Neuroscience: Boosting the brain.

A therapeutic effect of vagus nerve stimulation has been reported for a wide range of neurological, medical and psychiatric conditions. New research provides evidence that this effect results from extensive increase of physiological arousal and brain activation.

Anatomical bases of fast parietal grasp control in humans: A diffusion-MRI tractography study.

The dorso-posterior parietal cortex (DPPC) is a major node of the grasp/manipulation control network. It is assumed to act as an optimal forward estimator that continuously integrates efferent outflows and afferent inflows to modulate the ongoing motor command. In agreement with this view, a recent per-operative study, in humans, identified functional sites within DPPC that: (i) instantly disrupt hand movements when electrically stimulated; (ii) receive short-latency somatosensory afferences from intrinsic hand muscles.

Cerebellar lesions at a young age predict poorer long-term functional recovery.

Early studies on long-term functional recovery after motor and premotor lesions showed better outcomes in younger monkeys than in older monkeys. This finding led to the widespread belief that brain injuries cause less impairment in children than adults. However, this view has limitations and a large body of evidence now indicates that cerebral damages can be more harmful when inflicted at young age, during critical periods of neural development.

Superstitious beliefs and the associative mind.

Persistence of superstitions in the modern era could be justified by considering them as a by-product of the brain's capacity to detect associations and make assumptions about cause-effect relationships. This ability, which supports predictive behaviour, directly relates to associative learning. We tested whether variability in superstitious behaviour reflects individual variability in the efficiency of mechanisms akin to habit learning.

Awake brain surgery in children-review of the literature and state-of-the-art.

Objective: Awake brain surgery (ABS) is poorly reported in children as it is considered having limited indications due to age and neuropsychological aspects interfering with its feasibility and psychological outcome. The aim of this article is to review the current state-of-the-art of ABS in children and to offer an objective summary of the published literature on diversified outcome aspects of pediatric awake procedures.

Methods: A literature review was performed using the MEDLINE (PubMed) electronic database applying the following MeSH terms to the keyword search within titles and abstracts: "awake brain surgery children," "awake brain surgery pediatric," "awake craniotomy children," "awake craniotomy pediatric," and "awake surgery children.

How did I get so late so soon? A review of time processing and management in autism.

While the definition of Autism Spectrum Disorder (ASD) does not include any explicit criteria concerning difficulties of time perception or management, there is growing evidence of atypical temporal perception in individuals with ASD. This review synthesizes the evidence and gaps of the current literature on time processing in ASD. After a brief overview of clinical findings and available assessment tools, we synthetize outcomes of studies evaluating time perception at second and infra-second level, and then, recent literature on the circadian timing system.

Psychological aspects of awake brain surgery in children-interests and risks.

Awake brain surgery (ABS) in children remains a subject of controversial debate for the potential psychological limitations that are related to this type of procedure. However, the tolerance and benefits of ABS in adults advocate for increased application of ABS in children. In this study, we report the psychological assessment, evaluation algorithm, and outcome of pediatric patients, who underwent ABS for surgical treatment of lesions in eloquent areas.

Willingness towards cognitive engagement: a preliminary study based on a behavioural entropy approach.

Faced with a novel task some people enthusiastically embark in it and work with determination, while others soon lose interest and progressively reduce their efforts. Although cognitive neuroscience has explored the behavioural and neural features of apathy, the why's and how's of positive engagement are only starting to be understood. Stemming from the observation that the left hemisphere is commonly associated to a proactive ('do something') disposition, we run a preliminary study exploring the possibility that individual variability in eagerness to engage in cognitive tasks could reflect a preferred left- or right-hemisphere functioning mode.

Selective Inhibition of Volitional Hand Movements after Stimulation of the Dorsoposterior Parietal Cortex in Humans.

Inhibition is a central component of motor control. Although current models emphasize the involvement of frontal networks [1, 2], indirect evidence suggests a potential contribution of the posterior parietal cortex (PPC). This region is active during inhibition of upper-limb movements to undesired targets [3], and its stimulation with single magnetic pulses can depress motor-evoked potentials [4, 5].

Restoring consciousness with vagus nerve stimulation.

Patients lying in a vegetative state present severe impairments of consciousness [1] caused by lesions in the cortex, the brainstem, the thalamus and the white matter [2]. There is agreement that this condition may involve disconnections in long-range cortico-cortical and thalamo-cortical pathways [3]. Hence, in the vegetative state cortical activity is 'deafferented' from subcortical modulation and/or principally disrupted between fronto-parietal regions.

Revealing humans' sensorimotor functions with electrical cortical stimulation.

Direct electrical stimulation (DES) of the human brain has been used by neurosurgeons for almost a century. Although this procedure serves only clinical purposes, it generates data that have a great scientific interest. Had DES not been employed, our comprehension of the organization of the sensorimotor systems involved in movement execution, language production, the emergence of action intentionality or the subjective feeling of movement awareness would have been greatly undermined.

