Differential contributions of the two cerebral hemispheres to temporal and spectral speech feedback control.

Proper speech production requires auditory speech feedback control. Models of speech production associate this function with the right cerebral hemisphere while the left hemisphere is proposed to host speech motor programs. However, previous studies have investigated only spectral perturbations of the auditory speech feedback. Since auditory perception is known to be lateralized, with right-lateralized analysis of spectral features and left-lateralized processing of temporal features, it is unclear whether the observed right-lateralization of auditory speech feedback processing reflects a preference for speech feedback control or for spectral processing in general. Here we use a behavioral speech adaptation experiment with dichotically presented altered auditory feedback and an analogous fMRI experiment with binaurally presented altered feedback to confirm a right hemisphere preference for spectral feedback control and to reveal a left hemisphere preference for temporal feedback control during speaking. These results indicate that auditory feedback control involves both hemispheres with differential contributions along the spectro-temporal axis.

Subcortical nuclei volumes are associated with cognition in children post-convulsive status epilepticus: Results at nine years follow-up.

PURPOSE: The purpose of the present study was to investigate the relationship between subcortical nuclei volume and cognition in children with post-convulsive status epilepticus (CSE). METHODS: Structural T1-weighted magnetic resonance imaging (MRI) scans (Siemens Avanto, 1.5 T) and neuropsychological assessments (full-scale intelligence quotient (FSIQ) and Global Memory Scores (GMS)) were collected from subjects at a mean 8.5 years post-CSE (prolonged febrile seizures (PFS), n = 30; symptomatic/known, n = 28; and other, n = 12) and from age- and sex-matched healthy controls (HC). Subjects with CSE were stratified into those with lower cognitive ability (LCA) (CSE+, n = 22) and those without (CSE-, n = 48). Quantitative volumetric analysis using Functional MRI of the Brain Software Library (FSL) (Analysis Group, FMRIB, Oxford) provided segmented MRI brain volumes. Univariate analysis of covariance (ANCOVA) was performed to compare subcortical nuclei volumes across subgroups. Multivariable linear regression was performed for each subcortical structure and for total subcortical volume (SCV) to identify significant predictors of LCA (FSIQ <85) while adjusting for etiology, age, socioeconomic status, sex, CSE duration, and intracranial volume (ICV); Bonferroni correction was applied for the analysis of individual subcortical nuclei. RESULTS: Seventy subjects (11.8 ±â€¯3.4 standard deviation (SD) years; 34 males) and 72 controls (12.1 ±â€¯3.0SD years; 29 males) underwent analysis. Significantly smaller volumes of the left thalamus, left caudate, right caudate, and SCV were found in subjects with CSE+ compared with HC, after adjustment for intracranial, gray matter (GM), or cortical/cerebellar volume. When compared with subjects with CSE-, subjects with CSE+ also had smaller volumes of the left thalamus, left pallidum, right pallidum, and SCV. Individual subcortical nuclei were not associated, but SCV was associated with FSIQ (p = 0.005) and GMS (p = 0.014). Intracranial volume and etiology were similarly predictive. CONCLUSIONS: Nine years post-CSE, SCV is significantly lower in children who have LCA compared with those that do not. However, in this cohort, we are unable to determine whether the relationship is independent of ICV or etiology. Future, larger scale studies may help tease this out.

Differential contributions of the two human cerebral hemispheres to action timing.

Rhythmic actions benefit from synchronization with external events. Auditory-paced finger tapping studies indicate the two cerebral hemispheres preferentially control different rhythms. It is unclear whether left-lateralized processing of faster rhythms and right-lateralized processing of slower rhythms bases upon hemispheric timing differences that arise in the motor or sensory system or whether asymmetry results from lateralized sensorimotor interactions. We measured fMRI and MEG during symmetric finger tapping, in which fast tapping was defined as auditory-motor synchronization at 2.5 Hz. Slow tapping corresponded to tapping to every fourth auditory beat (0.625 Hz). We demonstrate that the left auditory cortex preferentially represents the relative fast rhythm in an amplitude modulation of low beta oscillations while the right auditory cortex additionally represents the internally generated slower rhythm. We show coupling of auditory-motor beta oscillations supports building a metric structure. Our findings reveal a strong contribution of sensory cortices to hemispheric specialization in action control.

