The effects of TMS over dorsolateral prefrontal cortex on trans-saccadic memory of multiple objects

Humans typically make several rapid eye movements (saccades) per second. It is thought that visual working memory can retain and spatially integrate three to four objects or features across each saccade but little is known about this neural mechanism. Previously we showed that transcranial magnetic stimulation (TMS) to the posterior parietal cortex and frontal eye fields degrade trans-saccadic memory of multiple object features (Prime, Vesia, & Crawford, 2008, Journal of Neuroscience, 28(27), 6938-6949; Prime, Vesia, & Crawford, 2010, Cerebral Cortex, 20(4), 759-772.). Here, we used a similar protocol to investigate whether dorsolateral prefrontal cortex (DLPFC), an area involved in spatial working memory, is also involved in trans-saccadic memory. Subjects were required to report changes in stimulus orientation with (saccade task) or without (fixation task) an eye movement in the intervening memory interval. We applied single-pulse TMS to left and right DLPFC during the memory delay, timed at three intervals to arrive approximately 100ms before, 100ms after, or at saccade onset. In the fixation task, left DLPFC TMS produced inconsistent results, whereas right DLPFC TMS disrupted performance at all three intervals (significantly for presaccadic TMS). In contrast, in the saccade task, TMS consistently facilitated performance (significantly for left DLPFC/perisaccadic TMS and right DLPFC/postsaccadic TMS) suggesting a dis-inhibition of trans-saccadic processing. These results are consistent with a neural circuit of trans-saccadic memory that overlaps and interacts with, but is partially separate from the circuit for visual working memory during sustained fixation.

The role of the right parietal cortex in sound localization: a chronometric single pulse transcranial magnetic stimulation study.

Auditory spatial functions, including the ability to discriminate between the positions of nearby sound sources, are subserved by a large temporo-parieto-frontal network. With the aim of determining whether and when the parietal contribution is critical for auditory spatial discrimination, we applied single pulse transcranial magnetic stimulation on the right parietal cortex 20, 80, 90 and 150 ms post-stimulus onset while participants completed a two-alternative forced choice auditory spatial discrimination task in the left or right hemispace. Our results reveal that transient TMS disruption of right parietal activity impairs spatial discrimination when applied at 20 ms post-stimulus onset for sounds presented in the left (controlateral) hemispace and at 80 ms for sounds presented in the right hemispace. We interpret our finding in terms of a critical role for controlateral temporo-parietal cortices over initial stages of the building-up of auditory spatial representation and for a right hemispheric specialization in integrating the whole auditory space over subsequent, higher-order processing stages.

Frontal Lobe Function and Performance Monitoring following Total Sleep Deprivation

