Sensory processing abilities and their relation to participation in leisure activities among children with high-functioning autism spectrum disorder (HFASD)

Children with autism may have atypical sensory processing abilities, which are known to impact child's performance and participation. However, lack of information exists regarding the expression of these abilities in specific groups on the spectrum, as children with high-functioning autism spectrum disorder (HFASD). This study aimed to characterize the sensory processing abilities of children with HFASD and examine their relationship to participation in leisure activities. Participants were 50 children aged 6–11 years: 25 children with HFASD and 25 with typical development. Sensory processing abilities were examined by the short sensory profile (SSP). Participation was assessed by the children's assessment of participation and enjoyment (CAPE). Children with HFASD had atypical sensory processing abilities. They also had lower participation in leisure activities expressed in limited range of activities, performed less often, mainly alone and at home. Their atypical sensory processing patterns were correlated with lower participation, specifically in social, physical and informal activities. In conclusion, children with HFASD may have atypical sensory processing abilities and restricted participation. Intervention should refer to each of these parameters and to the relationship between them in order to enable optimal inclusion of children with HFASD in society.     

Listen to your heart beat and shiver! An experimental study of anxiety-related emotional reasoning in children

The present study investigated anxiety-related emotional reasoning in 9–13-year-old children using an experimental approach. Eighty-one children completed a computerized ambiguous situations test for assessing their perception of threat under two conditions. In the experimental condition, children were attached to an apparatus that allegedly recorded their heart beat, the sound of which was presented to them via headphones. In the control condition, children listened to the sound of an African djembe drum while completing the ambiguous situations test. It was found that children in the experimental condition generally provided higher threat ratings than children in the control condition, and this difference remained significant when controlling for levels of anxiety sensitivity, panic and other anxiety symptoms. These results are in keeping with the idea that children may partially rely on internal physical sensations when evaluating the dangerousness of ambiguous events.     

The effect of a computerized visual perception and visual-motor integration training program on improving Chinese handwriting of children with handwriting difficulties

This study aimed to investigate the effect of a computerized visual perception and visual-motor integration training program to enhance Chinese handwriting performance among children with learning difficulties, particularly those with handwriting problems. Participants were 26 primary-one children who were assessed by educational psychologists and occupational therapists to have handwriting difficulties. They were matched according to their age and then randomly assigned into either the control group or the experimental group. Subjects in the experimental group (n = 13) would receive eight sessions of computerized visual perception and visual-motor integration training together with a home training program while those in the control group (n = 13) would only receive conventional handwriting training by teachers, which focused mainly on remedial handwriting exercises. Results from repeated measure ANOVA revealed that children in the experimental group showed improvements in their visual perception skills as well as in their handwriting time. Both the “On Paper” time and “In Air” time of this group were improved when compared to the control group. However, no significant differences were found in visual-motor integration skill and handwriting legibility between the two groups after the intervention. This computerized training program focusing on visual perception and visual-motor integration training appeared to be effective in enhancing the handwriting time among children with handwriting difficulties. However, the training program did not seem to improve the legibility of children.     

Home-based motor imagery training for gait rehabilitation of people with chronic poststroke hemiparesis

Dunsky A, Dickstein R, Marcovitz E, Levy S, Deutsch J. Home-based motor imagery training for gait rehabilitation of people with chronic poststroke hemiparesis.

Objective

To test the feasibility and efficacy of a home-based motor imagery gait training program to improve walking performance of individuals with chronic poststroke hemiparesis.

Design

Nonrandomized controlled trial.

Setting

Local facility.

Participants

Participants (N=17) were community-dwelling volunteers with hemiparesis caused by a unilateral stroke that occurred at least 3 months before the study.

Intervention

Participants received 15 minutes of supervised imagery gait training in their homes 3 days a week for 6 weeks. The intervention addressed gait impairments of the affected lower limb and task-specific gait training. Walking ability was evaluated by kinematics and functional scales twice before the intervention, 3 and 6 weeks after the intervention began, and at the 3-week follow-up.

Main Outcome Measures

Spatiotemporal, kinematic, and functional walking measurements.

Results

Walking speed increased significantly by 40% after training, and the gains were largely maintained at the 3-week follow-up. The effect size of the intervention on walking speed was moderate (.64). There were significant increases in stride length, cadence, and single-support time of the affected lower limb, whereas double-support time was decreased. Improvements were also noted on the gait scale of the Tinetti Performance-Oriented Mobility Assessment as well as in functional gait. Sixty-five percent of the participants advanced 1 walking category in the Modified Functional Walking Categories Index.

Conclusions

Although further study is recommended, the findings support the feasibility and justify the incorporation of home-based motor imagery exercises to improve walking skills for poststroke hemiparesis.     

