Unravelling foreshore ecosystem dynamics:Applications for ecosystem-based coastal defence

Hard engineering structures such as dikes, commonly used for coastal protection, are often associated with negative impacts on natural functioning and biodiversity of coastal ecosystems. Hybrid nature-based defences, which combine conventional hard engineered barriers with coastal ecosystems such as marshes, may offer a more sustainable, ecologically valuable and cost-effective alternative to hard engineering alone. However, uncertainties about the actual effectiveness of these nature-based measures still hampers their practical implementation. In this thesis I focussed on coastal ecosystem dynamics in relation to their coastal protection role, as well as investigating nature management strategies to optimize both the coastal protection services and the ecological value of these ecosystems. Overall, this thesis highlights that salt marshes effectively reduce wave heights reaching the dike and wave run-up onto the dikes, even if the marsh vegetation is short. Furthermore, marsh vegetation traps sediment and creates a cohesive top layer that is highly resistant to fast water flow, which is beneficial in reducing the breach depth in case of a dike failure. Only pioneer vegetation growing at sandy places is not erosion resistant, comparable to bare mudflats. Grazing by hare, geese and cattle can reduce the lateral erodibility of fine-grained marsh soils. The resulting slow cliff retreat is beneficial for flood safety, as marsh width is needed to attenuate waves. However, intensive cattle grazing can over-compact the soil, which may negatively impact the marsh resilience to sea level rise. Thus, to be beneficial, cattle grazing should be extensive. Finally, marsh expansion may be promoted by stabilizing and trapping sediment on the connected fronting tidal flats. More specifically, we found that foreshore ecosystems such as seagrass beds with high root density can reduce soil erosion, and that there is potential to change the tidal flat morphology by using artificial reefs

The importance of marshes providing soil stabilization to resist fast-flow erosion in case of a dike breach

Salt marshes provide valuable ecosystem services including coastal protection by reducing wave loading on dikes and seawalls. If the topsoil is erosion resistant to fast-flowing water, it may also reduce breach depth if a dike fails. In this experiment, we quantified the topsoil erosion resistance from marshes and bare tidal flats with different soil types to understand the extent to which they can help reduce breach depth. Intact soil samples were collected from 11 locations in the Netherlands at different tidal elevations and then exposed for 3 h to 2.3 m/s currents. To the samples that remained stable after flow exposure, an artificial crack was made to test their stability following soil disturbance. All samples from the tidal flats were completely eroded, regardless of sediment type. In contrast, all samples from well-established marsh plateaus were stable as long as no disturbances were made, including those with sandy subsoils. After creating artificial cracks, samples with a thin cohesive top layer on top of sandy subsoil collapsed, while marshes with silty subsoils remained stable. Pioneer marshes on sandy substrate without a cohesive top layer were the only vegetated soils that completely eroded. The lower erosion of marshes with either sandy or silty soils compared to bare tidal flats was best explained by the presence of a top layer with belowground biomass, high organic content, high water content, and low bulk density. When analyzing the erodibility of marshes only, fine root density was the best predictor of erosion resistance. This study demonstrates the importance of preserving, restoring, or creating salt marshes, to obtain a topsoil that is erosion resistant under fast-flowing water, which helps reduce breach dimensions if a dike fails. The probability of topsoil erosion in established marshes with sandy subsoil is higher than in silty marshes. A silty layer of cohesive sediment on top of the sand provides extra erosion resistance as long as it does not break. Pioneer marshes that have not developed a cohesive top layer are erosion sensitive, especially in sandy soils. For future marsh creations, using fine-grained sediments or a mixture of sand with silt or clay is recommended

Cross-habitat interactions in the Wadden Sea

Here, we report on the results of the OBN-project ‘Cross-habitat interactions in the Wadden Sea’. Evidence is mounting that ecological linkages between spatially separated key-habitats are vital for the functioning of these habitats. However, management of these habitats rarely considers such spatial interactions in their conservation or restoration approaches. The presented work was carried out in close collaboration with the project ‘Restoration of Griend’, and as such formed part of an integrated investigation into the importance of spatial connectivity between the island Griend and the surrounding mudflats for the restoration and conservation of this, and similar slands. The main goals were to (1) understand how spatial connectivity drives the functioning of the island and the surrounding habitats, and (2) provide recommendations regarding the integration of spatial connectivity into future management approaches

Initiating and upscaling mussel reef establishment with life cycle informed restoration:Successes and future challenges

Worldwide, coastal ecosystems are rapidly degrading in quality and extent. While novel restoration designs include facilitation to enhance restoration success in stressful environments, they typically focus on a single life-stage, even though many organisms go through multiple life-stages accompanied by different bottlenecks. A new approach – life cycle informed restoration – was designed to ameliorate multiple bottlenecks throughout an organism's life cycle. It has successfully been tested on a small scale to facilitate intertidal bivalve reef formation in the Netherlands and Florida. Yet, it remains unknown whether this approach can be scaled to ecosystem-relevant scales. To test whether life cycle informed restoration is upscalable, we conducted a large-scale restoration experiment using blue mussel reefs as a model system. In our experiment, we used biodegradable structures to temporarily facilitate mussel reef formation by providing early-life settlement substrates, and subsequently, reduce post-settlement predation on an intertidal flat in the Wadden Sea, the Netherlands. The structures were placed in 10 × 20 m plots, mimicking bands found in natural mussel beds, spread out across 650 m, and were followed for two years. Our results show that the structures enhance mussel biomass (0.7 ± 0.2 kg DW m−2), as mussels were absent in bare plots. However, biomass varied within plots; in intact structures it was 60 times higher (1.2 ± 0.2 kg DW m−2) than in those that became buried (0.02 ± 0.009 kg DW m−2). Next to burial, 18–46% of the structures were lost due to technical failure, especially during winters at this exposed site. We show that the life cycle informed restoration principle works, but we encountered technical challenges due to larger scale processes (e.g. sedimentation). Furthermore, environmental information is essential for site selection, and for restoration, the functioning of such structures should be tested under extreme conditions before upscaling

An Integrated Approach for the Early Detection of Endometrial and Ovarian Cancers (Screenwide Study): Rationale, Study Design and Pilot Study

Screenwide is a case-control study (2017-2021) including women with incident endometrial and ovarian cancers (EC and OC), BRCA1/2 and MMR pathogenic variant carriers, and age-matched controls from three centers in Spain. Participants completed a personal interview on their sociodemographic factors, occupational exposure, medication, lifestyle, and medical history. We collected biological specimens, including blood samples, self-collected vaginal specimens, cervical pap-brush samples, uterine specimens, and, when available, tumor samples. The planned analyses included evaluation of the potential risk factors for EC/OC; evaluation of molecular biomarkers in minimally invasive samples; evaluation of the cost-effectiveness of molecular tests; and the generation of predictive scores to integrate different epidemiologic, clinical, and molecular factors. Overall, 182 EC, 69 OC, 98 BRCA pathogenic variant carriers, 104 MMR pathogenic variant carriers, and 385 controls were enrolled. The overall participation rate was 85.7%. The pilot study using 61 samples from nine EC cases and four controls showed that genetic variants at the variant allele fraction > 5% found in tumors (n = 61 variants across the nine tumors) were detected in paired endometrial aspirates, clinician-collected cervical samples, and vaginal self-samples with detection rates of 90% (55/61), 79% (48/61), and 72% (44/61) by duplex sequencing, respectively. Among the controls, only one somatic mutation was detected in a cervical sample. We enrolled more than 800 women to evaluate new early detection strategies. The preliminary data suggest that our methodological approach could be useful for the early detection of gynecological cancers