Abstract
Biosorption is a cost-effective and simple technique for removing heavy metals and rare earth elements from aqueous solution. Here, metals were recovered from aqueous solutions using phosphorylated dry baker’s yeast cells. The cells were phosphorylated using cyclo-triphosphate, Na3P3O9. The total P content of the phosphorylated cells was ~1.0 mmol/g dry cell weight (DCW). The zeta potential of the phosphorylated cells was −45 mV, two times higher than for the non-phosphorylated cells. The strong negative charges of the phosphorylated cells allowed the cells to adsorb heavy metal ions such as Cd2+, Cu2+, Pb2+, and Zn2+, the adsorption capacities of which reached ~1.0 mmol/g DCW. This adsorption capacity was the highest level found in the previous studies using yeast dead biomass. The adsorbed metal ions were easily desorbed in 0.1 M HCl. The phosphorylated cells also adsorbed rare earth ions including Ce3+, Dy3+, Gd3+, La3+, Nd3+, Y3+, and Yb3+ with high efficiency. Furthermore, the phosphorylated yeast cells selectively adsorbed the rare earth ions (Nd3+ and Yb3+) from a solution containing heavy metals and rare earth ions because trivalent positively charged ions were adsorbed preferentially over divalent ions. Thus, phosphorylated yeast cells therefore have great potential for use as novel bioadsorbents. It is also expected that this technique can be applied to many microbial materials as well as yeast.
Highlights
Biosorption is a cost-effective and simple technique for removing heavy metals or rare earth elements from effluent
The P content was normalised to the dry cell weight (DCW) of the yeast cells
We investigated the adsorption of metal ions to phosphorylated yeast cells
Summary
Phosphorylation of yeast cells and the properties of the phosphorylated cells. Yeast cells were phosphorylated using P3m following a method previously used to phosphorylate cellulose[22]. Cu2+ adsorption time courses for phospho (+) and phospho (−) cells were compared (Fig. 2) These experiments were performed using a Cu2+ concentration of 100 ppm and a yeast cell concentration of 0.5 mg/mL. Whereas the maximum Cu2+ and Zn2+ adsorption capacities in the previous studies were approximately 0.2 mmol/g DCW, the values in this study were significantly higher (~1.0 mmol/g DCW), which suggests that the phospho (+) cells proposed in this study have broad utility for various types of metal ions. We concluded that 98% of the Cu2+ ions adsorbed to phospho (+) cells could be recovered by treating the cells with HCl
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