Brown HD, Kozak R, Sarter M (2006) Bilateral removal of cholinergic inputs to the medial prefrontal cortex disrupts the ability of rats to cope with challenges on attentional performance. Neuroscience 2006 Abstracts 369.20. Society for Neuroscience, Atlanta, GA.
Summary: Studies using microdialysis for the measurement of the release of neurotransmitters in task-performing animals demonstrated attentional performance-associated increases in acetylcholine (ACh) release in the medial prefrontal cortex (mPFC). Moreover, these studies indicated that challenges on attentional performance are associated with augmented increases in mPFC ACh release. Such increases in ACh release were observed while the animals’ performance remained impaired in response to pharmacological or behavioral challenges, and while performance recovered from such challenges. These findings support the general hypothesis that increases in prefrontal cholinergic neurotransmission mediate increases in attentional effort, including the recruitment of prefrontal efferent projections to optimize top-down input processing in sensory and sensory-associational cortical regions. This hypothesis further suggests that cholinergic inputs to these regions directly amplify input processing, and that this more posterior branch of the cortical cholinergic input system is regulated in part by prefrontal outputs (Sarter et al. 2005, 2006). We have previously demonstrated that cortex-wide removal of cholinergic inputs results in persistent impairments in attentional performance. The present experiment was designed to demonstrate that restricted removal of mPFC cholinergic inputs selectively disrupts the animals’ ability to increase their attentional effort in order to maintain and recover from impairments produced by a visual distractor. Animals were trained in a sustained attention task and familiarized with the distractor. Cholinergic inputs to the prelimbic and anterior cingulate cortex were removed by infusions of 192 IgG-saporin into the mPFC. Results indicate that this lesion primarily exaggerated the detrimental performance effects of the distractor. Specifically, the ability of lesioned animals to stabilize their residual hit rate was impaired following distractor presentation. These results indicate that the integrity of cholinergic inputs to the mPFC is necessary for the recruitment of the cognitive mechanisms mediating stabilization and recovery of cognitive performance following attentional challenges.
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