4 Hz in young rats and 535 Hz in aged rats (Insel et al, 2012),

4 Hz in young rats and 53.5 Hz in aged rats (Insel et al., 2012), and this difference was statistically reliable. Because gamma frequencies are thought

to be mediated by network interactions between glutamatergic and GABAergic cells (Tiesinga et al., 2001; Börgers et al., 2005; Wang, 2010), the changes in gamma frequency suggest that the interaction between these cell types may be compromised in aged animals. In support of this, Insel et al. found that, during the performance of the task, putative excitatory and inhibitory neurons of the medial PFC fired preferentially at different phases of the gamma cycle in young and aged rats. When cross-correlation analysis was applied to simultaneously recorded excitatory–inhibitory cell pairs, the interval between the excitatory drive onto this website inhibitory cells was lengthened in the older rats (Insel et al., 2012). While arguments for direct causation cannot be made, these studies suggest that GABAergic transmission is altered in the PFC of aged rodents and that this may contribute to altered gamma synchrony among medial PFC networks. Converging evidence links age-related working memory impairments to dysfunction of adrenergic systems in primates. Indeed, age-related disinhibition of cyclic adenosine monophosphate (cAMP) signaling has been shown to lead to decreases in persistent firing of area 46 neurons that are active through a delay period during Torin 1 purchase working-memory

tasks (Ramos et al., 2003; Arnsten et al., 2010; Wang et al., 2011). These delay-firing neurons show a sustained activation that 3-mercaptopyruvate sulfurtransferase lasts for the duration of the cue delay period of a delayed response task (Goldman-Rakic, 1995). This increased activation is modulated by spatial location on a screen, and is greatest for the neurons’ preferred direction. In aged monkeys, there is an age-related loss in response modulation of these neurons to their preferred spatial location during working memory tasks, to a point where

delay neurons show very little increase in firing rate during the cue delay period (Wang et al., 2011). The decrease in activity of delay neurons in aged monkeys could be rescued using local drug administration that inhibited either cAMP or the downstream potassium channels that cAMP is known to activate (HCN, KCNQ; Wang et al., 2011). The same results could be obtained using local infusion of guanfacine, an α2A adrenergic agonist that inhibits cAMP signaling (Wang et al., 2011). Guanfacine and clonidine are both α2A adrenergic agonists known to enhance working memory performance in aged rats (Arnsten et al., 1988; Arnsten & Goldman-Rakic, 1990; Ramos et al., 2003). Because α2A adrenergic agonists have no effects on a visual pattern discrimination task (Arnsten & Goldman-Rakic, 1985), the effect of guanfacine on working memory performance is probably through its action on the activity of PFC neurons.

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