Rimoldi, S.; Ponti, J.; Valsesia, A.; Saroglia, G.; La Spina, R.; Fumagalli, F.; Terova, G. Detection of Microplastic Contamination in Commercial Insect Meals. Environments2024, 11, 112.
Rimoldi, S.; Ponti, J.; Valsesia, A.; Saroglia, G.; La Spina, R.; Fumagalli, F.; Terova, G. Detection of Microplastic Contamination in Commercial Insect Meals. Environments 2024, 11, 112.
Rimoldi, S.; Ponti, J.; Valsesia, A.; Saroglia, G.; La Spina, R.; Fumagalli, F.; Terova, G. Detection of Microplastic Contamination in Commercial Insect Meals. Environments2024, 11, 112.
Rimoldi, S.; Ponti, J.; Valsesia, A.; Saroglia, G.; La Spina, R.; Fumagalli, F.; Terova, G. Detection of Microplastic Contamination in Commercial Insect Meals. Environments 2024, 11, 112.
Abstract
Background. Escalating global plastic production, expected to reach 34,000 million tons by 2050, poses a significant threat to human and environmental well-being, particularly in aquatic ecosystems. Microplastics (MP) and nanoplastics (NP), which originate from the degradation of plastics, are of concern due to their potential bioaccumulation and uptake of pollutants. This study addresses identification methods and focuses on insect meal, a raw material for aquaculture feed.
Methods. By using different techniques, the study was able to detect MP and NP in insect meal samples. Chemical digestion with KOH at 60°C efficiently removed organic matter without affecting the synthetic polymer polyethylene (PE). Filtration, confocal Raman microscopy, SEM and TEM were used for comprehensive analysis and integrity tests on PE films were performed using Raman and FTIR spectroscopy.
The results showed the presence of PE microplastic particles in the insect meal, which was confirmed by correlative Raman and SEM mapping on a positively charged surface. In addition, the increased resolution of the Raman microscope identified submicrometric PE NP (800 nm). Transmission electron microscopy (TEM) with energy dispersive X-ray spectroscopy (EDX) confirmed plastic-like structures in the insect meal, highlighting the presence of PE plastics characterized by irregular shapes and some agglomeration. The higher carbon concentration in the EDX analysis supported the plastic nature, which was also confirmed by Raman spectroscopy.
Conclusions. The study provides a robust method for the detection of MP and NP in insect meal and provides valuable insight into the possible presence of plastics in insect-based aquafeeds. The combination of different analytical methods increases the reliability of the results and sets the stage for future investigations that could focus on the quantification of NP and the assessment of their potential environmental impact.
Biology and Life Sciences, Animal Science, Veterinary Science and Zoology
Copyright:
This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.