Regional and cellular fractionation of working memory

Working memory in childhood-onset schizophrenia and attention-deficit/hyperactivity disorder

We investigated verbal and spatial working memory in participants with childhood-onset schizophrenia (N=13), attention-deficit/hyperactivity disorder (ADHD; N=31) and age-matched normal children (N=27). The ages of the participants ranged from 9 to 20 years, with an average age of approx. 14 in all groups. Diagnoses were based on structured interviews (Kiddie-Schedule for Affective Disorders and Schizophrenia) with the children and their parents and made using DSM-III-R criteria. Verbal working memory was assessed by the highest number of digits recalled in forward and backward order on the Digit Span subtest of the Wechsler Intelligence Scale. Results showed that normal children recalled more digits than schizophrenic and ADHD children, who did not differ. Spatial working memory was assessed with the Dot Test of Visuospatial Working Memory: The children were presented with a dot on a page for 5 s and asked to mark its location on a blank page immediately after presentation or 30 s later. A distracter task was used during the delay to prevent verbal rehearsal. The average distance between the target dot and the child's mark in the 30-s condition was shorter for normal than for schizophrenic and ADHD children, who did not differ. Thus, both schizophrenic and ADHD children showed deficits in verbal and spatial working memory. These results suggest that in both disorders, the capacity of the sensory buffers may be diminished, and/or the availability and allocation of resources to the central executive may be limited.

Subpopulations of cortical GABAergic interneurons differ by their expression of D1 and D2 dopamine receptor subtypes

D1 and D2 receptors have been described in different populations of efferent pyramidal neurons of the rat frontal cortex. Combined in situ hybridization and immunocytochemistry show here that these two subtypes are expressed in cortical GABAergic interneurons, with D1 and D2 mainly found in a subpopulation containing parvalbumin, whereas only 10% of the calbindin neurons express D1 receptors. These data indicate that various DA agonists may influence inhibitory circuits by distinct dopamine receptor subtypes.

D1- versus D2-receptor modulation of visuospatial working memory in humans

The effects of pergolide, a mixed D1/D2 receptor agonist, and bromocriptine, a selective D2 receptor agonist, were assessed in a visual delay task to further investigate the "dopamine link" of working memory in humans and to look for differential D1 versus D2 receptor contributions. Two groups of 32 healthy young adults (16 female) received either 0.1 mg of pergolide or 2.5 mg of bromocriptine in a placebo-controlled cross-over design. A pretreatment with domperidone, a peripherally active D2 antagonist, was performed in both groups to reduce side effects. Interindividual differences in pharmacokinetics were controlled by the time course of serum prolactin inhibition. The working memory paradigm was a visuospatial delayed matching task; the location of a randomly generated seven-point pattern had to be memorized and compared after 2, 8, or 16 sec with a second pattern that was either identical or slightly shifted within a reference frame. The task was designed with the intention to present unique stimuli at each trial and to require minimal motor demands. Practice effects between the two pharmacological test days were minimized by training sessions that preceded the tests. The paradigm showed significant error and reaction time increases with longer delays. After comparable doses, only pergolide, but not bromocriptine, facilitated visuospatial working memory performance as demonstrated by a significant drug-by-delay interaction. These findings are in accordance with the monkey literature as well as with neuroanatomical findings, and they confirm a preferential role of prefrontal D1 receptors for working memory modulation in humans.

D1- versus D2-receptor modulation of visuospatial working memory in humans

The effects of pergolide, a mixed D1/D2 receptor agonist, and bromocriptine, a selective D2 receptor agonist, were assessed in a visual delay task to further investigate the "dopamine link" of working memory in humans and to look for differential D1 versus D2 receptor contributions. Two groups of 32 healthy young adults (16 female) received either 0.1 mg of pergolide or 2.5 mg of bromocriptine in a placebo-controlled cross-over design. A pretreatment with domperidone, a peripherally active D2 antagonist, was performed in both groups to reduce side effects. Interindividual differences in pharmacokinetics were controlled by the time course of serum prolactin inhibition. The working memory paradigm was a visuospatial delayed matching task; the location of a randomly generated seven-point pattern had to be memorized and compared after 2, 8, or 16 sec with a second pattern that was either identical or slightly shifted within a reference frame. The task was designed with the intention to present unique stimuli at each trial and to require minimal motor demands. Practice effects between the two pharmacological test days were minimized by training sessions that preceded the tests. The paradigm showed significant error and reaction time increases with longer delays. After comparable doses, only pergolide, but not bromocriptine, facilitated visuospatial working memory performance as demonstrated by a significant drug-by-delay interaction. These findings are in accordance with the monkey literature as well as with neuroanatomical findings, and they confirm a preferential role of prefrontal D1 receptors for working memory modulation in humans.

