Group of Mutagenesis, Department of Genetics and Microbiology, Faculty of Biosciences, Universitat Autònoma de Barcelona, Cerdanyola del Vallès 08193, Spain; Facultad de Recursos Naturales Renovables, Universidad Arturo Prat, Iquique, Chile.
GTS Research Group, Department of Chemistry, Faculty of Science, Universitat Autònoma de Barcelona, Cerdanyola del Vallès 08193, Barcelona, Spain.
J Hazard Mater. 2024 Sep 5;476:135134. doi: 10.1016/j.jhazmat.2024.135134. Epub 2024 Jul 8.
The increased environmental presence of micro-/nanoplastics (MNPLs) and the potential health risks associated with their exposure classify them as environmental pollutants with special environmental and health concerns. Consequently, there is an urgent need to investigate the potential risks associated with secondary MNPLs. In this context, using "true-to-life" MNPLs, resulting from the laboratory degradation of plastic goods, may be a sound approach. These non-commercial secondary MNPLs must be labeled to track their presence/journeys inside cells or organisms. Because the cell internalization of MNPLs is commonly analyzed using fluorescence techniques, the use of fluorescent dyes may be a sound method to label them. Five different compounds comprising two chemical dyes (Nile Red and Rhodamine-B), one optical brightener (Opticol), and two industrial dyes (Amarillo Luminoso and iDye PolyPink) were tested to determine their potential for such applications. Using commercial standards of polystyrene nanoplastics (PSNPLs) with an average size of 170 nm, different characteristics of the selected dyes such as the absence of impact on cell viability, specificity for plastic staining, no leaching, and lack of interference with other fluorochromes were analyzed. Based on the overall data obtained in the wide battery of assays performed, iDye PolyPink exhibited the most advantages, with respect to the other compounds, and was selected to effectively label "true-to-life" MNPLs. These advantages were confirmed using a proposed protocol, and labeling titanium-doped PETNPLs (obtained from the degradation of milk PET plastic bottles), as an example of "true-to-life" secondary NPLs. These results confirmed the usefulness of iDye PolyPink for labeling MNPLs and detecting cell internalization.
微/纳米塑料(MNPLs)在环境中存在增加,以及与其暴露相关的潜在健康风险,使它们成为具有特殊环境和健康问题的污染物。因此,迫切需要研究与次生 MNPLs 相关的潜在风险。在这种情况下,使用实验室降解塑料制品产生的“真实”MNPLs 可能是一种合理的方法。这些非商业性的次生 MNPLs 必须进行标记,以跟踪它们在细胞或生物体内部的存在/旅程。由于 MNPLs 的细胞内化通常使用荧光技术进行分析,因此使用荧光染料可能是标记它们的合理方法。五种不同的化合物,包括两种化学染料(尼罗红和罗丹明 B)、一种光学增亮剂(Opticol)和两种工业染料(Amarillo Luminoso 和 iDye PolyPink),被测试以确定它们在这种应用中的潜力。使用平均粒径为 170nm 的商业标准聚苯乙烯纳米塑料(PSNPLs),分析了所选染料的不同特性,例如对细胞活力没有影响、对塑料染色的特异性、不浸出以及不干扰其他荧光染料。基于在广泛的测定中获得的整体数据,iDye PolyPink 相对于其他化合物表现出更多的优势,并被选中有效地标记“真实”MNPLs。这些优势在使用提议的方案进行验证时得到了确认,并对掺钛的 PETNPLs(从降解牛奶 PET 塑料瓶中获得)进行了标记,作为“真实”次生 NPLs 的示例。这些结果证实了 iDye PolyPink 用于标记 MNPLs 和检测细胞内化的有用性。