Imaging studies have shown reduced frontal lobe resources following total sleep deprivation (TSD). The anterior cingulate cortex (ACC) in the frontal region plays a role in performance monitoring and cognitive control; both error detection and response inhibition are impaired following sleep loss. Event-related potentials (ERPs) are an electrophysiological tool used to index the brain's response to stimuli and information processing. In the Flanker task, the error-related negativity (ERN) and error positivity (Pe) ERPs are elicited after erroneous button presses. In a Go/NoGo task, NoGo-N2 and NoGo-P3 ERPs are elicited during high conflict stimulus processing. Research investigating the impact of sleep loss on ERPs during performance monitoring is equivocal, possibly due to task differences, sample size differences and varying degrees of sleep loss. Based on the effects of sleep loss on frontal function and prior research, it was expected that the sleep deprivation group would have lower accuracy, slower reaction time and impaired remediation on performance monitoring tasks, along with attenuated and delayed stimulus- and response-locked ERPs. In the current study, 49 young adults (24 male) were screened to be healthy good sleepers and then randomly assigned to a sleep deprived (n = 24) or rested control (n = 25) group. Participants slept in the laboratory on a baseline night, followed by a second night of sleep or wake. Flanker and Go/NoGo tasks were administered in a battery at 1O:30am (i.e., 27 hours awake for the sleep deprivation group) to measure performance monitoring. On the Flanker task, the sleep deprivation group was significantly slower than controls (p's <.05), but groups did not differ on accuracy. No group differences were observed in post-error slowing, but a trend was observed for less remedial accuracy in the sleep deprived group compared to controls (p = .09), suggesting impairment in the ability to take remedial action following TSD. Delayed P300s were observed in the sleep deprived group on congruent and incongruent Flanker trials combined (p = .001). On the Go/NoGo task, the hit rate (i.e., Go accuracy) was significantly lower in the sleep deprived group compared to controls (p <.001), but no differences were found on false alarm rates (i.e., NoGo Accuracy). For the sleep deprived group, the Go-P3 was significantly smaller (p = .045) and there was a trend for a smaller NoGo-N2 compared to controls (p = .08). The ERN amplitude was reduced in the TSD group compared to controls in both the Flanker and Go/NoGo tasks. Error rate was significantly correlated with the amplitude of response-locked ERNs in control (r = -.55, p=.005) and sleep deprived groups (r = -.46, p = .021); error rate was also correlated with Pe amplitude in controls (r = .46, p=.022) and a trend was found in the sleep deprived participants (r = .39, p =. 052). An exploratory analysis showed significantly larger Pe mean amplitudes (p = .025) in the sleep deprived group compared to controls for participants who made more than 40+ errors on the Flanker task. Altered stimulus processing as indexed by delayed P3 latency during the Flanker task and smaller amplitude Go-P3s during the Go/NoGo task indicate impairment in stimulus evaluation and / or context updating during frontal lobe tasks. ERN and NoGoN2 reductions in the sleep deprived group confirm impairments in the monitoring system. These data add to a body of evidence showing that the frontal brain region is particularly vulnerable to sleep loss. Understanding the neural basis of these deficits in performance monitoring abilities is particularly important for our increasingly sleep deprived society and for safety and productivity in situations like driving and sustained operations.

Réorganisation fonctionnelle et structurale des cortex auditifs, visuels et associatifs chez les sourds profonds congénitaux ou prélinguaux

