Abstract
In recent years, the study of resting state neural activity has received much attention. To better understand the roles of different brain regions in the regulation of behavioral activity in an arousing or a resting period, we developed a novel behavioral paradigm (8-arm food-foraging task; 8-arm FFT) using the radial 8-arm maze and examined how AcbC lesions affect behavioral execution and learning. Repetitive training on the 8-arm FFT facilitated motivation of normal rats to run quickly to the arm tips and to the center platform before the last-reward collection. Importantly, just after this point and before confirmation of no reward at the next arm traverse, locomotor activity decreased. This indicates that well-trained rats can predict the absence of the reward at the end of food seeking and then start another behavior, namely planned resting. Lesions of the AcbC after training selectively impaired this reduction of locomotor activity after the last-reward collection without changing activity levels before the last-reward collection. Analysis of arm-selection patterns in the lesioned animals suggests little influence of the lesion in the ability to predict the reward absence. AcbC lesions did not change exploratory locomotor activity in an open-field test in which there were no rewards. This suggests that the AcbC controls the activity level of planned resting behavior shaped by the 8-arm FFT. Rats receiving training after AcbC lesioning showed a reduction in motivation for reward seeking. Thus, the AcbC also plays important roles not only in controlling the activity level after the last-reward collection but also in motivational learning for setting the activity level of reward-seeking behavior.
Highlights
The observation that neural activity can increase during awake and intentional resting states has received increasing research attention in recent years, from examination of individual neurons to functional brain imaging to behavior
We conclude that the Accumbens Core (AcbC) is involved in motivational learning that sets the activity level of reward-seeking behavior
We examined the influence of AcbC lesions on exploration and habituation in an open-field test (Figure 4)
Summary
The observation that neural activity can increase during awake and intentional resting states has received increasing research attention in recent years, from examination of individual neurons to functional brain imaging to behavior. A network of brain regions that exhibit increased activity during rest and decreased activity during a given task has been identified This network has been termed the ‘‘default mode network’’ (DMN) [4]. The patterns of correlated brain activity during rest can predict the disease progression of patients with mild cognitive impairment [10,11]. From these observations, it is hypothesized that enhanced neural activity during rest involves non-random cognitive processing. It is hypothesized that enhanced neural activity during rest involves non-random cognitive processing It is still unclear, what the physiological function is of this brain activity during rest
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