In an effort to develop alternate techniques to recover metals from waste electrical
and electronic equipment (WEEE), this research evaluated the bioleaching efficiency
of gold (Au), copper (Cu) and nickel (Ni) by two strains of Aspergillus
niger in the presence of gold-plated finger integrated circuits found in
computer motherboards (GFICMs) and cellular phone printed circuit boards (PCBs).
These three metals were analyzed for their commercial value and their diverse
applications in the industry. Au-bioleaching ranged from 42 to 1% for
Aspergillus niger strain MXPE6; with the combination of
Aspergillus niger MXPE6 + Aspergillus niger MX7,
the Au-bioleaching was 87 and 28% for PCBs and GFICMs, respectively. In contrast, the
bioleaching of Cu by Aspergillus niger MXPE6 was 24 and 5%; using
the combination of both strains, the values were 0.2 and 29% for PCBs and GFICMs,
respectively. Fungal Ni-leaching was only found for PCBs, but with no significant
differences among treatments. Improvement of the metal recovery efficiency by means
of fungal metabolism is also discussed.
ABSTRACT. DNA isolation from some fungal organisms of agronomic importance is difficult because they have cell walls or capsules that are relatively unsusceptible to lysis. We have developed a fast DNA isolation protocol for Fusarium oxysporum, which causes fusarium wilt disease in more than 100 plant species, and for Pyrenochaeta terrestris, which causes pink root in onions. This protocol was based on the sodium dodecyl sulfate/ phe nol method, without β-mercaptoethanol and without maceration in liquid nitrogen; it uses phenol/chloroform extraction to remove proteins and co-precipitated polysaccharides. The A 260/280 absorbance ratios of isolated DNA were around 1.9, suggesting that the DNA fraction was pure and may be used for further analysis. Additionally, the A 260/230 values were higher than 1.8, suggesting negligible contamination by polysaccharides. The DNA isolated by this protocol is of sufficient quality for molecular applications; this tech nique could be applied to other organisms that have similar substances that hinder DNA extraction.
Hydrometallurgical and pyrometallurgical processes to recover gold (Au) from cell-phone printed circuit boards (PCBs) have the disadvantage of generating corrosive residues and consuming a large amount of energy. Therefore, it is necessary to look for biological processes that have low energy consumption and are friendly to the environment. Among the biological alternatives for the recovery of Au from PCB is the use of cyanogenic bacteria and filamentous fungi in cultures with agitation. Considering that it is important to explore the response of microorganisms in cultures without agitation to reduce energy expenditure in the recovery of metals from PCB, the present investigation evaluated the capacity of Aspergillus niger MXPE6 and a fungal consortium to induce Au bioleaching from PCB in a culture medium with glucose as a carbon source and without agitation (pH 4.5). The results indicate that the treatments with PCB inoculated with the fungal consortium showed a considerable decrease in pH (2.8) in comparison with the treatments inoculated with A. niger MXPE6 (4.0). The fungal consortium showed a significantly higher Au bioleaching (56%) than A. niger MXPE6 (17%). Finally, the use of fungal consortia grown without agitation could be an alternative to recover metals from PCB, saving energy and material resources.
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