Nanotoxicity of ZrS₃ Probed in a Bioluminescence Test on <i>E. coli</i> Bacteria: The Effect of Evolving H₂S

Materials from a large family of transition metal trichalcogenides (TMTCs) attract considerable attention because of their potential applications in electronics, optoelectronics and energy storage, but information on their toxicity is lacking. In this study, we investigated the toxicity of ZrS₃, a prominent TMTC material, toward photoluminescent <i>E. coli</i> bacteria in a bioluminescence test. We found that freshly prepared ZrS₃ suspensions in physiological saline solution with concentrations as high as 1 g/L did not exhibit any toxic effects on the bacteria. However, ZrS₃ suspensions that were stored for 24 h prior to the bioluminescence tests were very toxic to the bacteria and inhibited their emission, even at concentrations down to 0.001 g/L. We explain these observations by the aqueous hydrolysis of ZrS₃, which resulted in the formation of ZrO_x on the surface of ZrS₃ particles and the release of toxic H₂S. The formation of ZrO_x was confirmed by the XPS analysis, while the characteristic H₂S smell was noticeable for the 24 h suspensions. This study demonstrates that while ZrS₃ appears to be intrinsically nontoxic to photoluminescent <i>E. coli</i> bacteria, it may exhibit high toxicity in aqueous media. The results of this study can likely be extended to other transition metal chalcogenides, as their toxicity in aqueous solutions may also increase over time due to hydrolysis and the formation of H₂S. The results of this study also demonstrate that since many systems involving nanomaterials are unstable and evolve over time in various ways, their toxicity may evolve as well, which should be considered for relevant toxicity tests.