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Resumen Objetivo: Explorar si voluntarios sanos presentarían correlación entre su puntaje en un test psicológico emocional y las activaciones de áreas cerebrales relacionadas con las emociones medidas con resonancia magnética funcional (RMf). Material y métodos: Estudio exploratorio de prueba diagnóstica, prospectivo, con diseño del propio individuo como control, con muestra de 12 participantes. Se categorizó a cada participante con un puntaje de estabilidad emocional derivado de un test psicológico y se utilizaron estímulos emocionales audiovisuales durante las adquisiciones de RMf. Resultados: La sumatoria de clusters de activación medidos en cantidad total de vóxeles durante los estímulos negativos en áreas cerebrales relacionadas con las emociones mostró una correlación negativa estadísticamente significativa para nuestro tamaño de muestra respecto de los puntajes en el test emocional, con rho de Spearman de −0,623 y p = 0,0428. Conclusiones: Los paradigmas de RMf utilizados permitieron cuantificar las activaciones cerebrales ante estímulos emocionales de valencia positiva y negativa, y los resultados obtenidos abren una perspectiva hacia la posibilidad de utilizar test psicológicos y secuencias de RMf para predecir la posibilidad de aparición de síntomas de patologías psicológicas o psiquiátricas ante factores desencadenantes en población sana que presente en estos test valores cercanos al límite de la normalidad.
Abstract Objective: To explore if healthy volunteers would present a correlation between their score in emotional psychological test and the activations of brain areas related to emotions measured with functional magnetic resonance imaging (fMRI). Material and methods: Exploratory study of a prospective diagnostic test, with the individuals own design as a control, with a sample of 12 participants. Each participant was categorized with an emotional stability score derived from a psychological test and audiovisual emotional stimuli were used during fMRI acquisitions. Results: The sum of activation clusters measured in total number of voxels during negative stimuli in brain areas related to emotions showed a statistically significant negative correlation for our sample size with respect to the scores in the emotional test, with Spearmans rho of −0.623 and p = 0.0428. Conclusions: The fMRI paradigms used made it possible to quantify brain activations in response to emotional stimuli of positive and negative valence, and the results obtained open a perspective towards the possibility of using psychological tests and fMRI sequences to predict the possibility of the appearance of symptoms of psychological or psychiatric pathologies in response to triggering factors in a healthy population that present values close to the normal limit in these tests.
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Paroxysmal sympathetic hyperactivity (PSH) is a syndrome characterized by paroxysmal tachycardia, increased blood pressure, tachypnea, hyperthermia, profuse sweating, abnormal posture or dystonia. It occurs in diseases such as moderate to severe brain injury, cerebral hypoxia, hydrocephalus, brain tumor and encephalitis. At present, the etiology and pathogenesis are still unclear, and it is easy to be misdiagnosed as epilepsy clinically. This article reports a 43-year-old male patient with late-onset mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (MELAS) confirmed by genetic testing. During hospitalization, he suddenly developed episodic involuntary limb movements, profuse sweating, tachycardia, and arterial hypertension. He was initially diagnosed with symptomatic epilepsy, but long-term electroencephalogram monitoring showed no synchronized discharge, and he was given antiepileptic drugs. The treatment was also ineffective. Brain magnetic resonance imaging revealed a new lesion in the left insular and insular operculum. Dexmedetomidine, baclofen, and gabapentin were given to suppress sympathetic nerve excitability. Drugs were effective, so the diagnosis was corrected to PSH. There is no report of MELAS complicated with PSH in the previous literature. It is speculated that it may be related to the low clinical cognition of PSH. In this case, new lesions in the insula and insular operculum appeared during the onset of PSH, suggesting that may be related to the pathogenesis of PSH.
