Adaptive normalization in the prefrontal
cortex is reduced by memory load
|
|
Holper L, Van Brussel LD, Schmidt L, Schulthess S, Burke CJ, Louie K, Seifritz E, Tobler PN
eNeuro, 4(2) ENEURO.0365-17.2017 |
|
Adaptation
facilitates neural representation of a wide range of diverse inputs,
including reward values. Adaptive value coding typically relies on
contextual information obtained either from the environment or
retrieved from and maintained in memory. However, it is unknown whether
having to retrieve and maintain context information modulates the
brain’s capacity for value adaptation. To address this issue, we
measured hemodynamic responses of the prefrontal cortex (PFC) in two
studies on risky decision-making. In each trial, healthy human subjects
chose between a risky and a safe alternative and half of the
participants had to remember the risky alternatives whereas for the
other half it was presented. The value of safe alternatives varied
across trials. PFC responses adapted to contextual risk information,
with steeper coding of safe alternative value in lower risk contexts.
Importantly, this adaptation depended on working memory load, such that
response functions relating PFC activity to safe values were steeper
with presented compared to remembered risk. An independent second study
replicated the findings of the first study and showed that similar
slope reductions also arose when memory maintenance demands were
increased with a secondary working memory task. Formal model comparison
showed that a divisive normalization model fitted effects of both risk
context and working memory demands on PFC activity better than
alternative models of value adaptation, and revealed that reduced
suppression of background activity was the critical parameter impairing
normalization with increased memory maintenance demand. Our findings
suggest that mnemonic processes can constrain normalization of neural
value representations.
|
|
PDF | PubMed
|