Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Plastic pollution is and will be a problem for humanity to deal with for decades to come. The main cause for concern is plastic debris of microsizes, that has been detected in many worrying locations, e.g. human body. Microplastic can carry many substances. It’s possible for many substances, including toxins, to accumulate on plastic surface. This review pertains to the compilation of the newest scientific information regarding plastic’s ability to sorption. The methodological approach as well as mathematical models used in studies pertaining to this topic have been demonstrated. The type of plastic, the matrix and state of microplastic sample have been described to be affecting sorption on plastic. Some problems with methodology in compiled sorption studies have been outlined. It was concluded that more research is needed to be done to fully grasp this topic.
Czasopismo
Rocznik
Tom
Strony
150--165
Opis fizyczny
Bibliogr. 65 poz., rys., tab.
Twórcy
autor
- University of Bialystok, Bialystok
autor
- University of Bialystok, Faculty of Chemistry, Bialystok
Bibliografia
- 1. https://plasticseurope.org/knowledge-hub/plastics-the-fast-facts-2023/ access 29.02.2024.
- 2. https://adapetation.net/global-plastic-regulations/ access 29.02.2024.
- 3. https://circular.tomra.com/explore/what-is-the-single-use-plastics-directive access 29.02.2024.
- 4. Wąskowski, J and Bogdanowicz, A 2020. Mikroplastiki w środowisku wodnym. Warszawa: PWN.
- 5. Kik, K, Bukowska, B and Sicińska, P 2020. Polystyrene nanoparticles: sources, occurrence in the environment, distribution in tissues, accumulation and toxicity to various organisms. Environmental Pollution 262, 114297.
- 6. Boucher, J and Friot, D 2017. Primary microplastics in the oceans: a global evaluation of sources. IUCN: Gland.
- 7. Campanale, C, Massarelli, C, Savino, I, Locaputo, V and Uricchio VF 2020. A detailed review study on potential effects of microplastics and additives of concern on human health. International Journal of Environmental Research and Public Health 17, 1212.
- 8. Diepens, NJ and Koelmans, AA 2018. Accumulation of plastic debris and associated contaminants in aquatic food webs. Environmental Science and Technology 52, 8510-8520.
- 9. Park, B et al. 2023. Microplastics in large marine animals stranded in the Republic of Korea. Marine Pollution Bulletin 189, 114734.
- 10. Meaza, I, Toyoda, JH and Wise, Sr JP 2021. Microplastics in sea turtles, marine mammals and humans: A One Environmental Health Perspective. Frontiers in Environmental Science 8.
- 11. https://ourworldindata.org/how-much-plastic-waste-ends-up-in-the-ocean access 29.02.2024.
- 12. Kye, H et al. 2023. Microplastics in water systems: A review of their impacts on the environment and their potential hazards. Heliyon 9, e14359.
- 13. Sánchez, A et al. 2022. Dietary microplastics: occurrence, exposure and health implications. Environmental Research 212, 113150.
- 14. Kwon, J-H et al. 2020. Microplastics in food: a review on analytical methods and challenges. International Journal of Environmental Research and Public Health 17, 6710
- 15. Jenner, LC, Rotchell, JM, Bennett, RT and Cowen, M 2022. Detection of microplastics in human lung tissue using μ FTIR spectroscopy. Science of the Total Environment 831, 154907.
- 16. Leslie, HA et al. 2022. Discovery and quantification of plastic particle pollution in human blood. Environment International 163, 107199.
- 17. Ragusa, A et al. 2021. Plasticenta: first evidence of microplastics in human placenta. Environment International 146, 106274.
- 18. Hahladakis, JN, Velis, CA, Weber, R, Iacovidou, E and Purnell, P 2018. An overview of chemical additives present in plastics: Migration, release, fate and environmental impact during their use, disposal and recycling. Journal of Hazardous Materials 344, 179-199.
- 19. Seidensticker, S, Grathwohl, P, Lamprecht, J and Zarfl, C 2018. A combined experimental and modeling study to evaluate pH dependent sorption of polar and non-polar compounds to polyethylene and polystyrene microplastics. Environmental Sciences Europe 30, 30.
- 20. Atugoda, T et al. 2021. Interactions between microplastics, pharmaceuticals and personal care products: Implications for vector transport. Environment International 149: 106367.
- 21. Verdú, I, González-Pleiter, M, Leganés, F, Rosal, R and Fernández-Piñas, F 2021. Microplastics can act as vector of the biocide triclosan exerting damage to freshwater microalgae. Chemosphere 266, 129193.
- 22. Lin, Z, Hu, Y, Yuan, Y, Hu, B and Wang, B (2021) Comparative analysis of kinetics and mechanisms for Pb(II) sorption onto three kinds of microplastics. Ecotoxicology and Environmental Safety 208, 111451.