Interhemispherically dynamic representation of an eye movement-related activity in mouse frontal cortex.

Cortical plasticity is fundamental to motor recovery following cortical perturbation. However, it is still unclear how this plasticity is induced at a functional circuit level. Here, we investigated motor recovery and underlying neural plasticity upon optogenetic suppression of a cortical area for eye movement. Using a visually-guided eye movement task in mice, we suppressed a portion of the secondary motor cortex (MOs) that encodes contraversive eye movement. Optogenetic unilateral suppression severely impaired contraversive movement on the first day. However, on subsequent days the suppression became inefficient and capability for the movement was restored. Longitudinal two-photon calcium imaging revealed that the regained capability was accompanied by an increased number of neurons encoding for ipsiversive movement in the unsuppressed contralateral MOs. Additional suppression of the contralateral MOs impaired the recovered movement again, indicating a compensatory mechanism. Our findings demonstrate that repeated optogenetic suppression leads to functional recovery mediated by the contralateral hemisphere.

Epilepsia, Mozart y su sonata K.448: ¿es terapéutico el "efecto Mozart"? / Epilepsy, Mozart and his sonata K.448: is the 'Mozart effect' therapeutic?

Objetivos. Presentar una revisión del denominado "efecto Mozart", explicar por qué se eligió a Mozart y su sonata K.448, y repasar la bibliografía disponible sobre el tratamiento de la epilepsia con la citada sonata. Desarrollo. Existe abundante bibliografía sobre los mecanismos cerebrales que nos permiten percibir, procesar y responder al estímulo musical. También se ha demostrado la plasticidad cerebral que, en especial el adiestramiento musical, desencadena. El «efecto Mozart» se planteó a raíz de la comprobación de que la audición de la sonata K.448 mejoraba habilidades cognitivas, pero el hecho de que esos resultados se puedan deber no a la música en sí, sino a que el oyente aumente su nivel de alerta o disfrute con ella, generó controversia. En este contexto de debate se publicó un volumen importante de estudios sobre el «efecto Mozart» en el campo de la epilepsia, que se repasan en este trabajo. Conclusiones. El «efecto Mozart» tiene base científica, pero su propia naturaleza limita la calidad metodológica de los estudios. La música de Mozart, elegida por su exquisita estructura, ha podido aumentar aún más la polémica porque también resulta del gusto de una gran mayoría. Aún está lejos de consolidarse como tratamiento antiepiléptico no farmacológico, pero podría aumentar la evidencia científica con estudios cuyo diseño minimice los factores de confusión citados (AU)

Aims. To present a review of the so-called 'Mozart effect', to explain why Mozart and his sonata K.448 were chosen, and to review the available literature on the treatment of epilepsy with that sonata. Development. Profuse literature exists on the cerebral mechanisms that allow us to perceive, process and respond to the musical stimulus. Cerebral plasticity, especially in people with musical training, has also been demonstrated. The 'Mozart effect' arose from the finding that hearing the sonata K.448 improved cognitive abilities, but the fact that these results may be due not to the music itself but to the listener increasing arousal or enjoyment generated controversy. In this context of debate, a large number of papers about the 'Mozart effect' in the field of epilepsy were published, and are reviewed in this work. Conclusions. The ‘Mozart effect’ has a scientific basis but its nature limits the methodological quality of the research. The music of Mozart, chosen for its exquisite structure, has been able to increase even more the controversy because also it is of the taste of a great majority. It is still far from being consolidated as a non-pharmacological antiepileptic treatment, but it could increase the scientific evidence with studies whose design minimizes the cited confounding factors (AU)

PLP1 Gene Variation Modulates Leftward and Rightward Functional Hemispheric Asymmetries.

