Abstract
Industrialization and technological advancements have led to the exploitation of natural resources and the production of hazardous wastes, including electronic waste (E-waste). The traditional physical and chemical techniques used to combat E-waste accumulation have inherent drawbacks, such as the production of harmful gases and toxic by-products. These limitations may be prudently addressed by employing green biological methods, such as biosorption and bioleaching. Therefore, this study was aimed at evaluating the biosorption and bioleaching potential of seven microbial cultures using E-waste (printed circuit board (PCB)) as a substrate under submerged culture conditions. The cut pieces of PCB were incubated with seven microbial cultures in liquid broth conditions in three replicates. Atomic absorption spectroscopy (AAS) analysis of the culture biomass and culture filtrates was performed to evaluate and screen the better-performing microbial cultures for biosorption and bioleaching potentials. The best four cultures were further evaluated through SEM, energy-dispersive X-ray spectroscopy (EDX), and sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) studies to identify the possible culture that can be utilized for the biological decontamination of E-waste. The study revealed the highest and differential ability of Pleurotus florida and Pseudomonas spp. for biosorption and bioleaching of copper and iron. This can be attributed to bio-catalysis by the laccase enzyme. For both P. florida and Pseudomonas spp. on the 20th day of incubation, laccase exhibited higher specific activity (6.98 U/mg and 5.98 U/mg, respectively) than other microbial cultures. The biomass loaded with Cu2+ and Fe2+ ions after biosorption was used for the desorption process for recovery. The test cultures exhibited variable copper recovery efficiencies varying between 10.5 and 18.0%. Protein characterization through SDS-PAGE of four promising microbial cultures exhibited a higher number of bands in E-waste as compared with microbial cultures without E-waste. The surface topography studies of the E-waste substrate showed etching, as well as deposition of vegetative and spore cells on the surfaces of PCB cards. The EDX studies of the E-waste showed decreases in metal element content (% wt/% atom basis) on microbial treatment from the respective initial concentrations present in non-treated samples, which established the bioleaching phenomenon. Therefore, these microbial cultures can be utilized to develop a biological remediation method to manage E-waste.
Highlights
Advanced technological devices, including mobile phones, laptops, fitness trackers, and Wi-Fi modems, have been indispensable commodities for urban and peri-urban dwellers
The variability in the metal content concentrations may be attributed to the type of printed circuit boards (PCBs) electronic waste (E-waste) sample, which may have been different in these studies
Similar to the results presented for A. niger, it was observed that the bioleaching of metals from E-waste circuit boards was efficiently carried out by acidophilic fungi; the presence of precipitated E-waste particles on the surface of the cell wall of Aspergillus niger DDNSI was observed through scanning electron microscopy (SEM) [63]
Summary
Advanced technological devices, including mobile phones, laptops, fitness trackers, and Wi-Fi modems, have been indispensable commodities for urban and peri-urban dwellers. E-waste consists primarily of various components of discarded electronic products, such as printed circuit boards (PCBs), printers, photocopiers, television sets, refrigerators, and mobile phones that are broken beyond repair or are technologically obsolete [2]. It consists of large quantities of heavy metals, including arsenic, antimony, cadmium, chromium, copper, iron, lead, mercury, zinc, and certain organic contaminants [3]. E-wastes are non-biodegradable, and get accumulated in the soil and water, causing a serious threat to living organisms and the ecosystem Most of these heavy metals, even at very low concentrations, are highly toxic and impose serious damage to living organisms by entering the food chain [4]. To save the ecosystem from getting contaminated, there is a dire need to create awareness for extracting useful metals present in the E-waste
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