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OBJECTIVE Fear can be learned indi-rectly,but excessive transmission of fear is essential for the development of mental illness.Previous research has indicated that the anterior insular cortex(AIC)may play a crucial role in the process of fear transmission,and abnormal AIC activity is a possible mechanism under-lying various affective disorders.Inhibitory neurons are crucial for maintaining local microcircuit homeostasis.With the support of novel specific neuroregulatory tech-niques,it is now possible to monitor and regulate differ-ent types of neurons in real-time.Therefore,investigating distinct subtypes of inhibitory neurons in the AIC that are involved in fear contagion may provide valuable insights into potential mechanisms underlying mental disorders.METHODS We established a modified observational fear(OF)model.A demonstrator(DM)mouse was placed in an acrylic cup at the center of the apparatus,and two observer(OB)mice were allowed to explore the DM mouse simultaneously from separate areas on either side.During the OF training,electric foot shocks were administered to the DM mouse and freezing,the side and corner time,and social interaction behavior were scored.Next,we characterized the activity patterns of distinct neuronal subtypes in the AIC using GCaMP-based calcium recording.Finally,we employed a Cre-dependent optogenetic approach to selectively modulate excitatory or inhibitory neurons in the AIC,and investigat-ed empathic fear behavior across different Cre transgenic mouse lines(CK2-Cre,PV-Cre,SOM-Cre,VIP-Cre).RESULTS During the training phase,the OB mice exhib-ited significantly higher levels of fear compared to the control group(which did not observe a traumatic event),as evidenced by increased freezing time,decreased interaction time,and increased corner zone time.Calcium fiber recording results suggested that CK2 neurons are involved in risk prediction,while PV and VIP neurons exert inhibitory control on this behavior.Optogenetic silencing of CK2-positive neurons in the AIC through injection of AAV-DIO-NpHR-mCherry in mice demon-strated a significant reduction in empathic fear.Similarly,activation of PV or VIP inhibitory neurons expressing ChR2-eYFP also resulted in a similar effect.However,activation of SOM neurons led to a significant increase in empathic fear.CONCLUSION Our study demonstrated that VIP and PV neuron activity in the AIC attenuates empathetic fear,while SOM and CK2 neuron activity enhances fear expression.These findings shed light on the distinct contributions of various inhibitory interneu-rons in the AIC to fear contagion,indicating their mutual interaction for maintaining local microcircuit homeostasis that regulates empathetic fear behaviors.
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Itch is an unpleasant sensation that urges people and animals to scratch. Neuroimaging studies on itch have yielded extensive correlations with diverse cortical and subcortical regions, including the insular lobe. However, the role and functional specificity of the insular cortex (IC) and its subdivisions in itch mediation remains unclear. Here, we demonstrated by immunohistochemistry and fiber photometry tests, that neurons in both the anterior insular cortex (AIC) and the posterior insular cortex (PIC) are activated during acute itch processes. Pharmacogenetic experiments revealed that nonselective inhibition of global AIC neurons, or selective inhibition of the activity of glutaminergic neurons in the AIC, reduced the scratching behaviors induced by intradermal injection of 5-hydroxytryptamine (5-HT), but not those induced by compound 48/80. However, both nonselective inhibition of global PIC neurons and selective inhibition of glutaminergic neurons in the PIC failed to affect the itching-scratching behaviors induced by either 5-HT or compound 48/80. In addition, pharmacogenetic inhibition of AIC glutaminergic neurons effectively blocked itch-associated conditioned place aversion behavior, and inhibition of AIC glutaminergic neurons projecting to the prelimbic cortex significantly suppressed 5-HT-evoked scratching. These findings provide preliminary evidence that the AIC is involved, at least partially via aversive emotion mediation, in the regulation of 5-HT-, but not compound 48/80-induced itch.
