Density of Key-Species Determines Efficiency of Macroalgae Detritus Uptake by Intertidal Benthic Communities

Polybrominated diphenyl ethers in bivalves: metabolites, accumulation, quantification and ecological risks

Polybrominated diphenyl ethers (PBDEs) are extensively used as flame retardants in plastics but have emerged as persistent environmental pollutants due to their bioaccumulation and toxicity. Analysis of 74 studies from 2000 to 2024 highlights the increasing research interest in PBDE contamination, particularly in aquatic ecosystems and bivalves. Recurring themes such as "health risk," "bioaccumulation," and "risk assessment" dominate the discourse, emphasizing the need for deeper investigations into PBDE pathways and impacts. This trend underscores the critical importance of evaluating PBDE contamination in seafood species like oysters, mussels and clams, which are integral to human diets and aquatic food chains. Building on these insights, this study focused on analyzing PBDEs and their metabolites (MeO-BDE, OH-BDE) in commonly consumed bivalve species. Advanced methods for extraction, purification and simultaneous analysis revealed significant variations in PBDE concentrations: oysters (29-101 ng/g lw), mussels (10-274.8 ng/g lw) and clams (23-64,900 ng/g lw). Notably, metabolites MeO-BDE and OH-BDE were frequently detected, sometimes surpassing PBDE levels, indicating complex bioaccumulation processes. Bioaccumulation and bio-sediment accumulation factors (BAF and BSAF) showed that PBDEs and their metabolites accumulate more effectively through water pathways than sediment. Trophic magnification factor (TMF) analysis further revealed higher TMF values for PBDEs compared to their metabolites, categorizing PBDEs and MeO-BDE as low-risk TMFs. These findings align with citation analysis trends, which emphasize "risk assessment" as a pivotal theme, particularly concerning human exposure. The human health risk assessment based on bivalve consumption highlights potential exposure concerns in regions with high seafood intake. This study not only enriches the understanding of PBDE distribution and bioaccumulation in bivalves but also emphasizes the importance of effective monitoring, regulatory control and continued investigation into their ecological and human health impacts.

Isotopically labelled macroalgae: A new method for determining sources of excess nitrogen pollution

RATIONALE

Stable nitrogen isotope ratios (δ15 N) can be used to discern sources of excess nitrogen pollution in water. The δ15 N values of nitrate in water often do not reflect the true δ15 N source value owing to high temporal variation, and there are high analytical costs associated with obtaining δ15 N values from water nitrate. To find alternative solutions, we isotopically labelled macroalgae (i.e. seaweed) beyond natural variation as a new method for determining sources of excess nitrogen pollution in seawater.

METHODS

Fucus vesiculosus (bladder wrack) non-fertile tips were collected from Easington Colliery, County Durham, UK, and cultured in two isotopically enriched solutions containing ammonium sulphate with δ15 N values of 170 ± 5‰ and -60 ± 3‰ for a period of 19 days. The macroalgae were cultured in separate opened glass jars in an incubator with set temperature (11°C) and light (125 μmol photons m-2 s-2 on a light/dark rhythm of 16 h/8 h). The oven-dried tips were analysed for δ15 N over the 19-day experiment.

RESULTS

The macroalgal tips incorporated the isotopically enriched solutions rapidly, reaching 50% of the isotopically enriched seawater after ca 11 days for the 15 N-enriched solution and ca 15 days for the 14 N-enriched solution. δ15 N values were incorporated more into the torn base of the macroalgal tips than into the middle and apex regions.

CONCLUSIONS

F. vesiculosus rapidly incorporates the isotopic ratio of the artificial seawater solution to which it is translocated. The laboratory-developed isotopically labelled macroalgae can be manufactured to generate 'unnatural' δ15 N values for translocation into coastal environments. This approach can provide an efficient, low-cost alternative to current analytical methods for determining and monitoring nitrogen pollution.

Large Infaunal Bivalves Determine Community Uptake of Macroalgal Detritus and Food Web Pathways