Molecular neurobiological factors determining corpus callosum physiology and anatomy have been suggested to be one of the major factors determining functional hemispheric asymmetries. Recently, it was shown that allelic variations in two myelin-related genes, the proteolipid protein 1 gene PLP1 and the contactin 1 gene CNTN1, are associated with differences in interhemispheric integration. Here, we investigated whether three single nucleotide polymorphisms that were associated with interhemispheric integration via the corpus callosum in a previous study also are relevant for functional hemispheric asymmetries. To this end, we tested more than 900 healthy adults with the forced attention dichotic listening task, a paradigm to assess language lateralization and its modulation by cognitive control processes. Moreover, we used the line bisection task, a paradigm to assess functional hemispheric asymmetries in spatial attention. We found that a polymorphism in PLP1, but not CNTN1, was associated with performance differences in both tasks. Both functional hemispheric asymmetries and their modulation by cognitive control processes were affected. These findings suggest that both left and right hemisphere dominant cognitive functions can be modulated by allelic variation in genes affecting corpus callosum structure. Moreover, higher order cognitive processes may be relevant parameters when investigating the molecular basis of hemispheric asymmetries.

Reproducción y cerebro. I. Bases morfofuncionales del control cerebral: avances y dilemas / Reproduction and brain. I Morphofunctional basis of brain control: advances and therapeutical implications

Desde hace muchos años se considera que el control de la reproducción radica en el cerebro y que el hipotálamo es la región del SNC directamente implicada en esta función. Clásicamente se había descrito un eje hipotálamo-hipofisario-gonadal encargado de controlar la función reproductora. Los avances de los últimos años confirman este concepto, pero se está demostrando que existe una mayor dependencia del eje al estar íntimamente conectado con el resto del SNC, con otros ejes reguladores hipotalámicos (energía y metabolismo, medio líquido interno, control simpático y parasimpático, estrés, hormonas, etc) y con el resto del organismo. Se reciben, además, de manera directa o indirecta, informaciones nerviosas y moleculares del medio interno y de situaciones del medio externo con mayor amplitud y selectividad que lo anteriormente descrito. Las amplias interconexiones que cada vez se van poniendo más de manifiesto (entre los núcleos y neuronas no secretoras y secretoras del hipotálamo; entre éstas neuronas y las extrahipotalámicas; y entre los ejes funcionales descritos), hacen cada vez más difícil describir con exactitud la base morfofuncional de cada individuo de cada especie en cada situación (sexo, edad, estadio del ciclo reproductivo, condiciones externas y externas), máxime cuando existen enormes capacidades de adaptación de las células y los sistemas funcionales. Las neuronas descritas en los últimos años relacionadas con la reproducción son las neuronas secretoras de GnRH, GnIH y Kisspeptina (neuronas productoras de la hormona liberadora de gonadotropina, la hormona inhibidora de las neuronas GnRH y las neuronas reguladoras de GnRH mediante el péptido Kisspeptina), pero todavía se desconoce si existen otros péptidos reguladores de las gonadotropinas hipofisarias así como de otras neuronas (o péptidos) que producen factores controladores de estas neuronas. Sí se sabe que estas neuronas están formadas por subconjuntos que pueden secretar otras substancias y/o ser reguladas de diferente manera. La gran variabilidad de las conexiones sinápticas y la secreción de neuropéptidos parece indicar que es necesario conocer la ‘modalidad funcional’ específica (o cuadro éspecífico de una situación en un individuo de una especie) más que las células intervinientes en un proceso. La compleja interrelación de los subtipos morfofuncionales de las neuronas secretoras y no secretoras de los diferentes núcleos o áreas del hipotálamo relacionadas con la reproducción plantea dudas sobre la actuación terapéutica. Posibles tratamientos farmacológicos y no farmacológicos, estimulando ‘específicamente’ algunos tipos neuronales, pueden tener consecuencias adversas al desestimar conexiones colaterales a otros sistemas o desconocer la existencia de neuronas de un subtipo en otras ‘vía’ o ‘ejes’ funcionales del hipotálamo, con lo que se podrían inducir fenómenos secundarios de gran transcendencia (AU)