En raison de l’utilisation d’un mode de communication totalement différent de celui des entendants, le langage des signes, et de l’absence quasi-totale d’afférences en provenance du système auditif, il y a de fortes chances que d’importantes modifications fonctionnelles et structurales s’effectuent dans le cerveau des individus sourds profonds. Les études antérieures suggèrent que cette réorganisation risque d’avoir des répercussions plus importantes sur les structures corticales situées le long de la voie visuelle dorsale qu’à l’intérieur de celles situées à l’intérieur de la voie ventrale. L’hypothèse proposée par Ungerleider et Mishkin (1982) quant à la présence de deux voies visuelles dans les régions occipitales, même si elle demeure largement acceptée dans la communauté scientifique, s’en trouve aussi relativement contestée. Une voie se projetant du cortex strié vers les régions pariétales postérieures, est impliquée dans la vision spatiale, et l’autre se projetant vers les régions du cortex temporal inférieur, est responsable de la reconnaissance de la forme. Goodale et Milner (1992) ont par la suite proposé que la voie dorsale, en plus de son implication dans le traitement de l’information visuo-spatiale, joue un rôle dans les ajustements sensori-moteurs nécessaires afin de guider les actions. Dans ce contexte, il est tout à fait plausible de considérer qu’un groupe de personne utilisant un langage sensori-moteur comme le langage des signes dans la vie de tous les jours, s’expose à une réorganisation cérébrale ciblant effectivement la voie dorsale. L’objectif de la première étude est d’explorer ces deux voies visuelles et plus particulièrement, la voie dorsale, chez des individus entendants par l’utilisation de deux stimuli de mouvement dont les caractéristiques physiques sont très similaires, mais qui évoquent un traitement relativement différent dans les régions corticales visuelles. Pour ce faire, un stimulus de forme définie par le mouvement et un stimulus de mouvement global ont été utilisés. Nos résultats indiquent que les voies dorsale et ventrale procèdent au traitement d’une forme définie par le mouvement, tandis que seule la voie dorsale est activée lors d’une tâche de mouvement global dont les caractéristiques psychophysiques sont relativement semblables. Nous avons utilisé, subséquemment, ces mêmes stimulations activant les voies dorsales et ventrales afin de vérifier quels pourraient être les différences fonctionnelles dans les régions visuelles et auditives chez des individus sourds profonds. Plusieurs études présentent la réorganisation corticale dans les régions visuelles et auditives en réponse à l’absence d’une modalité sensorielle. Cependant, l’implication spécifique des voies visuelles dorsale et ventrale demeure peu étudiée à ce jour, malgré plusieurs résultats proposant une implication plus importante de la voie dorsale dans la réorganisation visuelle chez les sourds. Suite à l’utilisation de l’imagerie cérébrale fonctionnelle pour investiguer ces questions, nos résultats ont été à l’encontre de cette hypothèse suggérant une réorganisation ciblant particulièrement la voie dorsale. Nos résultats indiquent plutôt une réorganisation non-spécifique au type de stimulation utilisé. En effet, le gyrus temporal supérieur est activé chez les sourds suite à la présentation de toutes nos stimulations visuelles, peu importe leur degré de complexité. Le groupe de participants sourds montre aussi une activation du cortex associatif postérieur, possiblement recruté pour traiter l’information visuelle en raison de l’absence de compétition en provenance des régions temporales auditives. Ces résultats ajoutent aux données déjà recueillies sur les modifications fonctionnelles qui peuvent survenir dans tout le cerveau des personnes sourdes, cependant les corrélats anatomiques de la surdité demeurent méconnus chez cette population. Une troisième étude se propose donc d’examiner les modifications structurales pouvant survenir dans le cerveau des personnes sourdes profondes congénitales ou prélinguales. Nos résultats montrent que plusieurs régions cérébrales semblent être différentes entre le groupe de participants sourds et celui des entendants. Nos analyses ont montré des augmentations de volume, allant jusqu’à 20%, dans les lobes frontaux, incluant l’aire de Broca et d’autres régions adjacentes impliqués dans le contrôle moteur et la production du langage. Les lobes temporaux semblent aussi présenter des différences morphométriques même si ces dernières ne sont pas significatives. Enfin, des différences de volume sont également recensées dans les parties du corps calleux contenant les axones permettant la communication entre les régions temporales et occipitales des deux hémisphères.