Abstract

Human activities alter biodiversity, influencing bottom-up and top-down control on food webs which can affect ecosystem functioning. In marine ecosystems, large bivalves play a critical role in benthic–pelagic coupling including nutrient cycling; however, their influence on the uptake of detrital organic matter by benthic communities is less understood. In a replicated factorial field experiment, we examined how the presence or absence (overharvesting scenario) of a large suspension-feeding clam on an intertidal sandflat and the addition of isotopically enriched macroalgal (Ulva sp.) detritus (eutrophication scenario) influenced infaunal biodiversity, and how changes in trophic interactions influenced key ecosystem functions (nutrient cycling and benthic metabolism and primary production). Both clams and Ulva increased community metabolism, but only clams had an effect on nutrient regeneration. We used the 13C- and 15N-enriched Ulva to quantify the effect of clams on detritus uptake in fauna and recovery in sediment. Due to their large biomass, nitrogen incorporation by clams constituted one-third of the infaunal community uptake after 14 days. Clam uptake likely resulted from ingestion of resuspended microphytobentos which had utilized 15N leaking out from decomposing Ulva. In plots without Ulva addition, the effect of clams on the overall resource utilization by the benthic community using natural abundance isotope niche metrics were tested. In plots without clams, the isotope niche of the community was reduced, and less carbon of pelagic origin was channelled into the infaunal food web. Our results imply that the loss of clams changes trophic pathways and reduces community uptake of macroalgal detritus, potentially exacerbating eutrophication.

Graphic Abstract

Anthropogenic influences on benthic food web dynamics by interrupted freshwater discharge in a closed Geum River estuary, Korea

Stable isotope analysis was used to investigate the benthic food web dynamics in the Geum River estuary where continuous river flow has been blocked by a sea dike over the past 25 years. In order to address the dike effect(s) on distribution of food sources (i.e., organic matters and microphytobenthos) and their utilization by marine predators, a three years monitoring survey (total of 30 surveys) was seasonally conducted at four fixed locations at both inside of dike and outer tidal flats. All the collected biota (total of 19 species; >1100 individuals and microphytobenthos) and abiotic (n = 118) samples were analyzed for carbon (δ¹³C) and nitrogen (δ¹⁵N) stable isotopes. In particular, two dominant marine bivalves inhabiting outer reach of tidal flats, Mactra veneriformis and Cyclina sinensis, were targeted to identify their feeding strategies that being related to a year-round population growth. In general, the stable isotopic signatures of samples indicated dissimilarity in distribution of organic matters between inside and outside of dike, supporting geographical and/or trophic isolation. The taxa-dependent trophic levels are also evidenced in consistent manner, with two to three levels being positioned over the years. Meantime, their dietary contributions varied in time, i.e., seasonal chances in compositions of major food sources (microphytobenthos and particulate organic matters) were observed for two target bivalves. Such temporal variations could be further linked to selective feedings that evidenced by age(size)-dependent and/or tissue specific distributions. Altogether, the present study suggested seasonality, diet preference, and growth dependent food web dynamics in the Geum River estuary. Overall, the present study suggested that the stable isotopic technique could be a powerful tool for characterizing the long-term anthropogenic influences of a sea dike on marine food-web dynamics.

Food webs and species biodiversity of the fouling community associated with bivalve aquaculture farms compared to analogous non-farm structures

Bivalve aquaculture farms are an integral part of the surrounding coastal marine ecosystem and associated food webs. What is not well understood is how these anthropogenically manipulated, dense, single-species cultures influence species trophodynamics in the coastal ocean. Fouling macrofauna biodiversity, macroalgae biomass, sediment, and food web structure were studied at two blue mussel (Mytilus edulis) floating raft rope-culture aquaculture farm structures and two analogous floating dock structures without mussels in Casco Bay, Maine, USA during the summers of 2016 and 2017. Shannon Wiener diversity index of macrofauna was variable across structures compared depending on month. Macroalgae biomass was significantly higher on farm structures exclusively due to green macroalgae. There was no shift in food web structure determined by stable isotope analysis (δ¹³C and δ¹⁵N) and Layman metrics. This study is an initial step critical to assessing interactions of bivalve farms with coastal food webs.

Seafloor ecological functioning over two decades of organic enrichment

Climate change and anthropogenic nutrient enrichment are driving rapid increases in ocean deoxygenation. These changes cause biodiversity loss and have severe consequences for marine ecosystem functioning and in turn the delivery of ecosystem services upon which humanity depends (e.g. fisheries). We seek to understand how such changes will impact seafloor functioning using biological traits analysis. Results from a sewage-sludge disposal site in the Firth of Clyde, UK spanning 26 years of monitoring showed that substantial changes in macrobenthic nutrient cycling and the provision of food for predators occurred, with elevated functioning on the margins 1-2 km from the centre of the disposal grounds. Thus, changes in food-web dynamics are expected, that weaken benthic pelagic coupling and lower secondary production (such as fisheries). Generally, functioning was conserved, but declined below a ~6% total organic carbon threshold. Similar to other severely deoxygenated systems, the recovery was slow and hysteresis was apparent.