For many years, the control of reproduction has been considered a brin function, being the hypothalamus the CNS region directly involved. The main neurons described in recent years related to reproduction are the secretory neurons of GnRH, GnIH and Kisspeptine (gonadotropin-releasing hormone; the gonadotropin-inhibitory hormone and by the peptide Kisspeptine- GnRH regulatory neurons), but it is still unknown whether other pituitary gonadotropin regulatory peptides exist as well as other neurons (or peptides) that produce regulatory factors for these neurons. It is known that these neurons are formed by subsets that can secrete other substances and/or be regulated in different ways. The great variability of the synaptic connections and the secretion of neuropeptides seem to indicate that it is necessary to know the specific ’functional modality’ (or specific picture of a situation in an individual of a species) rather than the cells involved in a process. The complex interrelationship of the morphofunctional subtypes of secretory and non-secreting neurons of the different nuclei or areas of the hypothalamus related to reproduction raises doubts about the therapeutic performance. Possible pharmacological and non-pharmacological treatments, specifically stimulating some neuronal types, may have important side effects by disregarding collateral connections to other systems or by ignoring the existence of neurons of a subtype in other functional ‘axes’ of the hypothalamus (AU)

Una nueva vacuna: la vacuna del autoconocimiento. Bases neurobiológicas de la conducta humana. El juego entre el cerebro instintivo-emocional y el cerebro racional / A new vaccine: vaccine for self-knowledge. Neurobiological base of human behavior. The game between the instinctive-emocional brain and the rational brain

¿Por qué nos comportamos como nos comportamos? ¿Por qué repetimos conductas que sabemos nos hacen daño o hacen daño a otro? Detrás de toda conducta humana, hay un cerebro. Un cerebro, cuya función principal es velar por la supervivencia individual y de grupo. El sistema instintivo emocional (cerebro reptiliano y cerebro límbico) es la parte del cerebro que se encarga de esta función, dando lugar a conductas impulsivas, inconscientes, automáticas y rápidas, en ocasiones, dañinas. La neocorteza (en concreto, los lóbulos prefrontales) es la parte del cerebro que se encarga de las conductas más reflexivas y humanas. Pero esta zona necesita más tiempo para analizar toda la información entrante. Por lo tanto, para que la neocorteza guíe nuestras conductas es imprescindible educar al cerebro y dotarle de herramientas que le permitan modular y gestionar los primeros impulsos procedentes del sistema instintivo emocional. Todo educador (padres, profesores, pediatras) debe conocer cómo funciona el cerebro para así dotar al niño de habilidades socioemocionales que le permitan actuar bajo el mandato de los lóbulos prefrontales (AU)

Why do we behave as we behave? Why do we repeat behaviors that we know hurt us or harm others? There is a brain behind all human behavior. A brain, whose main function is to ensure the survival of the individual and group. Instinctive emotional system (reptilian and limbic brain) is the part of the brain that is responsible for this function, resulting in rapid, automatic, unconscious, and impulsive behaviors sometimes, harmful. The neocortex (specifically the pre-frontal lobes), is the part of the brain that is responsible for the more reflexive and human behaviors. But, this area needs more time to analyze incoming information. Therefore, is essential to educate the brain and provide tools that allow us manage first impulses from the instinctive emotional system. All Educator (parents, teachers, pediatricians) must know how the brain works to provide the child’s socio-emotional skills enabling them to act under the mandate of the prefrontal lobes (AU)

Decoding four different sound-categories in the auditory cortex using functional near-infrared spectroscopy.

The ability of the auditory cortex in the brain to distinguish different sounds is important in daily life. This study investigated whether activations in the auditory cortex caused by different sounds can be distinguished using functional near-infrared spectroscopy (fNIRS). The hemodynamic responses (HRs) in both hemispheres using fNIRS were measured in 18 subjects while exposing them to four sound categories (English-speech, non-English-speech, annoying sounds, and nature sounds). As features for classifying the different signals, the mean, slope, and skewness of the oxy-hemoglobin (HbO) signal were used. With regard to the language-related stimuli, the HRs evoked by understandable speech (English) were observed in a broader brain region than were those evoked by non-English speech. Also, the magnitudes of the HbO signals evoked by English-speech were higher than those of non-English speech. The ratio of the peak values of non-English and English speech was 72.5%. Also, the brain region evoked by annoying sounds was wider than that by nature sounds. However, the signal strength for nature sounds was stronger than that for annoying sounds. Finally, for brain-computer interface (BCI) purposes, the linear discriminant analysis (LDA) and support vector machine (SVM) classifiers were applied to the four sound categories. The overall classification performance for the left hemisphere was higher than that for the right hemisphere. Therefore, for decoding of auditory commands, the left hemisphere is recommended. Also, in two-class classification, the annoying vs. nature sounds comparison provides a higher classification accuracy than the English vs. non-English speech comparison. Finally, LDA performs better than SVM.