Subject(s)
Humans , Animals , Serotonin , Insular Cortex , Pruritus/chemically induced , Cerebral Cortex/physiology , NeuronsABSTRACT
The rostral agranular insular cortex (RAIC) has been associated with pain modulation. Although the endogenous cannabinoid system (eCB) has been shown to regulate chronic pain, the roles of eCBs in the RAIC remain elusive under the neuropathic pain state. Neuropathic pain was induced in C57BL/6 mice by common peroneal nerve (CPN) ligation. The roles of the eCB were tested in the RAIC of ligated CPN C57BL/6J mice, glutamatergic, or GABAergic neuron cannabinoid receptor 1 (CB1R) knockdown mice with the whole-cell patch-clamp and pain behavioral methods. The E/I ratio (amplitude ratio between mEPSCs and mIPSCs) was significantly increased in layer V pyramidal neurons of the RAIC in CPN-ligated mice. Depolarization-induced suppression of inhibition but not depolarization-induced suppression of excitation in RAIC layer V pyramidal neurons were significantly increased in CPN-ligated mice. The analgesic effect of ACEA (a CB1R agonist) was alleviated along with bilateral dorsolateral funiculus lesions, with the administration of AM251 (a CB1R antagonist), and in CB1R knockdown mice in GABAergic neurons, but not glutamatergic neurons of the RAIC. Our results suggest that CB1R activation reinforces the function of the descending pain inhibitory pathway via reducing the inhibition of glutamatergic layer V neurons by GABAergic neurons in the RAIC to induce an analgesic effect in neuropathic pain.
Subject(s)
Mice , Animals , Insular Cortex , Peroneal Nerve , Mice, Inbred C57BL , Neuralgia , GABAergic Neurons , Analgesia , Analgesics , Receptors, CannabinoidABSTRACT
The interaction between the heart and brain is complex and integral to the maintenance of normal cardiovascular function. Even in the absence of coronary disease, acute neuronal injury can induce a variety of cardiac changes. Recent neuroimaging data revealed a network including the insular cortex, anterior cingulate gyrus, and amygdala playing a crucial role in the regulation of central autonomic nervous system. Damage in these areas has been associated with arrhythmia, myocardial injury, higher plasma levels of brain natriuretic peptide, catecholamines, and glucose. Some patients after brain injury may die due to occult cardiac damage and functional impairment in the acute phase. Heart failure adversely influences acute stroke mortality. Troponin and NT-proBNP are elevated in acute brain injury patients, in response to the activated renin–angiotensin–aldosterone system and other neurohumoral changes, as a protective mechanism for sympathoinhibitory activity. Such patients have been shown to be associated with higher short- and long-term mortality. While thrombolysis, neuroprotection, and other measures, alone or in combination, may limit the cerebral damage, attention should also be directed toward the myocardial protection. Early administration of cardioprotective medication aimed at reducing increased sympathetic tone may have a role in myocardial protection in stroke patients. For a full understanding of the brain–heart control, the consequences of disruption of this control, the true incidence of cardiac effects of stroke, and the evidence-based treatment options further research are needed.
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ABSTRACT Gerstmann Syndrome (GS) is a rare neurological condition described as a group of cognitive changes corresponding to a tetrad of symptoms comprising agraphia, acalculia, right-left disorientation and finger agnosia. It is known that some specific brain lesions may lead to such findings, particularly when there is impairment of the angular gyrus and adjacent structures. In addition, the possibility of disconnection syndrome should be considered in some cases. The purpose of this article is to report a case of a young, cardiac patient, non-adherent to treatment, who presented with a stroke in which transient clinical symptoms were compatible with the tetrad of GS. The case report is followed by a discussion and brief review of the relevant literature.
RESUMO A síndrome de Gerstmann (SG) é uma condição neurológica rara, caracterizada por um grupo de alterações cognitivas que correspondem a uma tétrade composta por agrafia, acalculia, desorientação direita-esquerda e agnosia para dedos. Sabe-se que certas lesões encefálicas específicas podem levar a tais achados, particularmente quando ocorre acometimento do giro angular e estruturas adjacentes. Além disso, a possibilidade de síndrome de desconexão deve ser considerada em alguns casos. O propósito deste artigo é relatar o caso de um paciente jovem cardiopata e não aderente ao tratamento que se apresentou com uma síndrome encéfalo-vascular associada a alterações clínicas transitórias compatíveis com a tétrade da SG. Este relato de caso é acompanhado de discussão e breve revisão de dados pertinentes da literatura.
