The research presented in this paper is being carried out within the framework of the activities of the Spanish Government through the “Severo Ochoa Centre Excellence” granted to ICM-CSIC (CEX2019-000928-S) and the Research Unit Tecnoterra (ICM-CSIC/UPC). The present research was conceived within the framework of the Spanish National Projects BITER-LANDER (PID2020-114732RB-C32), BITER-ECO (PID2020-114732RB-C31), BITER-AUV (PID2020-114732RB-C33), and PLOME (PLEC2021-007525/AEI/10.13039/501100011033). The proposed data banking and analysis approaches were also tailored in accordance with the guidelines of the EU Project DIGT4ECO (Digital Twin-sustained 4D ecological monitoring of restoration in fishery depleted areas; 101112883 - GAP-101112883). NJR was funded by the Spanish government (Agencia Española de Investigación-AEI) through the Ramon y Cajal postdoctoral program (#RYC2021-034381-I). DC was funded by Ministerio de Cultura e Innovación/Agencia Española de Investigación and European Union Next Generation EU/PRTR through the Juan de la Cierva Formación Post-doctoral Fellowship (#FJC2021-047734-I)<br/>Peer reviewed<br/>12 pages, 7 figures, 2 tables, supplementary material https://doi.org/10.1016/j.scitotenv.2024.178139.-- Data availability: The data that has been used is confidential<br/>Monitoring the effects of climate change and other multi-years processes on coastal ecosystems require long-term datasets that may extend into decades. One tool to achieve this are cabled seafloor observatories that can collect continual streams of environmental and biological data as long as the equipment is maintained. Here, we used 10-years of time-lapse images (every 30 mins) from the OBSEA seafloor cabled observatory located at 20 m depth, four km offshore from Vilanova i la Geltrú (Spain) coast, to characterize temporal trends in fish community dynamics. These temporal trends were compared to in situ and remotely-sensed (MODIS-Aqua) data on temperature, salinity, and chlorophyll-a concentration (Chl-a). We observed a reduction in fish diversity over time and an increase in species turnover. Specifically, there was a decrease in the relative abundance of fish species at the lowest trophic levels alongside an increase in predators, suggesting a top-down effect. Of temperature, salinity, and Chl-a, only salinity exhibited a significant change over time. Nevertheless, the Generalized Additive Models (GAMs) revealed significant correlations between fish biodiversity indices and both temperature and Chl-a. Following models results we concluded that environmental variables affected the local fish community only at seasonal level. Including more environmental variables, such as fishing activity and pollution, in the applied models may help explain the detected decreases in biodiversity<br/>

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