Auditory intensity processing: Effect of MRI background noise.

Studies on active auditory intensity discrimination in humans showed equivocal results regarding the lateralization of processing. Whereas experiments with a moderate background found evidence for right lateralized processing of intensity, functional magnetic resonance imaging (fMRI) studies with background scanner noise suggest more left lateralized processing. With the present fMRI study, we compared the task dependent lateralization of intensity processing between a conventional continuous echo planar imaging (EPI) sequence with a loud background scanner noise and a fast low-angle shot (FLASH) sequence with a soft background scanner noise. To determine the lateralization of the processing, we employed the contralateral noise procedure. Linearly frequency modulated (FM) tones were presented monaurally with and without contralateral noise. During both the EPI and the FLASH measurement, the left auditory cortex was more strongly involved than the right auditory cortex while participants categorized the intensity of FM tones. This was shown by a strong effect of the additional contralateral noise on the activity in the left auditory cortex. This means a massive reduction in background scanner noise still leads to a significant left lateralized effect. This suggests that the reversed lateralization in fMRI studies with loud background noise in contrast to studies with softer background cannot be fully explained by the MRI background noise.

Hearing it right: Evidence of hemispheric lateralization in auditory imagery.

An advantage of the right ear (REA) in auditory processing (especially for verbal content) has been firmly established in decades of behavioral, electrophysiological and neuroimaging research. The laterality of auditory imagery, however, has received little attention, despite its potential relevance for the understanding of auditory hallucinations and related phenomena. In Experiments 1-4 we find that right-handed participants required to imagine hearing a voice or a sound unilaterally show a strong population bias to localize the self-generated auditory image at their right ear, likely the result of left-hemispheric dominance in auditory processing. In Experiments 5-8 - by means of the same paradigm - it was also ascertained that the right-ear bias for hearing imagined voices depends just on auditory attention mechanisms, as biases due to other factors (i.e., lateralized movements) were controlled. These results, suggesting a central role of the left hemisphere in auditory imagery, demonstrate that brain asymmetries can drive strong lateral biases in mental imagery.

Interhemispheric transcallosal connectivity between the left and right planum temporale predicts musicianship, performance in temporal speech processing, and functional specialization.

Currently, there is strong evidence showing that musicianship favours functional and structural changes of the left planum temporale (PT), and that these cortical reorganizations facilitate the discrimination of temporal speech cues. Based on the proposition of a division of labour between the left and right PT, here we postulated that the musicians' advantage in processing temporal speech cues and PT specialization origin, at least in part, from increased white matter connectivity between the two auditory-related cortices. In particular, we assume that increased transcallosal PT connectivity might promote functional specialization and asymmetry of homotopic brain regions. With this purpose in mind, we applied diffusion tensor imaging and compared axial diffusivity (AD), radial diffusivity (RD), and fractional anisotropy (FA) of the interhemispheric connection between the left and right PT in thirteen musicians and 13 nonmusicians. Furthermore, in the form of an addendum, we integrated cortical surface area values and blood oxygenation level dependent (BOLD) responses of the left PT that were collected in the context of two previous studies conducted with the same sample of subjects. Our results indicate increased connectivity between the left and right PT in musicians compared to nonmusicians, as indexed by reduced mean RD. We did not find significant between-group differences in FA and AD. Most notably, RD was related to the performance in the phonetic categorization task, musical aptitudes, as well as to BOLD responses in the left PT. Hence, we provide first evidence for a relationship between PT connectivity, musicianship, and phonetic categorization.

[Motion-Onset Responses During Active and Passive Listening to the Moving Sound Stimuli].

