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Inducing mussel beds, based on an aquaculture long-line system, as nature-based solutions: effects on seabed dynamics and benthic communities
Islam, M.; Semeraro, A.; Langedock, K.; Moulaert, I.; Stratigaki, V.; Sterckx, T.; Van Hoey, G. (2024). Inducing mussel beds, based on an aquaculture long-line system, as nature-based solutions: effects on seabed dynamics and benthic communities. Nature-Based Solutions 6: 100142. https://dx.doi.org/10.1016/j.nbsj.2024.100142
In: Nature-Based Solutions. Elsevier: New York. e-ISSN 2772-4115
Peer reviewed article  

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Keywords
    Monitoring
    Mytilus edulis Linnaeus, 1758 [WoRMS]
    Marine/Coastal
Author keywords
    Nature-based solutions; Ecosystem engineer; Mussel bed; Hydrodynamic; Sediment; Macro benthic community

Authors  Top 
  • Islam, M.
  • Semeraro, A.
  • Langedock, K.
  • Moulaert, I., more
  • Stratigaki, V.
  • Sterckx, T.
  • Van Hoey, G.

Abstract
    Nature-based solutions (NbS) offer a promising path to enhance climate-resilient shorelines. For instance, the creation of mussel beds in subtidal sandy shore systems provides a versatile strategy for coastal management, reinforcing coastal defense and fostering biodiversity, ultimately strengthening the resilience and well-being of coastal communities. This study analysed the changes in seabed dynamics and surrounding benthic communities as a result of the formation of mussel beds (Mytilus edulis) using an aquaculture longline system. Therefore, a comprehensive monitoring approach at two sites characterized by distinct hydrodynamic conditions was applied over a three-year period. To assess the effects, a before/after control/impact design (BACI) was employed. Seabed dynamics were evaluated by observing mussel bed persistence, erosion/deposition, and sediment composition. The influence on the benthic community included assessments of community structure and biodiversity. Finally, the impact of mussels, hydrodynamic conditions, and their interactions on seabed dynamics and benthic communities was examined using linear mixed models (LMMs). Factors such as mussel presence, Lanice conchilega abundance, shell cover, and sediment composition played a role in shaping the distinct characteristics observed between two different sites: a site that lies at a location that is more sheltered from hydrodynamic conditions, and a second site that is exposed to higher current and wave conditions. The sheltered site exhibited higher species density, richness, biomass, and diversity compared to the exposed site. In relation to the mussel bed development, mussel patches were found at both sites (with higher occurrence at the sheltered site) in the 2nd and 3rd years (mainly in summer towards early winter). The influence of mussels on sediment deposition was noticeable at the sheltered site, albeit lacking statistical significance, suggesting their potential role in erosion/deposition mechanisms. Also, a higher proportion of very fine sand was observed in the mussel bed compared to the bare sand. However, due to the absence of higher-density permanent mussel beds and irregular sedimentation/erosion patterns throughout the study period, no significant effect of the mussel beds on the community structure or diversity was found. In order to achieve a sustained and dense mussel bed and maximize the potential impact of mussels in combating climate change (e.g., shore protection and biodiversity enrichment), additional measures to increase coastal resilience against harsh hydrodynamic conditions may be necessary.

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