Distinct brain mechanisms support spatial vs temporal filtering of nociceptive information

The role of endogenous analgesic mechanisms has largely been viewed in the context of gain modulation during nociceptive processing. However, these analgesic mechanisms may play critical roles in the extraction and subsequent utilization of information related to spatial and temporal features of nociceptive input. To date, it remains unknown if spatial and temporal filtering of nociceptive information is supported by similar analgesic mechanisms. To address this question, human volunteers were recruited to assess brain activation with functional magnetic resonance imaging during conditioned pain modulation (CPM) and offset analgesia (OA). CPM provides one paradigm for assessing spatial filtering of nociceptive information while OA provides a paradigm for assessing temporal filtering of nociceptive information. CPM and OA both produced statistically significant reductions in pain intensity. However, the magnitude of pain reduction elicited by CPM was not correlated with that elicited by OA across different individuals. Different patterns of brain activation were consistent with the psychophysical findings. CPM elicited widespread reductions in regions engaged in nociceptive processing such as the thalamus, insula, and secondary somatosensory cortex. OA produced reduced activity in the primary somatosensory cortex but was associated with greater activation in the anterior insula, dorsolateral prefrontal cortex, intraparietal sulcus, and inferior parietal lobule relative to CPM. In the brain stem, CPM consistently produced reductions in activity, while OA produced increases in activity. Conjunction analysis confirmed that CPM-related activity did not overlap with that of OA. Thus, dissociable mechanisms support inhibitory processes engaged during spatial vs temporal filtering of nociceptive information.     

Pain sensitivity is inversely related to regional grey matter density in the brain

Pain is a highly personal experience that varies substantially among individuals. In search of an anatomical correlate of pain sensitivity, we used voxel-based morphometry to investigate the relationship between grey matter density across the whole brain and interindividual differences in pain sensitivity in 116 healthy volunteers (62 women, 54 men). Structural magnetic resonance imaging (MRI) and psychophysical data from 10 previous functional MRI studies were used. Age, sex, unpleasantness ratings, scanner sequence, and sensory testing location were added to the model as covariates. Regression analysis of grey matter density across the whole brain and thermal pain intensity ratings at 49 °C revealed a significant inverse relationship between pain sensitivity and grey matter density in bilateral regions of the posterior cingulate cortex, precuneus, intraparietal sulcus, and inferior parietal lobule. Unilateral regions of the left primary somatosensory cortex also exhibited this inverse relationship. No regions showed a positive relationship to pain sensitivity. These structural variations occurred in areas associated with the default mode network, attentional direction and shifting, as well as somatosensory processing. These findings underscore the potential importance of processes related to default mode thought and attention in shaping individual differences in pain sensitivity and indicate that pain sensitivity can potentially be predicted on the basis of brain structure.     

Clinical Effects of Repetitive Transcranial Magnetic Stimulation of the Motor Cortex Are Associated With Changes in Resting-State Functional Connectivity in Patients With Fibromyalgia Syndrome

In this double-blinded, sham-controlled, counterbalanced, and crossover study, we investigated the potential neuroplasticity underlying pain relief and daily function improvements following repetitive transcranial magnetic stimulation of the motor cortex (M1-rTMS) in fibromyalgia syndrome (FMS) patients. Specifically, we used magnetic resonance imaging (MRI) to examine changes in brain structural and resting-state functional connectivity (rsFC) that correlated with improvements in FMS symptomology following M1-rTMS. Twenty-seven women with FMS underwent real and sham treatment series, each consisting of 10 daily treatments of 10Hz M1-rTMS over 2 weeks, with a washout period in between. Before and after each series, participants underwent anatomical and resting-state functional MRI scans and questionnaire assessments of FMS-related clinical pain and functional and psychological burdens. The expected reductions in FMS-related symptomology following M1-rTMS occurred with the real treatment only and correlated with rsFC changes in brain areas associated with pain processing and modulation. Specifically, between the ventromedial prefrontal cortex and the M1 (t = -5.54, corrected P = .002), the amygdala and the posterior insula (t = 5.81, corrected P = .044), and the anterior and posterior insula (t = 6.01, corrected P = .029). Neither treatment significantly changed brain structure. Therefore, we provide the first evidence of an association between the acute clinical effects of M1-rTMS in FMS and functional alterations of brain areas that have a significant role in the experience of chronic pain. Structural changes could potentially occur over a more extended treatment period.PerspectiveWe show that the neurophysiological mechanism of the improvement in fibromyalgia symptoms following active, but not sham, rTMS applied to M1 involves changes in resting-state functional connectivity in sensory, affective and cognitive pain processing brain areas, thus substantiating the essence of fibromyalgia syndrome as a treatable brain-based disorder.