Behavioral narrative data showed that monadic pictures were significantly more traumatic for BPD patients than for controls. As hypothesized BPD patients showed significantly more anterior midcingulate CHIR-99021 molecular weight cortex activation in response to monadic pictures than controls. In response to dyadic pictures patients showed
more activation of the fight superior temporal sulcus and less activation of the fight parahippocampal gyrus compared to controls. Our results suggest evidence for potential neural mechanisms of attachment trauma underlying interpersonal symptoms of BPD, i.e. fearful and painful intolerance of aloneness, hypersensitivity to social environment, and reduced positive memories of dyadic interactions. (c) 2007 Elsevier Ireland Ltd. All rights reserved.”
“Autism spectrum disorders (ASD) are characterized by impairments in reciprocal
CYT387 chemical structure social communication, and repetitive, stereotyped verbal and non-verbal behaviors. Genetic studies have provided a relatively large number of genes that constitute a comprehensive framework to better understand this complex and heterogeneous syndrome. Based on the most robust findings, three observations can be made. First, genetic contributions to ASD are highly heterogeneous and most probably involve a combination of alleles with low and high penetrance. Second, the majority of the mutations apparently affect a single allele, suggesting a key role for gene dosage in susceptibility
to ASD. Finally, the broad expression and function of the causative genes suggest that alteration of synaptic homeostasis could be a common biological process associated with ASD. Understanding the mechanisms that regulate synaptic homeostasis should shed new light on the causes of ASD and could selleck chemicals llc provide a means to modulate the severity of the symptoms.”
“Tactile sensation, which is one of the earliest developing sensory systems, is very important in the perception of an individual’s body and the surrounding physical environment, especially in newborns. However, currently, only little is known about the response of a newborn’s brain to tactile sensation. The objective of the present study was to determine the response of a newborn’s brain to tactile sensation and to compare the brain responses to various sensory stimuli. Ten healthy newborns, 2-9 days after birth, were enrolled. A multichannel near-infrared spectroscopy system was used to measure brain responses. The probe array covered broad cortical areas, including the parietal, temporal, and occipital areas. We measured cortical hemodynamic changes in response to three different types of stimuli: tactile, auditory, and visual. Activated areas were analyzed by t-tests, and the number of activated channels among the three different stimuli was compared by chi(2)-tests.