ABSTRACT
Little is known about the underlying neural mechanism of deep brain stimulation (DBS). We found that DBS targeted at the nucleus accumbens (NAc) normalized NAc activity, reduced excessive connectivity between the NAc and prefrontal cortex, and decreased frontal low-frequency oscillations during symptom provocation in patients with obsessive-compulsive disorder. Our findings suggest that DBS is able to reduce maladaptive activity and connectivity of the stimulated region.
Subject(s)
Corpus Striatum/physiology , Deep Brain Stimulation , Frontal Lobe/physiology , Nerve Net/physiology , Obsessive-Compulsive Disorder/physiopathology , Obsessive-Compulsive Disorder/therapy , Adult , Deep Brain Stimulation/methods , Female , Humans , Magnetic Resonance Imaging/methods , Male , Middle Aged , Obsessive-Compulsive Disorder/psychology , Photic Stimulation/methods , Psychomotor Performance/physiologyABSTRACT
El hipocampo es sensible a altos niveles de glucocorticoides.Durante la respuesta de estrés, esta estructura sufre cambios bioquímicos y celulares que afectan funciones tales como la memoria espacial y la conducta exploratoria, entre otras. En este estudio analizamos la influencia del neuroesteroide progesterona (PROG) sobre los cambios inducidos por estrés en corticosterona (CORT) urinaria, memoria espacial y conducta exploratoria. Se implantó PROG o vehículo (VEHI) a ratas macho adultas castradas y se les expuso a estrés crónico por hacinamiento o ruido ultrasónico durante 10 días. Se evaluaron niveles de PROG y CORT en orina usando cromatografía líquida de alta resolución (HPLC). Los implantes de PROG inhibieron el incremento de CORT inducido por estrés, previnieron el detrimento de la memoria espacial en el laberinto acuático de Morris y eliminaron el incremento en la actividad exploratoria en la prueba del campo de agujeros. Estos resultados sugieren un efecto protector de la PROG, posiblemente mediado por los mecanismos ansiolíticos de la hormona, contra la elevación de corticoesteroides y el déficit conductual generado por las situaciones estresantes.
The hippocampus is sensitive to high levels of glucocorticoids during stress responses; it suffers biochemical and cellular changes that affect spatial memory and exploratory behavior, among others. We analyzed the influence of the neurosteroid progesterone (PROG) on stress-induced changes in urinary corticosterone (CORT) levels, spatial memory and exploratory behavior. Castrated adult male rats were implanted with PROG or vehicle (VEHI), and then exposed for ten days to chronic stress created by overcrowding or ultrasonic noise. PROG and CORT levels were assessed in urine using highperformance liquid chromatography (HPLC). Implanted PROG inhibited the rise of stress-induced CORT, prevented spatial memory impairment in the Morris water maze, and eliminated increased exploratory behavior in the hole-board test. These results suggest a protective role of PROG, possibly mediated by its anxiolytic mechanisms, against corticosteroids elevation and the behavioral deficit generated by stressful situations.
Subject(s)
Animals , Progesterone , Rats/psychology , Corticosterone , Stress, PsychologicalABSTRACT
Brain asymmetries are a widespread phenomenon among vertebrates and show a common behavioural pattern. The right hemisphere mediates more emotional and instinctive reactions, while the left hemisphere deals with elaborated experience-based behaviours. In order to achieve a lateralized behaviour, each hemisphere needs different information and therefore different representations of the world. However, how these representations are accomplished within the brain is still unknown. Based on the pigeon's visual system, we present experimental evidence that lateralized behaviour is the result of the interaction between the subtelencephalic ascending input directing more bilateral visual information towards the left hemisphere and the asymmetrically organized descending telencephalic influence on the tecto-tectal balance. Both the bilateral representation and the forebrain-modulated information processing might explain the left hemispheric dominance for complex learning and discrimination tasks.