55 research outputs found
Effects of time-compressed speech training on multiple functional and structural neural mechanisms involving the left superior temporal gyrus
Time-compressed speech is an artificial form of rapidly presented speech.
Training with time compressed speech in a second language leads to adaptation toward
time-compressed speech in a second language and toward time compressed speech in
different languages. However, the effects of training with time-compressed speech of a
second language (TCSSL) on diverse cognitive functions and neural mechanisms
beyond time compressed speech-related activation are unknown. We investigated the
effects of 4 weeks of training with TCSSL on the fractional amplitude of spontaneous
low-frequency fluctuations (fALFF) of 0.01â0.08 Hz, resting-state functional
connectivity (RSFC) with the left superior temporal gyrus (STG), fractional anisotropy
(FA), and regional gray matter volume (rGMV) of young adults by magnetic resonance
imaging. There were no significant differences in change of performance of measures of
cognitive functions or second language skills after training with TCSSL compared with
that of the active control group. However, compared with the active control group,
training with TCSSL was associated with increased fALFF, RSFC, and FA and
decreased rGMV involving areas in the left STG. These results lacked evidence of a far
transfer effect of time compressed speech training on a wide range of cognitive
functions and second language skills in young adults. However, these results
demonstrated effects of time compressed speech training on gray and white matter
structures as well as on resting-state intrinsic activity and connectivity involving the left
STG, which plays a key role in listening comprehension
Lenticular nucleus correlates of general self-efficacy in young adults
General self-efficacy (GSE) is an important factor in education, social participation, and medical treatment. However, the only study that has investigated the direct association between GSE and a neural correlate did not identify specific brain regions, rather only assessed brain structures, and included older adult subjects. GSE is related to motivation, physical activity, learning, the willingness to initiate behaviour and expend effort, and adjustment. Thus, it was hypothesized in the present study that the neural correlates of GSE might be related to changes in the basal ganglia, which is a region related to the abovementioned self-efficacy factors. This study aimed to identify the brain structures associated with GSE in healthy young adults (n = 1204, 691 males and 513 females, age 20.7 Âą 1.8 years) using regional grey matter density and volume (rGMD and rGMV), fractional anisotropy (FA) and mean diffusivity (MD) analyses of magnetic resonance imaging (MRI) data. The findings showed that scores on the GSE Scale (GSES) were associated with a lower MD value in regions from the right putamen to the globus pallidum; however, there were no significant association between GSES scores and regional brain structures using the other analyses (rGMD, rGMV, and FA). Thus, the present findings indicated that the lenticular nucleus is a neural correlate of GSE
Regional homogeneity, resting-state functional connectivity and amplitude of low frequency fluctuation associated with creativity measured by divergent thinking in a sex-specific manner
Brain connectivity is traditionally thought to be important for creativity. Here we investigated the associations of creativity measured by divergent thinking (CMDT) with resting-state functional magnetic imaging (fMRI) measures and their sex differences. We examined these relationships in the brains of 1277 healthy young adults. Whole-brain analyses revealed a significant interaction between verbal CMDT and sex on (a) regional homogeneity within an area from the left anterior temporal lobe (b) on the resting state functional connectivity (RSFC) between the mPFC and the left inferior frontal gyrus and (c) on fractional amplitude of low frequency fluctuations (fALFF) in several distinct areas, including the precuneus and middle cingulate gyrus, left middle temporal gyrus, right middle frontal gyrus, and cerebellum. These interactions were mediated by positive correlations in females and negative correlations in males. These findings suggest that greater CMDT in females is reflected by (a) regional coherence (regional homogeneity) of brain areas responsible for representing and combining concepts as well as (b) the efficient functional connection (RSFC) between the key areas for the default state of cognitive activity and speech production, and (c) greater spontaneous neural activity (fALFF) during the resting of brain areas involved in frontal lobe functions, default cognitive activities, and language functions. Furthermore, these findings suggest that the associations between creativity and resting state brain connectivity patterns are different between males and females
Results of a multiple regression analysis of change in salivary cortisol levels before and after the earthquake.
*<p>β: Standardized Coefficients.</p><p>R<sup>2</sup> : R Squar.</p><p>P: Significance probability.</p
Statistics for the response time (RT) predictivity of the nine temporally coherent networks (TCNs) at pre-trial time points (<i>t</i>â=ââ6.0 to 0.0 s).
<p>Each cell shows the <i>t</i>-value (dfâ=â47) of the two-tailed one sample <i>t</i>-test of the mean coefficient of RT-predictive ANCOVA model over subjects, with a braced false discovery rate (FDR)-corrected <i>p</i>-value.</p
Distribution of response time (RT) for the Stroop task (A) and simple response task (B).
<p>Data of all subjects were concatenated.</p
Experimental paradigm.
<p>(A) The Stroop task for fMRI sessions. In each trial, subjects were required to indicate the position of a surrounding word that names the font color of the central word. All the words used were colorâword incongruent. (B) Control task outside the scanner. Subjects were required to simply replicate the directions indicated by the arrows. (C) Distribution of inter-stimulus intervals (ISIs) across trials for both tasks.</p
Ongoing Activity in Temporally Coherent Networks Predicts Intra-Subject Fluctuation of Response Time to Sporadic Executive Control Demands
<div><p>Can ongoing fMRI BOLD signals predict fluctuations in swiftness of a personâs response to sporadic cognitive demands? This is an important issue because it clarifies whether intrinsic brain dynamics, for which spatio-temporal patterns are expressed as temporally coherent networks (TCNs), have effects not only on sensory or motor processes, but also on cognitive processes. Predictivity has been affirmed, although to a limited extent. Expecting a predictive effect on executive performance for a wider range of TCNs constituting the cingulo-opercular, fronto-parietal, and default mode networks, we conducted an fMRI study using a version of the colorâword Stroop task that was specifically designed to put a higher load on executive control, with the aim of making its fluctuations more detectable. We explored the relationships between the fluctuations in ongoing pre-trial activity in TCNs and the task response time (RT). The results revealed the existence of TCNs in which fluctuations in activity several seconds before the onset of the trial predicted RT fluctuations for the subsequent trial. These TCNs were distributed in the cingulo-opercular and fronto-parietal networks, as well as in perceptual and motor networks. Our results suggest that intrinsic brain dynamics in these networks constitute âcognitive readiness,â which plays an active role especially in situations where information for anticipatory attention control is unavailable. Fluctuations in these networks lead to fluctuations in executive control performance.</p></div
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