Ramping single unit activity in the medial prefrontal cortex and ventral striatum reflects the onset of waiting but not imminent impulsive actions

Some have claimed that the medial prefrontal cortex (mPFC) mediates decision making. Others suggest mPFC is selectively involved in the retrieval of remote long-term memory. Yet others suggests mPFC supports memory and consolidation on time scales ranging from seconds to days. How can all these roles be reconciled? We propose that the function of the mPFC is to learn associations between context, locations, events, and corresponding adaptive responses, particularly emotional responses. Thus, the ubiquitous involvement of mPFC in both memory and decision making may be due to the fact that almost all such tasks entail the ability to recall the best action or emotional response to specific events in a particular place and time. An interaction between multiple memory systems may explain the changing importance of mPFC to different types of memories over time. In particular, mPFC likely relies on the hippocampus to support rapid learning and memory consolidation. Copyright © 2012 Elsevier Inc. All rights reserved.

The concept of impulsivity covers a wide range of "actions that are poorly conceived, prematurely expressed, unduly risky, or inappropriate to the situation and that often result in undesirable outcomes". As such it plays an important role in normal behaviour, as well as, in a pathological form, in many kinds of mental illness such as mania, personality disorders, substance abuse disorders and attention deficit/hyperactivity disorder. Although evidence from psychological studies of human personality suggests that impulsivity may be made up of several independent factors, this has not made a major impact on biological studies of impulsivity. This may be because there is little unanimity as to which these factors are. The present review summarises evidence for varieties of impulsivity from several different areas of research: human psychology, psychiatry and animal behaviour. Recently, a series of psychopharmacological studies has been carried out by the present author and colleagues using methods proposed to measure selectively different aspects of impulsivity. The results of these studies suggest that several neurochemical mechanisms can influence impulsivity, and that impulsive behaviour has no unique neurobiological basis. Consideration of impulsivity as the result of several different, independent factors which interact to modulate behaviour may provide better insight into the pathology than current hypotheses based on serotonergic underactivity.

The developmental history and application of the 5-choice serial reaction time task (5CSRTT) for measuring effects of drugs and other manipulations on attentional performance (and stimulus control) in rats is reviewed. The 5CSRTT has been used for measuring effects of systemic drug treatments and also central manipulations such as neurochemical lesions on various aspects of attentional control, including sustained, selective and divided attention--and is relevant to the definition of neural systems of attention and applications to human disorders such as attention deficit/hyperactivity disorder (ADHD) and Alzheimer's disease. The 5CSRTT is implemented in a specially designed operant chamber with multiple response locations ('nine-hole box') using food reinforcers to maintain performance on baseline sessions (about 100 trials) at criterion levels of accuracy and trials completed. The 5CSRTT can be used for measuring various aspects of attentional control over performance with its main measures of accuracy, premature responding, correct response latencies and latency to collect earned food pellets. The data reviewed include studies mainly of systemic and intra-cerebral effects of adrenoceptor, dopamine receptor, serotoninergic receptor and cholinergic receptor agents. These are compared with investigations of effects of selective chemical neurotoxins and excitotoxins applied to discrete parts of the forebrain, in order to define the neural and neurochemical substrates of attentional function. Furthermore, these results are integrated with findings from in vivo microdialysis in freely moving rats or metabolic studies. The monoaminergic and cholinergic systems appear to play separable roles in different aspects of performance controlled by the 5CSRTT, in neural systems centred on the prefrontal cortex, cingulate cortex and striatum. These conclusions are considered in the methodological and theoretical context of other psychopharmacological studies of attention in animals and humans.