Lignosus rhinocerotis, commonly known as Tiger Milk Mushroom, has been long extolled for its medicinal properties and used for treatment of asthma, cough, fever, cancer, liver-related illnesses, joint pains and as tonic. The history of usage for Tiger Milk Mushroom dates back to almost 400 years, ago but there were no records of scientific studies done due to inavailability of sufficient samples. Even when there were samples collected from the wild, the supply and quality was inconsistent. With the advent of cultivation success of one of the most utilized species of Tiger milk mushroom (L. rhinocerotis) in 2009 (known as TM02), scientific investigation was done to validate its traditional use and to investigate its safety for consumption, biochemical and biopharmacological properties. Preclinical toxicology evaluations showed that TM02 did not induce adverse effects on fertility. It also poses neither teratogenic effects nor genotoxicity. The no-observed-adverse-effect level (NOAEL) dose of the TM02 in 180-day chronic toxicity study is 1000 mg/kg which is equivalent to 162 mg/kg human dose, anticipated dose for a 60 kg adult is ~10g. The effective dosage of TM02 is as low as 0.5g per day for an adult. There is therefore, a huge margin for the safe consumption of TM02. TM02 is proven to be effective in supporting the lung and respiratory health, immune health, maintenance of joint health (caused by inflammation), improving vitality and stamina and improving the quality of life for cancer patients. Recent scientific findings have shown that TM02 contains various active components such as the polysaccharides-protein complexes, β-glucans, proteins, immuno-modulatory proteins all of which could play possible roles in rendering significant therapeutic properties such as anti-inflammatory, immuno-modulatory, anti-proliferative, anti-oxidative, neurite outgrowth stimulation etc. The revelation of the genome, transcriptome, proteome of L. rhinocerotis by MMRG has provided valuable insights into the biomolecule discovery and provided the foundation for future research and exploitation of L. rhinocerotis in pharmacological and functional food applications. These data forms a valuable foundation for future research in the exploitation of the L. rhinocerotis in pharmacological and industrial applications.

This paper presents a study of large grains by transmission electron microscopy in two WC-Co alloys, one W rich and one C rich. In the W rich alloy, some large grains are found in contact with the phase. The C content influences the morphology of large grains: they are flatter in the C rich alloy with smoother interfaces. Whatever the C content, they contain few dislocations compared to matrix grains except often in a small area. Small WC grains are often found inside the large grains. They have likely been engulfed during the growth of the large grains owing to the low boundary energy.

The driving forces and the probable processes of WC-Co grain growth are reanalysed from recent data of interface energy and microstructure. Grain growth is driven by the disappearing of the high energy WC/WC and WC/Co interfaces with habit planes different from {0001}, and facets and by the area decrease of the WC/WC and WC/Co interfaces with {0001} and habit planes. Grain growth mainly results of dissolution-precipitation. Abnormal grains are likely formed by defects assisted nucleation.

A steel/cemented carbide couple is selected to generate a tough/hard two layers material. Sintering temperature and composition are deduced from phase equilibria, and experimental studies are used to determine optimal conditions. Liquid migration from the hard layer to the tough one is observed. Microstructure evolution during sintering of the tough material (TEM, SEM, image analysis) evidences coupled mechanisms of pore reduction and WC dissolution. Liquid migration, as well as interface crack formation due to differential densification are limited by suitable temperature and time conditions.

Processing of W-Cu graded materials from attritor-milled W-CuO mixtures is described. The powder reduction steps are investigated by TG and XRD analyses and by microstructural observations (SEM, TEM). Sintering of reduced powder with different compositions is analysed by dilatometry. Sintering behaviour of the graded component processed by co-compaction of a 10/20/30wt%Cu multi-layer material is briefly discussed. Liquid Cu migration is observed and smooths the composition gradient. Perspectives to control this migration are discussed.

This parametric study investigates the effect of significant parameters on the elastic global lateral torsional buckling capacity of horizontally curved twin I-girder systems. Included are the effect of curvature and the effect of girder spacing. Twin I-girder systems analyzed in this study are those which are interconnected by intermediate cross frames and are subjected to uniform moment. The finite element analysis software, ABAQUS, is used to model the horizontally curved twin I-girder system and conduct the buckling analysis. To see the significant effect of curvature and girder spacing, the results from the finite element analysis of horizontally curved twin I-girder systems are compared to the results of a closed form solution for straight twin I-girder systems. The findings of this parametric study will be shown using illustrative figures and tabulated data and conclusions are made.