Rôle du cortex pariétal postérieur dans le processus d'intégration visuomotrice - connexions anatomiques avec le cortex moteur et activité cellulaire lors de la locomotion chez le chat

La progression d’un individu au travers d’un environnement diversifié dépend des informations visuelles qui lui permettent d’évaluer la taille, la forme ou même la distance et le temps de contact avec les obstacles dans son chemin. Il peut ainsi planifier en avance les modifications nécessaires de son patron locomoteur afin d’éviter ou enjamber ces entraves. Ce concept est aussi applicable lorsque le sujet doit atteindre une cible, comme un prédateur tentant d’attraper sa proie en pleine course. Les structures neurales impliquées dans la genèse des modifications volontaires de mouvements locomoteurs ont été largement étudiées, mais relativement peu d’information est présentement disponible sur les processus intégrant l’information visuelle afin de planifier ces mouvements. De nombreux travaux chez le primate suggèrent que le cortex pariétal postérieur (CPP) semble jouer un rôle important dans la préparation et l’exécution de mouvements d’atteinte visuellement guidés. Dans cette thèse, nous avons investigué la proposition que le CPP participe similairement dans la planification et le contrôle de la locomotion sous guidage visuel chez le chat. Dans notre première étude, nous avons examiné l’étendue des connexions cortico-corticales entre le CPP et les aires motrices plus frontales, particulièrement le cortex moteur, à l’aide d’injections de traceurs fluorescents rétrogrades. Nous avons cartographié la surface du cortex moteur de chats anesthésiés afin d’identifier les représentations somatotopiques distales et proximales du membre antérieur dans la partie rostrale du cortex moteur, la représentation du membre antérieur située dans la partie caudale de l’aire motrice, et enfin la représentation du membre postérieur. L’injection de différents traceurs rétrogrades dans deux régions motrices sélectionnées par chat nous a permis de visualiser la densité des projections divergentes et convergentes pariétales, dirigées vers ces sites moteurs. Notre analyse a révélé une organisation topographique distincte de connexions du CPP avec toutes les régions motrices identifiées. En particulier, nous avons noté que la représentation caudale du membre antérieur reçoit majoritairement des projections du côté rostral du sillon pariétal, tandis que la partie caudale du CPP projette fortement vers la représentation rostrale du membre antérieur. Cette dernière observation est particulièrement intéressante, parce que le côté caudal du sillon pariétal reçoit de nombreux inputs visuels et sa cible principale, la région motrice rostrale, est bien connue pour être impliquée dans les fonctions motrices volontaires. Ainsi, cette étude anatomique suggère que le CPP, au travers de connexions étendues avec les différentes régions somatotopiques du cortex moteur, pourrait participer à l’élaboration d’un substrat neural idéal pour des processus tels que la coordination inter-membre, intra-membre et aussi la modulation de mouvements volontaires sous guidage visuel. Notre deuxième étude a testé l’hypothèse que le CPP participe dans la modulation et la planification de la locomotion visuellement guidée chez le chat. En nous référant à la cartographie corticale obtenue dans nos travaux anatomiques, nous avons enregistré l’activité de neurones pariétaux, situés dans les portions des aires 5a et 5b qui ont de fortes connexions avec les régions motrices impliquées dans les mouvements de la patte antérieure. Ces enregistrements ont été effectués pendant une tâche de locomotion qui requiert l’enjambement d’obstacles de différentes tailles. En dissociant la vitesse des obstacles de celle du tapis sur lequel le chat marche, notre protocole expérimental nous a aussi permit de mettre plus d’emphase sur l’importance de l’information visuelle et de la séparer de l’influx proprioceptif généré pendant la locomotion. Nos enregistrements ont révélé deux groupes de cellules pariétales activées en relation avec l’enjambement de l’obstacle: une population, principalement située dans l’aire 5a, qui décharge seulement pendant le passage du membre au dessus del’entrave (cellules spécifiques au mouvement) et une autre, surtout localisée dans l’aire 5b, qui est activée au moins un cycle de marche avant l’enjambement (cellules anticipatrices). De plus, nous avons observé que l’activité de ces groupes neuronaux, particulièrement les cellules anticipatrices, était amplifiée lorsque la vitesse des obstacles était dissociée de celle du tapis roulant, démontrant l’importance grandissante de la vision lorsque la tâche devient plus difficile. Enfin, un grand nombre des cellules activées spécifiquement pendant l’enjambement démontraient une corrélation soutenue de leur activité avec le membre controlatéral, même s’il ne menait pas dans le mouvement (cellules unilatérales). Inversement, nous avons noté que la majorité des cellules anticipatrices avaient plutôt tendance à maintenir leur décharge en phase avec l’activité musculaire du premier membre à enjamber l’obstacle, indépendamment de sa position par rapport au site d’enregistrement (cellules bilatérales). Nous suggérons que cette disparité additionnelle démontre une fonction diversifiée de l’activité du CPP. Par exemple, les cellules unilatérales pourraient moduler le mouvement du membre controlatéral au-dessus de l’obstacle, qu’il mène ou suive dans l’ordre d’enjambement, tandis que les neurones bilatéraux sembleraient plutôt spécifier le type de mouvement volontaire requis pour éviter l’entrave. Ensembles, nos observations indiquent que le CPP a le potentiel de moduler l’activité des centres moteurs au travers de réseaux corticaux étendus et contribue à différents aspects de la locomotion sous guidage visuel, notamment l’initiation et l’ajustement de mouvements volontaires des membres antérieurs, mais aussi la planification de ces actions afin d’adapter la progression de l’individu au travers d’un environnement complexe.

Causal evidence for frontal involvement in memory target maintenance by posterior brain areas during distracter interference of visual working memory

Dorsolateral prefrontal cortex (DLPFC) is recruited during visual working memory (WM) when relevant information must be maintained in the presence of distracting information. The mechanism by which DLPFC might ensure successful maintenance of the contents of WM is, however, unclear; it might enhance neural maintenance of memory targets or suppress processing of distracters. To adjudicate between these possibilities, we applied time-locked transcranial magnetic stimulation (TMS) during functional MRI, an approach that permits causal assessment of a stimulated brain region's influence on connected brain regions, and evaluated how this influence may change under different task conditions. Participants performed a visual WM task requiring retention of visual stimuli (faces or houses) across a delay during which visual distracters could be present or absent. When distracters were present, they were always from the opposite stimulus category, so that targets and distracters were represented in distinct posterior cortical areas. We then measured whether DLPFC-TMS, administered in the delay at the time point when distracters could appear, would modulate posterior regions representing memory targets or distracters. We found that DLPFC-TMS influenced posterior areas only when distracters were present and, critically, that this influence consisted of increased activity in regions representing the current memory targets. DLPFC-TMS did not affect regions representing current distracters. These results provide a new line of causal evidence for a top-down DLPFC-based control mechanism that promotes successful maintenance of relevant information in WM in the presence of distraction.