Dissociable contribution of the parietal and frontal cortex to coding movement direction and amplitude.

To reach for an object, we must convert its spatial location into an appropriate motor command, merging movement direction and amplitude. In humans, it has been suggested that this visuo-motor transformation occurs in a dorsomedial parieto-frontal pathway, although the causal contribution of the areas constituting the "reaching circuit" remains unknown. Here we used transcranial magnetic stimulation (TMS) in healthy volunteers to disrupt the function of either the medial intraparietal area (mIPS) or dorsal premotor cortex (PMd), in each hemisphere.

Movement-related discharge in the macaque globus pallidus during high-frequency stimulation of the subthalamic nucleus.

Deep brain stimulation (DBS) of the subthalamic nucleus (STN-DBS) has largely replaced ablative therapies for Parkinson's disease. Because of the similar efficacies of the two treatments, it has been proposed that DBS acts by creating an "informational lesion," whereby pathologic neuronal firing patterns are replaced by low-entropy, stimulus-entrained firing patterns. The informational lesion hypothesis, in its current form, states that DBS blocks the transmission of all information from the basal ganglia, including both pathologic firing patterns and normal, task-related modulations in activity.

The dorsal medial frontal cortex mediates automatic motor inhibition in uncertain contexts: evidence from combined fMRI and EEG studies.

Response inhibition is commonly thought to rely on voluntary, reactive, selective, and relatively slow prefrontal mechanisms. In contrast, we suggest here that response inhibition is achieved automatically, nonselectively, within very short delays in uncertain environments. We modified a classical go/nogo protocol to probe context-dependent inhibitory mechanisms.

Neural representations of ethologically relevant hand/mouth synergies in the human precentral gyrus.

Complex motor responses are often thought to result from the combination of elemental movements represented at different neural sites. However, in monkeys, evidence indicates that some behaviors with critical ethological value, such as self-feeding, are represented as motor primitives in the precentral gyrus (PrG). In humans, such primitives have not yet been described.

Re-establishing the merits of electrical brain stimulation.

During the past decades, direct electrical stimulation (DES) has been a key method not only in determining the organization of brain networks mediating movement, language, and cognition but also in establishing many central concepts of modern neuroscience, such as the electrical nature of neural transmission, the localization of brain functions, and the homuncular arrangement of sensorimotor areas. However, recent criticisms have questioned the utility of DES and argued that data collected with this technique may be flawed and unreliable. As with every other neuroscientific method, DES does have limitations.

Searching for the neural correlates of conscious intention.

It is typically assumed that the conscious experience of wanting to move is not the driving force for motor planning, but the secondary consequence of the unconscious neural processes preparing the movement. A recent study by Schneider et al. [Schneider, L.

A common optimization principle for motor execution in healthy subjects and parkinsonian patients.

Recent research on Parkinson's disease (PD) has emphasized that parkinsonian movement, although bradykinetic, shares many attributes with healthy behavior. This observation led to the suggestion that bradykinesia in PD could be due to a reduction in motor motivation. This hypothesis can be tested in the framework of optimal control theory, which accounts for many characteristics of healthy human movement while providing a link between the motor behavior and a cost/benefit trade-off.

Mapping motor representations in the human cerebellum.

The cerebellum is a major motor structure. However, in humans, its efferent topographical organization remains controversial and indirectly inferred from neuroimaging and animal studies. Even central questions such as 'Can we evoke limb movements by stimulating the cerebellar cortex?' have no clear answer.

Conscious motor intention emerges in the inferior parietal lobule.

Willed actions are characterized by the subjective experience of 'conscious intention'. During the last decade the neural bases of this experience have been widely investigated. Previous findings have suggested that conscious intention emerges in the mesial precentral area (MPA) including the supplementary and pre-supplementary motor area.

When one size does not fit all: a simple statistical method to deal with across-individual variations of effects.

In science, it is a common experience to discover that although the investigated effect is very clear in some individuals, statistical tests are not significant because the effect is null or even opposite in other individuals. Indeed, t-tests, Anovas and linear regressions compare the average effect with respect to its inter-individual variability, so that they can fail to evidence a factor that has a high effect in many individuals (with respect to the intra-individual variability). In such paradoxical situations, statistical tools are at odds with the researcher's aim to uncover any factor that affects individual behavior, and not only those with stereotypical effects.

Recognition of self-generated facial emotions is impaired in schizophrenia.

Individuals with schizophrenia have difficulties in recognizing facial emotions in others. This study investigated whether this impairment also exists for self-generated expressions. Nineteen patients with schizophrenia and 19 comparison subjects were filmed while producing facial expressions in response to a visual model or a written sentence.

Basal ganglia contributions to motor control: a vigorous tutor.

The roles of the basal ganglia (BG) in motor control are much debated. Many influential hypotheses have grown from studies in which output signals of the BG were not blocked, but pathologically disturbed. A weakness of that approach is that the resulting behavioral impairments reflect degraded function of the BG per se mixed together with secondary dysfunctions of BG-recipient brain areas.