Temporal limits of spatial working memory in humans

An essential feature attributed to working memory is the labile and transient nature of its representations. Using an oculomotor task, we examined the stability of spatial working memory in 16 normal human subjects. Eye movements towards remembered spatial cues (memory-guided saccades) were electro-oculographically recorded after memorization delays that varied unpredictably between 0.5 and 30s. A peaked time-course of saccadic targeting errors, with maximal errors around 20s delay, was found, showing that delay-dependent decay of spatial information in working memory occurs, but is time-limited and reverts significantly beyond delays of about 20s. These data (i) indicate temporal limits of spatial working memory and (ii) provide the first behavioural evidence for the existence of two parallely generated mental representations of space that successively control memory-guided behaviour in humans.

The evolutionary origin of the language areas in the human brain. A neuroanatomical perspective

The capacity to learn syntactic rules is a hallmark of the human species, but whether this has been acquired by the process of natural selection has been the subject of controversy. Furthermore, the cortical localization of linguistic capacities has prompted some authors to suggest a modular representation of language in the brain. In this paper, we rather propose that the neural device involved in language is embedded into a large-scale neurocognitive network comprising widespread connections between the temporal, parietal and frontal (especially prefrontal) cortices. This network is involved in the temporal organization of behavior and motor sequences, and in working (active) memory, a sort of short-term memory that participates in immediate cognitive processing. In human evolution, a precondition for language was the establishment of strong cortico-cortical interactions in the postrolandic cortex that enabled the development of multimodal associations. Wernicke's area originated as a converging place in which such associations (concepts) acquired a phonological correlate. We postulate that these phonological representations projected into inferoparietal areas, which were connected to the incipient Broca's area, thus forming a working memory circuit for processing and learning complex vocalizations. As a result of selective pressure for learning capacity and memory storage, this device yielded a sophisticated system able to generate complicated utterances (precursors of syntax) as it became increasingly connected with other brain regions, especially in the prefrontal cortex. This view argues for a gradual origin of the neural substrate for language as required by natural selection.

Neural correlates of motor memory consolidation

Computational studies suggest that acquisition of a motor skill involves learning an internal model of the dynamics of the task, which enables the brain to predict and compensate for mechanical behavior. During the hours that follow completion of practice, representation of the internal model gradually changes, becoming less fragile with respect to behavioral interference. Here, functional imaging of the brain demonstrates that within 6 hours after completion of practice, while performance remains unchanged, the brain engages new regions to perform the task; there is a shift from prefrontal regions of the cortex to the premotor, posterior parietal, and cerebellar cortex structures. This shift is specific to recall of an established motor skill and suggests that with the passage of time, there is a change in the neural representation of the internal model and that this change may underlie its increased functional stability.

Getting a grasp on working memory

Without it, you couldn't understand this sentence, add up a restaurant tab in your head, or even find your way home. The “it” is working memory, an erasable mental blackboard that allows you to hold briefly in your mind the information essential for comprehension, reasoning, and planning. Now, neurobiologists are beginning to identify the neural machinery underlying this critical ability. They have found that working memory relies on cooperation among scattered areas of the brain, with the prefrontal cortex apparently working as the orchestrator that coordinates the activity of these various regions.

The fractionation of working memory

In performing many complex tasks, it is necessary to hold information in temporary storage to complete the task. The system used for this is referred to as working memory. Evidence for the need to postulate separable memory systems is summarized, and one particular model of working memory is described, together with its fractionation into three principal subsystems. The model has proved durable and useful and, with the development of electrophysiological and positive emission tomography scanning measures, is proving to map readily onto recent neuroanatomical developments.