.

Individual differences in biology as well as experience and exposures throughout life may contribute risk or resilience to neurocognitive decline in aging. To investigate the role of sex as a biological variable in cognitive function due to normal aging, we used substantial cohorts of healthy male and female aged outbred rats maintained under similar conditions throughout life to assess whether both sexes display a similar distribution of individual differences in behavioral performance using a water maze task optimized to assess hippocampal-dependent cognition in aging. We found both aged male and female rats performed poorer than young adults overall, but with no performance differences between sex in either young adults or aged groups in memory probe tests. In addition, aged male and female rats had similar distributions of individual differences such that the same proportion of male and female performed on par with (intact memory) or outside of (impaired memory) the benchmark of young rats of their respective sex. The data support the use of this outbred model with biological diversity to study the neurobiology of aging trajectories for variation in cognitive outcomes in both male and females. (PsycInfo Database Record (c) 2022 APA, all rights reserved).

Cognitive aging and the hippocampus: how old rats represent new environments.

Spatial learning impairment in aged rats is associated with changes in hippocampal connectivity and plasticity. Several studies have explored the age-related deficit in spatial information processing by recording the location-specific activity of hippocampal neurons (place cells). However, these studies have generated disparate characterizations of place cells in aged rats as unstable (Barnes et al., 1997), resistant to change (Tanila et al., 1997b; Oler and Markus, 2000; Wilson et al., 2003), or delayed in using external cues (Rosenzweig et al., 2003). To reconcile these findings, we recorded place cells from aged and young rats as they repeatedly explored both a highly familiar environment and an initially novel environment, and we repeatedly tested whether the place fields formed in the novel environment were anchored by external cues. Initially, spatial representations in aged rats were abnormally maintained between the familiar and novel environments. Then, new representations were formed but were also delayed in becoming anchored to the external landmarks. Finally, even when the new spatial representations became bound to the landmarks, they were multi-stable across repetitive exposures to the formerly novel environment. These observations help to reconcile previously divergent characterizations of spatial representation in aged rats and suggest a model of cognitive aging and hippocampal function.

Place cells of aged rats in two visually identical compartments.

Aged rats perform poorly on spatial learning tasks, a cognitive impairment which has been linked to the failure of hippocampal networks to fully encode changes in the external environment [Barnes CA, Suster MS, Shen J, McNaughton BL. Multistability of cognitive maps in the hippocampus of old rats. Nature 1997;388(6639):272-5; Wilson IA, Ikonen S, Gureviciene I, McMahan RW, Gallagher M, Eichenbaum H, et al. Cognitive aging and the hippocampus: how old rats represent new environments. J Neurosci 2004;24(15):3870-8]. To examine whether the impairment in hippocampal processing extends to conditions in which self-motion provides the cues for environmental change, we have analyzed spatial firing patterns of hippocampal pyramidal neurons in young and aged rats, as well as in young rats with selective cholinergic lesions, another model of cognitive aging. The rats walked between two visually identical environments, pitting self-motion cues that indicated environmental change against visual inputs that indicated no differences between environments. Our results indicated that place cells in both aged and cholinergic-lesioned rats were equally likely as those of young rats to create new spatial representations in the second compartment. These findings suggest that the hippocampal network of aged rats is able to process changes in internally generated cues without rigidity, but that incomplete processing of external landmark cues may lead to impaired spatial learning.