- 23. Kapelewska, J, Klekotka, U, Żadziłko, E and Karpińska J 2021. Simultaneous sorption behaviors of UV filters on the virgin and aged micro-high-density polyethylene under environmental conditions. Science of the Total Environment 789, 147979.
- 24. Gong, W et al. 2019. Comparative analysis on the sorption kinetics and isotherms of fipronil on nondegradable and biodegradable microplastics. Environmental Pollution 254, 112927.
- 25. Liu, G et al. 2019. Sorption behavior and mechanism of hydrophilic organic chemicals to virgin and aged microplastics in freshwater and seawater. Environmental Pollution 246: 26-33.
- 26. Sahoo, TR and Prelot, B 2020. Adsorption processes for the removal of contaminants from wastewater: the perspective role of nanomaterials and nanotechnology. In: Bonelli, B, Freyria, FS, Rossetti, I and Sethi, R (eds) Nanomaterials for the Detection and Removal of Wastewater Pollutants. Elsevier Inc., 161-222.
- 27. Azizian, S 2004. Kinetic models of sorption: a theoretical analysis. Journal of Colloid and Interface Science 276, 47-52.
- 28. Wang, J and Guo, X 2020. Adsorption kinetic models: physical meanings, applications, and solving methods. Journal of Hazardous Materials 390, 122156.
- 29. Kajjumba, GW, Emik, S, Öngen, A, Özcan, HK and Aydin, S 2019. Modelling of adsorption kinetic processes- errors, theory and application. In: Edebali S (ed) Advanced Sorption Process Applications. IntechOpen, 1-19.
- 30. Wang, J and Guo, X 2020. Adsorption isotherm models: classification, physical meaning, application and solving method. Chemosphere 258, 127279.
- 31. Ye, W et al. 2021. Chapter 3 - Design with modeling techniques. In: Goodfellow, HD and Wang, Y (eds) Industrial Ventilation Design Guidebook (Second Edition). Academic Press: 109–183.
- 32. Dada, AO, Olalekan, AP, Olatunya, AM and Dada, O 2012. Langmuir, Freundlich, Temkin and Dubinin-Radushkevich isotherms studies of equilibrium sorption of Zn2+ unto phosphoric acid modified rice husk. Journal of Applied Chmistry 3, 38-45.
- 33. Jiang, M et al. 2020. Strong sorption of two fungicides onto biodegradable microplastics with emphasis on the negligible role of environmental factors. Environmental Pollution 267, 115496.
- 34. Razanajatovo Mamitiana, R, Ding, J, Zhang, S, Jiang, H and Zou, H 2018. Sorption and desorption of selected pharmaceuticals by polyethylene microplastics. Marine Pollution Bulletin 136, 516-523.
- 35. Li, J, Zhang, K and Zhang, H 2018. Adsorption of antibiotics on microplastics. Environmental Pollution 237, 460-467.
- 36. Costa, ST, Rudnitskaya, A, Vale, C, Guilhermino, L and Botelho, MJ 2020. Sorption of okadaic acid lipophilic toxin onto plastics in seawater. Marine Pollution Bulletin 157, 111322.
- 37. Tubić, A et al. 2019. Significance of chlorinated phenols adsorption on plastics and bioplastics during water treatment. Water 11, 2358.
- 38. Elizalde-Velázquez, A et al. 2020. Sorption of three common nonsteroidal anti-inflammatory drugs (NSAIDs) to microplastics. Science of the Total Environment 715, 136974.
- 39. Hildebrandt, L, Nack, FL, Zimmermann, T and Profrock, D 2021. Microplastics as a Trojan horse for trace metals. Journal of Hazardous Materials Letters 2, 100035.
- 40. Moura, DS et al. 2022. Adsorption of cyanotoxins on polypropylene and polyethylene terephthalate: Microplastics as vector of eight microcystin analogues. Environmental Pollution 303, 119135.
- 41. Munoz, M, Ortiz, D, Nieto-Sandoval, J, de Pedro, ZM and Casas, JA 2021. Adsorption of micropollutants onto realistic microplastics: Role of microplastic nature, size, age, and NOM fouling. Chemosphere 283, 131085.
- 42. Goswami, P and O’Haire, T 2016. Developments in the use of green (biodegradable), recycled and biopolymer materials in technical nonwovens. In: Kellie G (ed) Advances in Technical Nonwovens. Woodhead Publishing: 97-114.
- 43. Yap, XY, Gew, LT, Khalid, M and Yow, Y-Y 2023. Algae-based bioplastic for packaging: a decade of development and challenges (2010–2020). Journal of Polymers and the Environment 31, 833-851.
- 44. Flury, M and Narayan, R 2021. Biodegradable plastic as an integral part of the solution to plastic waste pollution of the environment. Current Opinion in Green and Sustainable Chemistry 30: 100490.
