INFLUENCE OF SHOOT FORCE ON MOTION VARIABILITY OF TOP SNOOKER PLAYERS

The purpose of this study was to determine the influence of shooting with different force on motion variability of top snooker players. Six professional male players shot with hard force shot (HF) and soft force shot (SF), then coefficient of multiple correlations (CMC) and coefficient of variation (CV) were calculated. In SF, flexion-extension (p=.045) and adduction-abduction (p=.001) of shoulder showed higher CMCs than HF and adduction-abduction (p=.042) of shoulder showed lower CV than HF. In SF, flexion-extension of wrist showed higher CMC (p=.035) and lower CV (p=.030) than HF and adduction-abduction of wrist showed higher CMC (p=.039) and lower CV (p=.036) than HF. There was no difference in CMC and CV of cue. Thus hard force shot might increase motion variability of upper limbs

In situ synthesis of interlinked three-dimensional graphene foam/polyaniline nanorod supercapacitor

Three-dimensional (3-D) graphene foam/PANI nanorods were fabricated by hydrothermal treatment of graphene oxide (GO) solution and sequentially in-situ synthesis of PANI nanorods on the surface of graphene hydrogel. 3-D graphene foam was used as substrate for the growth of PANI nanorods and it increases the specific surface area as well as the double layer capacitance performance of the graphene foam/PANI nanorod composite. The length of the PANI nanorod is about 340 nm. PANI nanorods exhibited a short stick shape. These PANI nanorods agglomerate together and the growth orientation is anisotropic. The highest specific capacitance of 3-D graphene/PANI nanorod composite electrodes is 352 F g−1 at the scan rate of 10 mV s−1.Institute of Textiles and Clothin

Direct in situ synthesis of a 3D interlinked amorphous carbon nanotube/graphene/BaFe12O19 composite and its electromagnetic wave absorbing properties

2016-2017 > Academic research: refereed > Publication in refereed journalbcrcVersion of RecordPublishe

3D multi-nozzle system with dual drives highly potential for 3D complex scaffolds with multi-biomaterials

Recently, additive manufacturing is one of the most focused research topics due to its explosive development, especially in manufacturing engineering and medical science. In order to build 3D complex scaffolds with multi-biomaterials for clinical application, a new 3D multi-nozzle system with dual-mode drives, i.e. ejection and extrusion was developed. In this paper, much effort was made to gain fine control of droplet and excellent coordination during fabrication. Specifically, the parameters that influence the size and stability of droplet most was intensively studied. Considering that the biomaterials used in the future may have much difference in properties, the combination of parameters was investigated to facilitate the settings for certainsized droplets, which are potentially eligible for bio-printing. The dispensing nozzles can work well both in independent and convergent mode, which can be freely switched. Outstanding to the most currently used 3D bio-printing techniques, this system can fabricate scaffolds with multi-materials of both low viscosity (by pneumatic dispensing) and high viscosity (through motor extrusion). It is highly expected that this system can satisfy clinical application in the near future

Fabrication and characterisation of 3D complex hydroxyapatite scaffolds with hierarchical porosity of different features for optimal bioactive performance

To improve the biological performance of hydroxyapatite scaffolds in bone tissue engineering, graphite was used as porogen to create additional micro/nanoporosity to macroporosity, resulting in hierarchical porosity. For maximum imitation of natural bone structures, scaffolds with different porosity features were fabricated using micron/nano-sized graphite. The sintering profile of graphite treated scaffolds was optimised to reduce the influence of shrinkage. To confirm the porosity features, the micro/nanostructures of scaffolds were characterised by scanning electron microscopy and Brunauer-Emmett-Teller method. Considering that hydroxyapatite is resistant to biodegradation in vivo, the degradation rate of scaffolds in modified simulated body fluid was examined. Furthermore, biological evaluations based on myoblasts were carried out to investigate the influence of porosity features on the essential performance such as adhesion, proliferation and differentiation. The results indicate that the scaffolds with dominant microporosity and little nanoporosity formed inside had high potential for clinical applications due to improved performance in bioactivity