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Neural correlates of the energetic value of food during visual processing and response inhibition
No full textPrevious research showed that human brain regions involved in reward and cognitive control are responsive to visually presented food stimuli, in particular high-energy foods. However, it is still to be determined whether the preference towards high-energy foods depends on their higher energy density (kcal/gram), or is based on the difference in energy content of the food items (total amount of kcal). Here we report the results of an fMRI study in which normal-weight healthy participants processed food images during a one-back task or were required to inhibit their response towards food stimuli during a Go/No-Go task. High-energy density (HD) and low-energy density (LD) foods were matched for energy content displayed. Food-related kitchen objects (OBJ) were used as control stimuli. The lateral occipital complex and the orbitofrontal cortex showed consistent higher activity in response to HD than LD foods, both during visual processing and response inhibition. This result suggests that images of HD foods, even when the amount of food shown is not associated with a higher energy content, elicit preferential visual processing - possibly involving attentional processes - and trigger a response from the reward system. We conclude that the human brain is able to distinguish food energy densities of food items during both active visual processing and response inhibition
Dual-route imitation in preschool children
No full textImitation can be realized via two different routes: a direct route that translates visual input into motor output when gestures are meaningless or unknown, and a semantic route for known/meaningful gestures. Young infants show imitative behaviours compatible with the direct route, but little is known about the development of the semantic route, studied here for the first time. The present study examined preschool children (3–5 years of age) imitating gestures that could be transitive or intransitive, and meaningful or meaningless. Both routes for imitation were already present by three years of age, and children were more accurate at imitating meaningful-intransitive gestures than meaningless-intransitive ones; the reverse pattern was found for transitive gestures. Children preferred to use their dominant hand even if they had to anatomically imitate the model to do this, showing that a preference for specular imitation is not exclusive at these ages
The effect of observed biological and non biological movements on action imitation: An fMRI study
No full textAbstract Past research has indicated that when individuals observe biological movements many areas in the observer's motor system become active. Nonetheless, recent behavioral evidence showed that observed movements can interfere with execution of incompatible movements, especially the biological ones. However, the hypothesis that the interference originates within a common neural network, encoding both movement observation and execution, and responding preferentially to biological movements, still awaits confirmation. To test this hypothesis, in the present fMRI study we compared patterns of activation obtained when participants executed finger-movements after having observed either a biological or a non biological model performing compatible (imitative) or incompatible (non imitative) movements. Moreover, we tested the possibility that imitative responses are influenced by the emotional facial expression (sad, neutral, angry) presented before the observed movement. Behaviorally, participants showed a marginally larger compatibility effect (compatible movements faster than incompatible movements) in the biological condition than in the non biological condition. In the imaging data, the interaction testing for areas more active when the observed model was biological (compared with non biological) and performed compatible movements (compared with incompatible movements), activated a network including the motor, premotor and parietal cortices. Notably, the interaction was significant for the neutral and sad facial expressions only. We showed that observing biological movements modulates the activation of motor-related regions, by facilitating the execution of compatible movements and/or interfering with the execution of incompatible movement
Aphasia and limb apraxia are not due to a damage to a unique mechanism: Evidence from a study with left-brain damaged patients
No full textRespiratory burst in activated neutrophis is directly correlated to the intracellular level of protein kinase C
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Modulation of calpastatin specificity in rat tissues by reversible phosphorylation and dephosphorylation.
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