Subject(s)
Humans , Parietal Lobe , Cerebral Cortex , Gerstmann Syndrome , Frontal LobeABSTRACT
El síndrome X frágil en los seres humanos es causado por una mutación en el gen FMR1 y se asocia con grave retraso mental, hiperactividad y ansiedad. Hemos comparado ratones FMR1-KO con ratones Control en la densidad neuronal de la corteza insular, área del cerebro asociada con el procesamiento del dolor y manejo de la ansiedad. Los ratones también fueron sometidos a una prueba de aprendizaje espacial en un entorno de ansiedad. Los resultados muestran asimetría significativa entre la densidad neuronal entre ínsula izquierda y derecha en KO en comparación con ratones de tipo Control. En cuanto al comportamiento, a pesar de los ratones KO no mostraron marcados déficits en la realización de tareas mostraron una velocidad superior a la de sus homólogos de tipo Control. Por otra parte, la asimetría de densidad insular se correlaciona con una mayor velocidad a nivel individual. Estos resultados sugieren que la asimetría de la densidad neuronal insular en FMR1 ratones KO se puede considerar como un correlato anatómico de las anormalidades de comportamiento observados.
Fragile X syndrome in humans is caused by a mutation in the FMR1 gene and it is associated with severe mental retardation, hyperactivity and anxiety. Here we compare FMR1 Knock-Out mice, a model of Fragile-X syndrome, and wild-type mice with respect to the neuronal density of the insular cortex, a brain area associated with pain processing and anxiety management. Mice were also subjected to a spatial learning test in an anxiogenic environment. Results show significant asymmetry between neuronal density between left and right insula in knock out as compared to wild type mice. Behaviorally, although knock-out mice did not show deficits in task completion they explored the maze at a higher velocity than their wild-type counterparts. Furthermore, insular density asymmetry correlated with higher velocity during one of the spatial navigation tasks at the individual mouse level. These results suggest that insular neuronal density asymmetry in FMR1 Knot-Out mice may be considered as an anatomical correlate of the observed behavioral abnormalities.
Subject(s)
Animals , Male , Female , Anxiety , Cerebral Cortex , Fragile X Mental Retardation Protein , Pain , Mice, Knockout , Disease Models, Animal , Spatial Learning , Mice, Inbred C57BLABSTRACT
The term pain matrix refers to the structures and pathways in the central nervous system that play a role in pain processing and integration. For the last several years, our group has been studying the mechanisms that are involved in the establishment of long-term pain. Our research focus has been the study of the different nuclei and corticolimbic pathways that are involved in the affective-cognitive component of pain. In addition, we have also explored painful processes and memory. The pain matrix is constituted by the ventral tegmental area (VTA), anterior cingulate cortex (ACC), and insular cortex, among others. VTA is a predominantly dopaminergic area and has projections to ACC and the insular cortex. Stimulation of this region can reduce nociception, whereas its lesion has the opposite effect. In the ACC, it has been studied how excitatory aminoacids, such as glutamate, increase nociception while inhibitory ones decrease it. Moreover, this cortex is associated with mechanisms of pain memory. In this sense, we have seen that blocking cholinergic receptors diminishes the acquisition of pain-related memories. Nociceptive stimuli increase the expression of inhibitory muscarinic M2 receptors. In relation with insular cortex, the focus of study has been on the dopaminergic system. We have found that blocking dopaminergic D2 receptors significantly reduces neuropathic nociception. In response to an inflammatory process there is a decrease in the extracellular levels of dopamine and in the expression of mRNA for excitatory dopamine D1 receptors, while there is an increase in mRNA expression for inhibitory D2 receptors. Despite current progress in this research area, more studies are needed in order to integrate the relationship among the different neurotransmission systems. This will contribute to the proposal of novel therapeutic alternatives to the conventional treatments for pain.