This study investigated the energy-onset and motion-onset responses (N1, P2, cN 1 and cP2 components of the auditory evoked potential) elicited by moving sound stimuli in the passive and active listening conditions. In the passive conditions the subjects were distracted from auditory information; in active conditions they lo- calized the starting and final points of the stimulus trajectory. The sound movement to the left/right from the head midline was produced by linear-changes of the interaural time delay (ITD). The onset of motion was preceded by stationary sound located near the head midline. In the active conditions, the NI component was higher and the P2 component was higher and peaked later as compared to the passive listening. The early and later parts of the motion-onset response (cN 1 and cP2) also were larger in magnitude and peaked later during active listening. Both in active and passive conditions, cNI and cP2 amplitude exhibited increase and latency showed decrease when the stimulus velocity increased. Contralateral asymmetry was found only in the mo- tion-onset responses recorded from the left hemisphere.

[Delayed Copying of Unfamiliar Contour Shapes: Analysis of Potentials Related to Stimuli].

The high-density EEG was recorded and ERPs related to showing unfamiliar contour shapes and delivering imperative signal (a short sound) were estimated in the task requiring delayed motor reproduction of these shapes. A total of 22 right-handed adults participated in the experiment. They performed 5-blocks of trials corresponding-to 5 different delays (T= 0; 500, 1000, 2000 4000 ms) between the imperative signal relative to the end of the contour trajectory presentation. An ERP analysis showed that, unlike ERPs related to the contour shape presentation, those related to the imperative signal delivery do change with growing delay T. A subsequent analysis of cortical sources of the ERPs related to the imperative stimulus showed corresponding pronounced grows of reactivity of orbito-frontal cortex of the right hemisphere and a symmetrical bilateral grows of reactivity of dorsal parts of the sensorimotor cortex. The reported findings are discussed in the framework of the proposal according to which the internal representation of a trajectory undergoes a transi- tion from a sensory-specific format towards more abstract neither sensory- nor motor-specific format.

Binaural beats increase interhemispheric alpha-band coherence between auditory cortices.

Binaural beats (BBs) are an auditory illusion occurring when two tones of slightly different frequency are presented separately to each ear. BBs have been suggested to alter physiological and cognitive processes through synchronization of the brain hemispheres. To test this, we recorded electroencephalograms (EEG) at rest and while participants listened to BBs or a monaural control condition during which both tones were presented to both ears. We calculated for each condition the interhemispheric coherence, which expressed the synchrony between neural oscillations of both hemispheres. Compared to monaural beats and resting state, BBs enhanced interhemispheric coherence between the auditory cortices. Beat frequencies in the alpha (10 Hz) and theta (4 Hz) frequency range both increased interhemispheric coherence selectively at alpha frequencies. In a second experiment, we evaluated whether this coherence increase has a behavioral aftereffect on binaural listening. No effects were observed in a dichotic digit task performed immediately after BBs presentation. Our results suggest that BBs enhance alpha-band oscillation synchrony between the auditory cortices during auditory stimulation. This effect seems to reflect binaural integration rather than entrainment.

[The Influence of Long-Term Meditation Practice on Early Emotional Processing in the Brain: an ERP Study].

The main aim was to study effects of long-term meditation practice on event-related brain potentials (ERPs) during affective picture viewing. The meditators' (N = 20), contrary to control (N = 20), did not demonstrate arousal-related increases in the mid-latency (200-400 ms) ERP positivity over the right hemisphere. We also found in the same time window stronger ERP negativity for meditators over central regions, regardless of picture valence. We assume that long-term meditation practice enhances frontal top-down control over fast automatic detection of stimulus salience.

Brain networks governing the golf swing in professional golfers.

Golf, as with most complex motor skills, requires multiple different brain functions, including attention, motor planning, coordination, calculation of timing, and emotional control. In this study we assessed the correlation between swing components and brain connectivity from the cerebellum to the cerebrum. Ten female golf players and 10 age-matched female controls were recruited. In order to determine swing consistency among participants, the standard deviation (SD) of the mean swing speed time and the SD of the mean swing angle were assessed over 30 swings. Functional brain connectivity was assessed by resting state functional MRI. Pro-golfers showed greater positive left cerebellum connectivity to the occipital lobe, temporal lobe, parietal lobe and both frontal lobes compared to controls. The SD of play scores was positively correlated with the SD of the impact angle. Constant swing speed and back swing angle in professional golfers were associated with functional connectivity (FC) between the cerebellum and parietal and frontal lobes. In addition, the constant impact angle in professional golfers was associated with improved golf scores and additional FC of the thalamus.