Updating existing emotional memories involves the frontopolar/orbitofrontal cortex in ways that acquiring new emotional memories does not

In life, we must often learn new associations to people, places, or things we already know. The current fMRI study investigated the neural mechanisms underlying emotional memory updating. Nineteen participants first viewed negative and neutral pictures and learned associations between those pictures and other neutral stimuli, such as neutral objects and encoding tasks. This initial learning phase was followed by a memory updating phase, during which participants learned picture-location associations for old pictures (i.e., pictures previously associated with other neutral stimuli) and new pictures (i.e., pictures not seen in the first phase). There was greater frontopolar/orbito-frontal (OFC) activity when people learned picture–location associations for old negative pictures than for new negative pictures, but frontopolar OFC activity did not significantly differ during learning locations of old versus new neutral pictures. In addition, frontopolar activity was more negatively correlated with the amygdala when participants learned picture–location associations for old negative pictures than for new negative or old neutral pictures. Past studies revealed that the frontopolar OFC allows for updating the affective values of stimuli in reversal learning or extinction of conditioning [e.g., Izquierdo, A., & Murray, E. A. Opposing effects of amygdala and orbital PFC lesions on the extinction of instrumental responding in macaque monkeys. European Journal of Neuroscience, 22, 2341–2346, 2005]; our findings suggest that it plays a more general role in updating associations to emotional stimuli.

Caracterização de subpopulações de interneurônios imunorreativos para proteínas ligantes de cálcio no córtex pré-frontal do Sagui (Callithrix jacchus): distribuição e morfologia

Cortical interneurons are characterized by their distinct morphological, physiological and biochemical properties, acting as modulators of the excitatory activity by pyramidal neurons, for example. Various studies have revealed differences in both distribution and density of this cell group throughout distinct cortical areas in several species. A particular class of interneuron closely related to cortical modulation is revealed by the immunohistochemistry for calcium binding proteins calbindin (CB), calretinina (CR) and parvalbumin (PV). Despite the growing amount of studies focusing on calcium binding proteins, the prefrontal cortex of primates remains relatively little explored, particularly in what concerns a better understanding of the organization of the inhibitory circuitry across its subdivisions. In the present study we characterized the morphology and distribution of neurons rich in calcium-binding proteins in the medial, orbital and dorsolateral areas of the prefrontal cortex of the marmoset (Callithrix jacchus). Using both morphometric and stereological techniques, we found that CR-reactive neurons (mainly double bouquet and bipolar cells) have a more complex dendritic arborization than CB-reactive (bitufted and basket cells) and PV-reactive neurons (chandelier cells). The neuronal densities of CR- and CB-reactive cells are higher in the supragranular layers (II/III) whilst PV-reactive neurons, conversely, are more concentrated in the infragranular layers (V/VI). CR-reactive neurons were the predominant group in the three regions evaluated, being most prevalent in dorsomedial region. Our findings point out to fundamental differences in the inhibitory circuitry of the different areas of the prefrontal cortex in marmoset

Distribution of NADPH-diaphorase-positive neurons in the prefrontal cortex of the Cebus monkey

