More Like this

1. Heterotrophic Dinoflagellate Growth and Grazing Rates Reduced by Microplastic Ingestion

   https://doi.org/10.3389/fmars.2021.716349  

   Fulfer, Victoria M.; Menden-Deuer, Susanne (August 2021, Frontiers in Marine Science)

   Microplastics are ubiquitous contaminants in marine ecosystems worldwide, threatening fisheries production, food safety, and human health. Ingestion of microplastics by fish and large zooplankton has been documented, but there are few studies focusing on single-celled marine predators, including heterotrophic dinoflagellates. In laboratory experiments, the heterotrophic dinoflagellate species Oxyrrhis marina and Gyrodinium sp. readily ingested both algal prey and polystyrene microplastic spheres (2.5–4.5 μm), while Protoperidinium sp. did not ingest microplastics. Compared to algae-only fed dinoflagellates, those that ingested microplastics had growth rates reduced by 25–35% over the course of 5 days. Reduced growth resulted in a 30–50% reduction of secondary production as measured as predator biomass. Ingestion rates of algal prey were also reduced in the microplastic treatments. When given a mixture of microplastics and algal prey, O. marina displayed a higher selectivity for algal prey than Gyrodinium sp. Observations in the coastal ocean showed that phylogenetically diverse taxa ingested microplastic beads, and thus heterotrophic dinoflagellates could contribute to trophic transfer of microplastics to higher trophic levels. The results of this study may suggest that continued increase in microplastic pollution in the ocean could lead to reduced secondary production of heterotrophic protists due to microplastic ingestion, altering the flow of energy and matter in marine microbial food webs. 

   more » « less
2. Evaluating the Environmental Factors on Microplastic Generation: An Accelerated Weathering Study

   https://doi.org/10.3390/microplastics4010013  

   Rostampour, Sara; Jhang, Song Syun; Hsu, Jung-Kai; Cook, Rachel; Li, Yuejin; Fan, Chunlei; Sung, Li-Piin (March 2025, Microplastics)

   Microplastics pose a significant environmental threat, and understanding their sources and generation mechanisms is crucial for mitigation efforts. This study investigates the effects of ultraviolet intensity, temperature, and relative humidity on the degradation of polyethylene terephthalate (PET) plastics and the subsequent formation of microplastic particles. PET samples were exposed to ultraviolet (UV) radiation under various environmental conditions using the SPHERE (Simulated Photodegradation via High Energy Radiant Exposure) accelerated weathering device at the National Institute of Standards and Technology (NIST). Attenuated total reflectance–Fourier transform infrared spectroscopy (ATR-FTIR) and laser confocal scanning microscopy (LSCM)/atomic force microscopy (AFM) were employed to characterize the chemical and morphological changes on the weathered surfaces. This study’s findings reveal that temperature and relative humidity significantly influence the rate of photodegradation and the characteristics of the generated microplastics. Higher temperatures and increased humidity accelerated the degradation process, leading to a higher abundance of microplastic particles. However, larger particles were observed at higher temperatures due to aggregation. These results underscore the importance of considering environmental factors when assessing the fate and transport of microplastics in the environment. Developing strategies to reduce plastic pollution and mitigate the generation of microplastics is essential for protecting ecosystems and human health. 

   more » « less
3. Photodegradation of Landfill Leachate-Induced Dissolved Organic Nitrogen and Its Impact on Algal Growth in Estuaries

   Ahmed, Md Ashik; Deaton, Dawn; Taylor, Kayla; Bowen, Christian; Cheshire, Jack; Paerl, Hans; Zhang, Lifeng; Zhao, Renzun (May 2025, AEESP 2025 Conference)