El término "matriz del dolor" se refiriere a todas las estructuras y vías del Sistema Nervioso Central relacionadas con la integración del dolor. Nuestro grupo estudia desde hace varios años los principales mecanismos involucrados en el desarrollo del dolor a largo plazo. Nos hemos enfocado en el estudio de diferentes núcleos y vías cortico-límbicas que están relacionadas con la parte afectiva-cognitiva, así como en la memoria de los procesos dolorosos. Dentro de estos núcleos se encuentra el área tegmental ventral (ATV), la corteza anterior del cíngulo (CAC) y la corteza insular. El ATV es una estructura principalmente dopaminérgica con proyecciones a la CAC y a la corteza insular. Como se verá más adelante, estimular este núcleo disminuye la nocicepción, mientras que el lesionarlo, la aumenta. En la CAC se ha estudiado cómo aminoácidos excitadores como el glutamato aumentan la nocicepción y cómo, por el contrario, los aminoácidos inhibitorios como la taurina, la disminuyen. Además esta corteza está relacionada con mecanismos de memoria dolorosa. Hemos visto que el bloqueo de receptores colinérgicos disminuye la adquisición de la memoria relacionada al dolor. Además, un estímulo nociceptivo aumenta la expresión de los receptores muscarínicos inhibitorios M2. En el caso de la corteza insular, se ha estudiado principalmente el papel del sistema dopaminérgico. Hemos encontrado que el bloqueo de receptores dopaminérgicos D2 disminuye de manera significativa la nocicepción neuropática. Encontramos también que los niveles extracelulares de dopamina en esta región disminuyen a consecuencia de un proceso inflamatorio, además de que disminuye la expresión del RNAm de los receptores excitadores D1 y aumenta la de los receptores inhibidores D2. A pesar del avance que se ha obtenido en esta área de investigación, se necesitan más estudios para integrar la relación entre los diferentes sistemas de neurotransmisión y poder proponer alternativas a los tratamientos convencionales para las diferentes patologías que cursan con una experiencia dolorosa.
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Protein phosphorylation and dephosphorylation form a major post-translation mechanism that enables a given cell to respond to ever-changing internal and external environments. Neurons, similarly to any other cells, use protein phosphorylation/dephosphorylation to maintain an internal homeostasis, but they also use it for updating the state of synaptic and intrinsic properties, following activation by neurotransmitters and growth factors. In the present review we focus on the roles of several families of kinases, phosphatases, and other synaptic-plasticity-related proteins, which activate membrane receptors and various intracellular signals to promote transcription, translation and protein degradation, and to regulate the appropriate cellular proteomes required for taste memory acquisition, consolidation and maintenance. Attention is especially focused on the protein phosphorylation state in two forebrain areas that are necessary for taste-memory learning and retrieval: the insular cortex and the amygdala. The various temporal phases of taste learning require the activation of appropriate waves of biochemical signals. These include: extracellular signal regulated kinase I and II (ERKI/II) signal transduction pathways; Ca(2+)-dependent pathways; tyrosine kinase/phosphatase-dependent pathways; brain-derived neurotrophicfactor (BDNF)-dependent pathways; cAMP-responsive element bindingprotein (CREB); and translation-regulation factors, such as initiation and elongation factors, and the mammalian target of rapamycin (mTOR). Interestingly, coding of hedonic and aversive taste information in the forebrain requires activation of different signal transduction pathways.