[Comparison of electroencephalogram changes at cardiovascular training in adolescents of subpolar and polar northern territories].

The features of the electroencephalogram (EEG) at the heart rate variability single biofeedback session in adolescents aged 15-17 years living in the subpolar and polar northern regions were determined. In adolescents of the subpolar region identified shaped age EEG pattern. We have established higher diencephalic and subcortical brain structures activity manifested in the elevated theta-activity levels and the diffuse photic driving reactions in adolescents of the polar region than in adolescents of subpolar region. In the dynamics of the biofeedback sessions in both regions there were identified groups of persons with both increased alpha-activity spectral power and decreased of it. After biofeedback sessions in adolescents of polar region more prolonged increase of alpha-activity, more pronounced reduction of theta-activity and the photic driving reactions were revealed. Changes in EEG patterns are most characteristic of the right brain hemisphere involving the frontal brain areas.

The persistent crucial role of the left hemisphere for language in left-handers with a left low grade glioma: a stimulation mapping study.

BACKGROUND: Left-handers have a more bilateral language representation than right-handers. Therefore, in left-handers with a low-grade glioma (LGG) in the left hemisphere (LH), one could hypothesize that the right hemisphere (RH) might allow language compensation, at least partly, with no or only a minor persistent role of the LH in speech. However, although LGG induces language reorganization in right-handed patients, little is known in left-handers. Here, we report the first series of left-handers who underwent awake surgery for a left LGG using intraoperative mapping, in order to investigate whether there was still an involvement of LH in language. METHOD: Ten consecutive left-handed patients were operated for a left LGG (three frontal, four paralimbic, one parietal, one temporal, one parieto-temporal tumor) using an awake procedure with intraoperative electrical language mapping. RESULTS: Intraoperative language disorders were elicited in all cases but one by electrostimulation in the LH. Cortical language sites were detected in nine cases. Subcortical stimulation also demonstrated the crucial role of left white matter pathways in language, including the inferior occipital-frontal fascicle, arcuate fascicle, lateral segment of the superior longitudinal fascicle and fibers from the ventral premotor cortex. Moreover, stimulation of deep gray nuclei generated language disturbances in four patients. These nine patients experienced transient postoperative language worsening, supporting the persistent critical role of LH in speech. In only one patient, no language deficit was evoked intraoperatively and postoperatively. The ten patients returned to a normal life. Total or subtotal resection was achieved in all cases but one. CONCLUSIONS: Our results suggest that, even though the RH may participate in language compensation, the LH in left-handers still plays a crucial role, despite a left slow-growing LGG. Thus, we propose to routinely consider awake surgery for left LGG removal in left-handers patients, to optimize the extent of resection while preserving language.

Sound-sensitive neurons innervate the ventro-lateral protocerebrum of the heliothine moth brain.

Many noctuid moth species perceive ultrasound via tympanic ears that are located at the metathorax. Whereas the neural processing of auditory information is well studied at the peripheral and first synaptic level, little is known about the features characterizing higher order sound-sensitive neurons in the moth brain. During intracellular recordings from the lateral protocerebrum in the brain of three noctuid moth species, Heliothis virescens, Helicoverpa armigera and Helicoverpa assulta, we found an assembly of neurons responding to transient sound pulses of broad bandwidth. The majority of the auditory neurons ascended from the ventral cord and ramified densely within the anterior region of the ventro-lateral protocerebrum. The physiological and morphological characteristics of these auditory neurons were similar. We detected one additional sound-sensitive neuron, a brain interneuron with its soma positioned near the calyces of mushroom bodies and with numerous neuronal processes in the ventro-lateral protocerebrum. Mass-staining of ventral-cord neurons supported the assumption that the ventro-lateral region of the moth brain was the main target for the auditory projections ascending from the ventral cord.