   Abstract The treatment of landfill leachate and sewage is crucial for mitigating the environmental impacts of dissolved organic nitrogen (DON) effluent in aquatic ecosystems. This study used three sequencing batch reactors (SBRs) to treat sewage mixed with landfill leachates of varying organic carbon content. While the SBRs significantly removed dissolved inorganic nitrogen (DIN), the effluents were enriched with landfill leachate-induced DON. These landfill leachate-induced DON effluents (R1, R2, and R3) were then photodegraded under simulated summer sunlight conditions based on Greensboro, NC, USA weather data. The study utilized visible light (400–780 nm, 9340 μW/cm²), UVA (365 nm, 1442 μW/cm²), UVB (285 nm, 76 μW/cm²), UVC (254 nm, 315 μW/cm²), and dark controls. Effluents were mixed with Neuse River Estuary water, serving as a natural algal source, and exposed for 90 days under these light conditions. Samples were analyzed every 10 days for DON degradation and algal growth, with molecular changes assessed using FTICR-MS, FTIR, and EEM-PARAFAC. Results showed substantial DON degradation across all light treatments, with UVA achieving the highest reduction (up to 99.07%), followed by UVC (88.85%), visible light (86.19%), and UVB (75.11%), while no degradation occurred under dark conditions. Initial DON levels of 2.69–2.7 mg/L were reduced to as low as 0.025 mg/L under UVA in R3 effluent. UVC treatment led to increased NO3-N concentrations due to the oxidation of DON to NH4-N and its subsequent conversion to NO3-N, reaching 2.66, 2.59, and 2.63 mg/L in R1, R2, and R3, respectively. UVC inhibited algal growth, resulting in no NH4-N uptake and subsequent oxidation to stable, elevated NO3-N levels in the samples. Algal growth responses varied by light treatment, with visible light and UVB promoting the highest algae growth, minimal algae growth observed under UVA, and no growth under UVC or dark conditions. These findings demonstrate the evidence of rDON degradation during the long-term retention in the receiving water bodies and potential impact on the algal growth. 

   more » « less
4. Microplastics affect sedimentary microbial communities and nitrogen cycling

   https://doi.org/10.1038/s41467-020-16235-3  

   Seeley, Meredith E.; Song, Bongkeun; Passie, Renia; Hale, Robert C. (May 2020, Nature Communications)

   Abstract Microplastics are ubiquitous in estuarine, coastal, and deep sea sediments. The impacts of microplastics on sedimentary microbial ecosystems and biogeochemical carbon and nitrogen cycles, however, have not been well reported. To evaluate if microplastics influence the composition and function of sedimentary microbial communities, we conducted a microcosm experiment using salt marsh sediment amended with polyethylene (PE), polyvinyl chloride (PVC), polyurethane foam (PUF) or polylactic acid (PLA) microplastics. We report that the presence of microplastics alters sediment microbial community composition and nitrogen cycling processes. Compared to control sediments without microplastic, PUF- and PLA-amended sediments promote nitrification and denitrification, while PVC amendment inhibits both processes. These results indicate that nitrogen cycling processes in sediments can be significantly affected by different microplastics, which may serve as organic carbon substrates for microbial communities. Considering this evidence and increasing microplastic pollution, the impact of plastics on global ecosystems and biogeochemical cycling merits critical investigation. 

   more » « less
5. Distribution and transport of microplastic and fine particulate organic matter in urban streams

   https://doi.org/10.1002/eap.2429  

   Vincent, Anna E. S.; Hoellein, Timothy J. (August 2021, Ecological Applications)

   Abstract Plastic litter is accumulating in ecosystems worldwide. Rivers are a major source of plastic litter to oceans. However, rivers also retain and transform plastic pollution. While methods for calculating particle transport dynamics in rivers are well established, they are infrequently used to quantify the transport and retention of microplastics (i.e., particles < 5 mm) in flowing waters. Measurements of microplastic movement in rivers are needed for a greater understanding of the fate of plastic litter at watershed and global scales, and to inform pollution prevention strategies. Our objectives were to (1) quantify the abundance of microplastics within different river habitats and (2) adapt organic matter “spiraling” metrics to measure microplastic transport concurrent with fine particulate organic matter (FPOM). We quantified microplastic and FPOM abundance across urban river habitats (i.e., surface water, water column, benthos), and calculated downstream particle velocity, index of retention, turnover rate, and spiraling length for both particle types. Microplastic standing stock was assessed using a habitat‐specific approach, and estimates were scaled up to encompass the study reach. Spatial distribution of particles demonstrated that microplastics and FPOM were retained together, likely by hydrodynamic forces that facilitate particle sinking or resuspension. Microplastic particles had a higher downstream particle velocity and lower index of retention relative to FPOM, suggesting that microplastics were retained to a lesser degree than FPOM in the study reaches. Microplastics also showed lower turnover rates and longer spiraling lengths relative to FPOM, attributed to the slow rates of plastic degradation. Thus, rivers are less retentive of microplastics than FPOM, although both particles are retained in similar locations. Because microplastics are resistant to degradation, individual particles can be transported longer distances prior to mineralization than FPOM, making it likely that microplastic particles will encounter larger bodies of water and interact with various aquatic biota in the process. These empirical assessments of particle transport will be valuable for understanding the fate and transformation of microplastic particles in freshwater resources and ultimately contribute to the refinement of global plastic budgets. 

   more » « less