Subject(s)
Humans , Amygdala , Clinical Coding , Homeostasis , Intercellular Signaling Peptides and Proteins , Learning , Membranes , Memory , Neurons , Neurotransmitter Agents , Peptide Elongation Factors , Phosphoric Monoester Hydrolases , Phosphorylation , Phosphotransferases , Prosencephalon , Proteins , Proteolysis , Proteome , Signal Transduction , Sirolimus , TyrosineABSTRACT
This study was performed to investigate the role of glutamate neurotransmitter system on gastrointestinal motility in a middle cerebral artery occlusion (MCAO) model of rats. The right middle cerebral artery was occluded by surgical operation, and intestinal transit and geometric center as a parameter of gastrointestinal motility and expression of c-Fos protein in the insular cortex and cingulate cortex were measured at 2 and 12 h after MCAO. Intestinal transit was 66.3+/-7.5% and 62.3+/-5.7% 2 and 12 h after sham operation, respectively, and MCAO significantly decreased intestinal transit to 39.0+/-3.5% and 47.0+/-5.1% at 2 and 12 h after the occlusion, respectively (p<0.01). The geometric center was 5.6+/-0.4 and 5.2+/-0.9 at 2 and 12 h after sham operation, respectively, and MCAO significantly decreased geometric center to 2.9+/-0.8 and 3.0+/-0.3 at 2 and 12 h after the occlusion, respectively (p<0.01). In control animals, injection of atropine decreased intestinal transit to 35.9+/-5.2%, and injection of glutamate NMDA receptor antagonist, MK-801, decreased intestinal transit to 28.8+/-9.5%. Pretreatment with MK-801, a glutamate NMDA receptor antagonist, in the MCAO group decreased intestinal transit to 11.8+/-3.2%, which was significantly decreased compared to MCAO group (p<0.01). MCAO markedly increased the expression of c-Fos protein in the insular cortex and cingulate cortex ipsilateral to the occlusion 2 h after MCAO, and pretreatment with MK-801 produced marked reduction of c-Fos protein expression compared to MCAO group (p<0.01). These results suggest that modulation of gastrointestinal motility after MCAO might be partially mediated through a glutamate NMDA receptor system.
Subject(s)
Animals , Rats , Atropine , Dizocilpine Maleate , Gastrointestinal Motility , Glutamic Acid , Gyrus Cinguli , Infarction, Middle Cerebral Artery , Middle Cerebral Artery , N-Methylaspartate , Neurotransmitter Agents , SalicylamidesABSTRACT
BACKGROUND: Atrial fibrillation (AF), commonly considered as a cardiac embolic source, can itself be induced by stroke. We therefore tried to find and analyze this 'stroke-induced' AF. METHODS: From the Inha University Stroke Registry of the past 2 years, 143 middle cerebral artery (MCA) territorial infarct patients who had been admitted within 48 hours after stroke onset were recruited to participate in the study. Electrocardiograms (EKG) on admission and follow-up during hospitalization were analyzed. Also, MCA infarct was subdivided according to insular involvement by brain imaging. RESULTS: Among 143 MCA territorial infarcts, 38 patients had AF on admission (Rt:21; Lt:17). Of those, insular involvements of the MCA infarct was noted in 32 patients. All the patients had a follow-up EKG and AF disappeared in 3 patients (Rt:2; Lt:1). In the remaining 105 patients, 10 patients subsequently developed new AF within 1 week after hospitalization. All those 10 patients had right-sided MCA infarcts and insular involvements were present in 9 patients. In summary, among the 48 MCA infarct associated with AF, 13 AF (Rt:12; Lt:1) were presumed to be the consequence and not the cause of stroke. CONCLUSIONS: Though human insular stimulation and inactivation studies have suggested that AF would be more common in left insular destructive lesions, it was not always supported in clinical series. From our study, presumed 'stroke-induced' AF was highly associated with right insular lesions. The mechanism of arrhythmogenesis by ischemic stroke might be more complicated than previously expected and, not merely the simple inactivation of an anatomical substrate, the insular cortex.
Subject(s)
Humans , Atrial Fibrillation , Electrocardiography , Follow-Up Studies , Hospitalization , Middle Cerebral Artery , Neuroimaging , StrokeABSTRACT
Objective To assess the effects of electric stimulating insular cortex on ECG and heart rate variability(HRV) in rats. Methods ⑴The total of 36 healthy male Wistar rats were randomly divided into control group and electric stimulating group, and ECG was observed after electric stimulating insular cortex 1 hour with 500uA,50HZ current intensity. ⑵The total of 42 healthy male Wistar rats were randomly divided into sham group,control group and electric stimulating group, then the control group and electric stimulating group were further divided into 70uA,500uA,1500uA,50HZ stimulating groups, each group containing 6 rats. Blood pressure, heart rate and HRV were observed after electric stimulation 1 hour. Results ⑴The ECG showed change,and heart rate and blood pressure of rats in the electric stimulating group significantly increased at 500uA after electric stimulation 1 hour compared with sham and control groups. ⑵The measured components of HRV of 500uA and 1500uA stimulating groups, such as percentages of NN intervals differences