Rubberwood is the most popular timber for furniture manufacturing industry in Malaysia. Major drawback concerned
that rubberwood is very prone to attack by fungi and wood borers, and the preservation method using boron compounds
exhibited hazardous effect to the workers. Fungal-based biological control agents have gained wide acceptance and
Schizophyllum commune secondary metabolite played an important role in term of antifungal agent productivity. The
effects of initial pH, incubation temperature and agitation on biomass production by S. commune were investigated
under submerged shake culture. In this work, it was found that the synthetic medium with initial solution pH of 6.5
and incubated at 30ºC with shaking at 150 rpm provided the highest biomass production. The biomass extract from
S. commune was then applied onto the rubberwood block panel to investigate its effectiveness. The results showed
that biomass extract at a concentration of 5 µg/µL could inhibit the growth of selected rubberwood-degrading fungi,
such as Lentinus sp., L. strigosus and Pycnoporus sanguineus.
Timber scaffold boards have been widely utilised in the offshore construction industry. However, technical specifications
and inspection procedure for the application of scaffold boards from a wood material were inadequate. In the development
of the standard requirements, evaluation of actual engineering practices could indicate the level of workplace safety. A
study was conducted to identify risk and safety measures concerning the use of timber scaffold boards in construction.
This article discusses on the occupational risks and ergonomics issues of the scaffolding application based on the physical
and mechanical conditions of tropical timber scaffold boards extracted from offshore oil and gas rigs. The boards were
exposed to a seasonal climate of East Coast monsoon of South China Sea between November and February. The scaffolding
application extended up to 20 m directly above the ocean surface and some boards were completely immersed below
the ocean surface particularly during elevated tidal waves. Some of the boards were installed as the on-deck platforms.
Forty scaffold boards fabricated from tropical timber species were evaluated. Physical characteristics of the boards
were described by natural and man-made factors. A three-point bending test was conducted to determine the maximum
load capacity of each board and the mode of fracture was evaluated. Timber identification test was conducted to identify
the groups of the timber being used. The microscopic observation confirmed the presence of hyphae which indicated the
biological deterioration has happened in some of the boards. Occupational risks were summarised based on the results
of the physical and mechanical assessments
Generation of huge volumes of lignocellulosic biomass from agricultural sector is of concern due to its direct effects on the depletion of overall environmental quality. Conversion of biomass into solid biofuel through pyrolysis reaction has become one of the solutions to manage the abundance of biomass. Pyroligneous acid (PA) produced from the condensation of smoke generated during biomass carbonization process has the potential to be applied in various applications based on the diverse active chemical compounds present. In this study, PA obtained from palm kernel shell (PKS) was evaluated for antifungal activity and solid pineapple biomass (PB) was evaluated for antibacterial and plant growth promoter activities. Higher antifungal activity was determined for crude PA from PKS (PA-PKS) and dichloromethane-extract (DPA-PKS) with 0% coverage area when evaluated using rubber wood blocks against mold and blue sapstain after for 4 weeks of observation. This antifungal activity can be attributed to the presence of phenols and its major derivatives as suggested from the GC-MS and FTIR analysis. Concentrated PA from PB displayed good antibacterial capabilities with almost similar growth inhibition for Escherichia coli (13±1 to 20±1 mm) and Corynebacterium agropyri (20±1 mm). PA-PB also showed good potential as PGP where the addition of 2% (v/v) of PA-PB into the fertilizer for okra plant resulted in highest number of leaves and fruits while 4% (v/v) PA-PB managed to give highest plant height, longest root, heaviest fruits and biggest leaf diameter. Thus, this study successfully demonstrated the potential use of PA obtained from lignocelluosic biomass in various applications.