Functional and structural brain differences associated with mirror-touch synaesthesia

Observing touch is known to activate regions of the somatosensory cortex but the interpretation of this finding is controversial (e.g. does it reflect the simulated action of touching or the simulated reception of touch?). For most people, observing touch is not linked to reported experiences of feeling touch but in some people it is (mirror-touch synaesthetes). We conducted an fMRI study in which participants (mirror-touch synaesthetes, controls) watched movies of stimuli (face, dummy, object) being touched or approached. In addition we examined whether mirror touch synaesthesia is associated with local changes of grey and white matter volume in the brain using VBM (voxel-based morphometry). Both synaesthetes and controls activated the somatosensory system (primary and secondary somatosensory cortices, SI and SII) when viewing touch, and the same regions were activated (by a separate localiser) when feeling touch — i.e. there is a mirror system for touch. However, when comparing the two groups, we found evidence that SII seems to play a particular important role in mirror-touch synaesthesia: in synaesthetes, but not in controls, posterior SII was active for watching touch to a face (in addition to SI and posterior temporal lobe); activity in SII correlated with subjective intensity measures of mirror-touch synaesthesia (taken outside the scanner), and we observed an increase in grey matter volume within the SII of the synaesthetes' brains. In addition, the synaesthetes showed hypo-activity when watching touch to a dummy in posterior SII. We conclude that the secondary somatosensory cortex has a key role in this form of synaesthesia

The PAIDOS/Department of Health Policy Neonatal Fellowship in Outcomes Research

No abstract available

An acoustic multi-touch sensing method using amplitude disturbed ultrasonic wave diffraction patterns

This paper proposes an acoustic multi-touch tactile sensing method. The proposed method is based on an amplitude disturbed ultrasonic wave diffraction pattern. An A0 Lamb wave transmitted in a thin finite copper plate is processed to provide tactile information, for one or two fingers. A touch event is localized by identifying the diffraction signals among a database of diffracted Lamb wave references. Statistic models are used to improve the localization reliability. An artificial silicone finger is used in the calibration procedure. This touch interface is evaluated as a 2-touch interface

Around the table: Are multiple-touch surfaces better than single-touch for children's collaborative interactions?

This paper presents a classroom study that investigated the potential of using touch tabletop technology to support children's collaborative learning interactions. Children aged 7-10 worked in groups of three on a collaborative planning task in which they designed a seating plan for their classroom. In the single-touch condition, the tabletop surface allowed only one child to interact with the digital content at a time. In the multiple-touch condition, the children could interact with the digital content simultaneously. Results showed that touch condition did not affect the frequency or equity of interactions, but did influence the nature of children's discussion. In the multiple-touch condition, children talked more about the task; in the single-touch condition, they talked more about turn taking. We also report age and gender differences

Assessment of sensorial comfort of fabrics for protective clothing

Protection and comfort are important issues for protective clothing and an appropriate protection is most of the times detrimental for overall clothing comfort. The tactile or sensorial comfort is related to the mechanical interaction between the garment and the human body. Fabric Hand and Fabric Touch are two crucial elements that express how consumers experience textiles by touching them with the fingers and respectively by wearing them. Both subjective and objective methods are used to assess the fabric hand and touch. Within the ongoing CORNET project Touché both subjective methods (e.g. blind tests, questionnaires) and innovative instruments (e.g. FTT, TSA) are employed for assessment of fabric hand and touch. The Fabric Touch Tester (FTT) enables fast and simultaneous assessment of 13 physical fabric indices (e.g. bending, compression, friction, roughness and thermal conductivity) and uses these indices to predict comfort primary indexes such as smoothness, softness, warmness, total hand and total touch. It could be therefore a promising, very fast selection method of fabrics that will eventually lead to clothing with high sensorial comfort. Fabrics with similar weight and thickness were tested aiming at identifying possible significant differences between the samples