High prevalence of Pseudomonas species in soil samples from Ternate Island-Indonesia.

In the present study, Ten soil samples were examined and the pH of the soil was recorded. For bacterial isolation, a sterile nutrient and blood agars were used. Gram stain and biochemical tests were done for identification. A total of 384 genus were isolated, 314 (81.8%) were identified as Pseudomonas species of which 245 (78.0%) were Pseudomonas aeruginosa, 42 (13.4%) were Pseudomonas fluorescens, 13 (4.2%) were Pseudomonas mallei, 10 (3.1%) were Pseudomonas putida and 4 (1.3%) were Pseudomonas syringe and are regarded as pathogenic and harmful to man, animal and plants. This study shows that Pseudomonas aeruginosa had a high adaptation capability to grow in soil samples from Ternate, Indonesia. The rest of the bacterial isolates (18.2%) were identified as follows: 24 samples (6.2%) were Micrococcus, 23 samples (6.0%) were E. coli, 12 samples (3.1%) were Pasteurella and 11 samples (2.9%) were Staphylococcus. Pencillium was also isolated.

Effect of some environmental parameters on hydrogen production using C. acetobutylicum.

The aim of this study was to investigate the influence of some environmental factors on bacterial metabolism. Fermentative hydrogen production by C. acetobutylicum, using glucose as the substrate. The effect of initial pH (4-8), inoculum size (1-20% (v/v)) and glucose concentration (1-30 g L(-1)) on hydrogen production were studied. The optimum cultivation temperature for hydrogen production was at 30 degrees C. The results show that substrate concentration and inoculum size resulted in hydrogen yield (Y(P/S)) of 391 mL g(-1) glucose utilized with maximum hydrogen productivity of 77.5 mL/L/h. Higher substrate concentration or inoculum size adversely affects hydrogen production, which decreases hydrogen yield by 15% to 334 mL g(-1) glucose utilized when 30% (v/v) inoculum size was used. The use of 30 g L(-1) substrate concentration resulted in a 75% decrease to 97 mL g(-1) glucose supplied. Concluded that proper Xo/So enhanced the hydrogen production.

Removal of headspace CO2 increases biological hydrogen production by C. acetobutylicum.

The effect of removal of resultant gas resulted in enhancement of the H2 yield. The technique of CO2 scavenging resulted in H2 yield being improved from 408 mL g(-1) to reach the maximum of 422 mL g'. The highest hydrogen productivity of 87.9 ml L(-1) h(-1) was obtained by CO2 scavenging. Biomass concentration was enhanced to 1.47 g L(-1), Y(P,X) of 287 ml g(-1) L(-1), Y(X/S) of 0.294 and Y(H2/s) of 0.0377 by the use of CO2 scavenging. The results suggested that the presence of the gaseous products in fermentation medium and headspace adversely effect biomass growth and hydrogen production.