We studied the distribution of NADPH-diaphorase (NADPH-d) activity in the prefrontal cortex of normal adult Cebus apella monkeys using NADPH-d histochemical protocols. The following regions were studied: granular areas 46 and 12, dysgranular areas 9 and 13, and agranular areas 32 and Oap. NADPH-d-positive neurons were divided into two distinct types, both non-pyramidal. Type I neurons had a large soma diameter (17.24 +/- 1.73 pm) and were densely stained. More than 90% of these neurons were located in the subcortical white matter and infragranular layers. The remaining type I neurons were distributed in the supragranular layers. Type II neurons had a small, round or oval soma (9.83 +/- 1.03 mu m), and their staining pattern varied markedly. Type II neurons were distributed throughout the cortex, with their greatest numerical density being observed in layers II and III. In granular areas, the number of type II neurons was up to 20 times that of type I neurons, but this proportion was smaller in agranular areas. Areal density of type II neurons was maximum in the supragranular layers of granular areas and minimum in agranular areas. Statistical analysis revealed that these areal differences were significant when comparing some specific areas. In conclusion, our results indicate a predominance of NADPH-d-positive cells in supragranular layers of granular areas in the Cebus prefrontal cortex. These findings support previous observations on the role of type II neurons as a new cortical nitric oxide source in supragranular cortical layers in primates, and their potential contribution to cortical neuronal activation in advanced mammals. (c) 2006 Elsevier B.V. All rights reserved.

Cyto-, myelo- and chemoarchitecture of the prefrontal cortex of the Cebus monkey

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

The anatomical connections of the macaque monkey orbitofrontal cortex. A review

The orbitofrontal cortex (OfC) is a heterogeneous prefrontal sector selectively connected with a wide constellation of other prefrontal, limbic, sensory and premotor areas. Among the limbic cortical connections, the ones with the bippocampus and parabippocampal cortex are particularly salient. Sensory cortices connected with the OfC include areas involved in olfactory, gustatory, somatosensory, auditory and visual processing. Subcortical structures with prominent OfC connections include the amygdala, numerous thalamic nuclei, the striatum, hypothalamus, periaqueductal gray matter, and biochemically specific cell groups in the basal forebrain and brainstem. Architectonic and connectional evidence supports parcellation of the OfC. The rostrally placed isocortical sector is mainly connected with isocortical areas, including sensory areas of the auditory, somatic and visual modalities, whereas the caudal non-isocortical sector is principally connected with non-isocortical areas, and, in the sensory domain, with olfactory and gustatory areas. The connections of the isocortical and non- isocortical orbital sectors with the amygdala, thalamus, striatum, hypotbalamus and periaqueductal gray matter are also specific. The medial sector of the OfC is selectively connected with the bippocampus, posterior parabippocampal cortex, posterior cingulate and retrosplenial areas, and area prostriata, while the lateral orbitofrontal sector is the most heavily connected with sensory areas of the gustatory, somatic and visual modalities, with premotor regions, and with the amygdala.

Efeito do ambiente sobre o período crítico de plasticidade do córtex pré-frontal de ratos

O período crítico de plasticidade do córtex cerebral é a etapa do desenvolvimento pós-natal do sistema nervoso onde os circuitos neurais são mais suscetíveis à mudanças influenciadas por informações oriundas do ambiente. No córtex pré-frontal de humanos, responsável pelas funções executivas, o período crítico de plasticidade estende-se desde o nascimento até o final da adolescência e início da vida adulta. Isto é definido, entre outros fatores, pelo amadurecimento das redes perineuronais, uma estrutura especializada da matriz extracelular, localizada em volta do corpo celular e dendritos proximais de interneurônios inibitórios. O objetivo desta pesquisa foi verificar o efeito do ambiente em etapas distintas da adolescência sobre a estrutura e a função do córtex pré-frontal de ratos e a distribuição da expressão espacial e temporal das redes perineuronais sob estas condições. As funções executivas foram avaliadas através de testes comportamentais medindo a capacidade de memória operacional e a inibição comportamental. Observamos que estímulos estressores crônicos imprevisíveis provocam alterações no período crítico de plasticidade do córtex pré-frontal e, consequentemente, influenciam o amadurecimento das funções executivas. Observamos também que o estresse crônico induz modificação no padrão de amadurecimento das redes perineuronais no córtex pré-frontal. Estes resultados indicam a vulnerabilidade do córtex pré-frontal de ratos adolescentes para os efeitos negativos de estímulos ambientais estressores sobre o período crítico de plasticidade.