- 45. Sharmiladevi, S, Ramesh, N and Ramesh, S 2019. Production of Bio Degradable Bags Using cassava Starch. International Research Journal of Multidisciplinary Technovation 1, 553-559.
- 46. Yu, Y, Griffin-LaHue, DE, Miles, CA, Hayes, DG and Flury, M 2021. Are micro- and nanoplastics from soil-biodegradable plastic mulches an environmental concern? Journal of Hazardous Materials Advances 4, 100024.
- 47. Fojt, J, David, J, Přikryl, R, Řezáčová, V and Kučerík, J 2020. A critical review of the overlooked challenge of determining micro-bioplastics in soil. Science of The Total Environment 745, 140975.
- 48. Green, DS, Boots, B, Sigwart, J, Jiang, S and Rocha, C 2016. Effects of conventional and biodegradable microplastics on a marine ecosystem engineer (Arenicola marina) and sediment nutrient cycling. Environmental Pollution 208, 426–434.
- 49. Tamayo-Belda, M et al. 2023. Effects of petroleum-based and biopolymer-based nanoplastics on aquatic organisms: A case study with mechanically degraded pristine polymers. Science of The Total Environment 883, 163447.
- 50. Concha-Graña, E, Moscoso-Pérez, CM, López-Mahía, P, Muniategui-Lorenzo, S 2022. Adsorption of pesticides and personal care products on pristine and weathered microplastics in the marine environment. Comparison between bio-based and conventional plastics. Science of The Total Environment 848, 157703.
- 51. Zuo, L-Z et al. 2019. Sorption and desorption of phenanthrene on biodegradable poly(butylene adipate co-terephtalate) microplastics. Chemosphere 215, 25-32.
- 52. Evoli, S, Mobley, D, Guzzi, R and Rizzuti, B 2016. Multiple binding modes of ibuprofen in human serum albumin identified by absolute binding free energy calculations. Physical Chemistry Chemistry Physical 18, 32358-32368.
- 53. Völkl, M et al. 2022. Pristine and artificially-aged polystyrene microplastic particles differ in regard to cellular response. Journal of Hazardous Materials 435, 128955.
- 54. Ateia, M et al. 2020. Sorption behavior of real microplastics (MPs): insights for organic micropollutants adsorption on a large set of well-characterized MPs. Science of the Total Environment 720: 137634.
- 55. Hüffer, T, Weniger, A-K and Hofmann, T 2018. Sorption of organic compounds by aged polystyrene microplastic. Environmental Pollution 236, 218–225.
- 56. Müller, A, Becker, R, Dorgerloh, U, Simon, F-G and Braun, U 2018. The effect of polymer aging on the uptake of fuel aromatics and ethers. Environmental Pollution 240, 639–646.
- 57. Gardette, M et al. 2013. Photo- and thermal-oxidation of polyethylene: comparison of mechanisms and influence of unsaturation content. Polymer Degradation and Stability 98, 2383–2390.
- 58. Ho, W-K and Leung, KS-Y 2019. Sorption and desorption of organic UV filters onto microplastics in single and multi-solute systems. Environmental Pollution 254, 113066.
- 59. Guo, X and Wang, J (2019) Sorption of antibiotics onto aged microplastics in freshwater and seawater. Marine Pollution Bulletin 149, 110511.
- 60. Frigione, M and Rodríguez-Prieto, A 2021. Can accelerated aging procedures predict the long term behavior of polymers exposed to different environments? Polymers (Basel) 13, 2688.
- 61. Sun, C, Zhang, W, Ding, R, Wang, J and Yao, L 2020. Mechanism of low concentrations of polystyrene microplastics influence the cytotoxicity of Ag ions to Escherichia coli. Chemosphere 253, 126705.
- 62. Reichel, J, Graßmann, J, Letzel, T and Drewes, JE 2020. Systematic development of a simultaneous determination of plastic particle identity and adsorbed organic compounds by thermodesorption-pyrolysis GC/MS (TD-Pyr-GC/MS). Molecules (Basel, Switzerland) 25, 4985.
- 63. Cormier, B et al. 2022. Sorption and desorption kinetics of PFOS to pristine microplastic. Environmental Science and Pollution Research 29, 4497-4507.
- 64. Munier, B and Bendell, LI 2018. Macro and micro plastics sorb and desorb metals and act as a point source of trace metals to coastal ecosystems. PLoS ONE 13, e0191759.
- 65. Liu, X, Shi, H, Xie, B, Dionysiou, DD and Zhao, Y 2019 Microplastics as both a sink and a source of bisphenol A in the marine environment. Environmental Science & Technology 53, 10188–10196.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-31f4b7d4-c4e2-4c34-9254-d6e8c397edd2