Estudo do envolvimento da neurotransmissão noradrenérgica do córtex pré-frontal medial nas respostas autonômicas desencadeadas pelo estresse por restrição agudo em ratos

O córtex pré-frontal medial (CPFM) é uma região límbica envolvida no controle da atividade autonômica e cardiovascular. Foi demonstrado que a inibição da região infra-límbica (IL) do CPFM reduziu as repostas comportamentais, neuroendócrinas e autônomas induzidas por estímulos aversivos. Entretanto, apesar das evidências de um importante papel do córtex IL na integração das respostas ao estresse, informações sobre os mecanismos neuroquímicos locais envolvidos no controle destas respostas ainda são escassos. Diante disso, o presente estudo teve o objetivo de investigar um possível envolvimento de mecanismos noradrenérgicos do córtex IL nas respostas autonômicas ao estresse por restrição agudo em ratos. Para tanto, nós investigamos, em grupos independentes de animais, o efeito da microinjeção bilateral no córtex IL de veículo (salina, 100nL), WB4101 (antagonista seletivo de adrenoceptores α1), RX821002 (antagonista seletivo de adrenoceptores α2) e propranolol (antagonista não-seletivo de adrenoceptores β, 10nmol/100nL), sobre as respostas de aumento da pressão arterial (PA) e frequência cardíaca (FC) e redução da temperatura cutânea da cauda induzidas pelo estresse por restrição agudo em ratos. A microinjeção bilateral de WB4101, RX821002 e propranolol no córtex IL não afetou os parâmetros basais de PA, FC e temperatura cutânea da cauda, o que indica uma ausência de influência na manutenção tônica do sistema cardiovascular. Entretanto, o bloqueio de adrenoceptores α1 no córtex IL diminuiu a resposta taquicárdica induzida pelo estresse por restrição, sem afetar as respostas pressora e de redução da temperatura cutânea da cauda. O bloqueio de adrenoceptores α2 no córtex IL reduziu todos os parâmetros analisados e o bloqueio de adrenoceptores β no córtex IL atenuou a resposta de redução da temperatura cutânea induzida pelo estresse por restrição. As respostas de elevação da ...

Surgical Treatment of Severe Frontal Bone Fracture

Craniofacial trauma can lead to several complications. The combined fractures of anterior and posterior walls of the frontal bone are almost always followed by lesions in nasofrontal orifices and disruption of nasofrontal ostia or ducts, a significant factor for the development of early and late complications after sinus fractures. This article reports a case of trauma patient, who underwent neurological evaluation and at first showed good general condition. Computed tomography noted fracture of the anterior and posterior walls of the frontal sinus and small foci of pneumocephalus in the cerebral cortex. The patient was monitored periodically and 9 days after trauma showed increased areas of pneumocephalus in prefrontal cortex, cerebrospinal fluid draining, and large dura mater lesion, with signs of necrosis and inflammation (meningitis). The necrotic tissues were removed, and dura mater was repaired through the approximation with resorbable wire polyglactin 910 5-0, oxidized cellulose application, and bonding with human fibrin sealant (fibrinogen, thrombin, and calcium chloride). Sinusectomy, frontal sinus, and nasofrontal duct obliteration with pedicled pericranium flap were performed. Tomographically, a reanatomization was noted in frontal region, and a 12-month follow-up showed no complication. The use of fibrin glue to repair dura mater lacerations, as well as the pedicle pericranium flap for frontal sinus and nasofrontal duct obliteration, is an efficient method for treating fractures of the frontal bone.

Frontal assessment battery in a Brazilian sample of healthy controls: normative data

Objective: To show data on the performance of healthy subjects in the Frontal Assessment Battery (FAB), correlating with gender, age, education, and scores in the Mini-Mental State Examination (MMSE). Methods: Two hundred and seventy-five healthy individuals with mean age of 66.4 +/- 10.6 years-old were evaluated. Mean total FAB scores were established according to the educational level. Results: Mean total FAB scores according to the educational level were 10.9 +/- 2.3, for one to three years; 12.8 +/- 2.7, for four to seven years; 13.8 +/- 2.2, for eight to 11 years; and 15.3 +/- 2.3, for 12 or more years. Total FAB scores correlated significantly with education (r=0.47; p<0.0001) and MMSE scores (r=0.39; p<0.0001). No correlation emerged between FAB scores, age, and gender. Conclusion: In this group of healthy subjects, the Brazilian version of the FAB proved to be influenced by the education level, but not by age and gender.