From ecosystems to socio-economic benefits: A systematic review of coastal ecosystem services in the Baltic Sea

• We summarized 20 ecosystem services provided by coastal Baltic ecosystems. • Information on how services translate into socio-economic benefits is lacking. • The deep knowledge gap impairs the sustainable management of the benefits. • We propose a framework with four key measures to close this knowledge gap. • Toxins and Nutrients are the most welldocument pressures to these services. ⁎ Corresponding author. E-mail address: mheckwolf@geomar.de (M.J. Heckwol 1 Shared first author. 2 Shared last author. https://doi.org/10.1016/j.scitotenv.2020.142565 0048-9697/© 2020 The Authors. Published by Elsevier B.V a b s t r a c t a r t i c l e i n f o


H I G H L I G H T S
• We summarized 20 ecosystem services provided by coastal Baltic ecosystems. • Information on how services translate into socio-economic benefits is lacking. • The deep knowledge gap impairs the sustainable management of the benefits. • We propose a framework with four key measures to close this knowledge gap. • Toxins and Nutrients are the most welldocument pressures to these services.

G R A P H I C A L A B S T R A C T
a b s t r a c t a r t i c l e i n f o

Introduction
Ecosystem services refer to the numerous benefits that humans derive from ecosystems (Danley and Widmark, 2016). Ecological values of ecosystem services are often placed on supporting and regulating services (e.g. habitat provision; water filtration; carbon storage & coastal protection) and interactions among them. Supporting, provisioning and regulating services create a foundation for socio-economic benefits that people derive from healthy ecosystems including recreational, cultural and aesthetic values. Economic values of ecosystem services, however, are traditionally expressed in monetary units and assigned to the services themselves, i.e. to the consumable human benefit derived from the demand and the use of the service (de Groot et al., 2012;Moos et al., 2019). Estimating economic outputs derived from coastal ecosystem services has proven to be useful for raising awareness, communicating knowledge and prioritizing conservation measures due to easily relatable monetary values (Bagstad et al., 2013;Risén et al., 2017).
In light of the current global ecological crisis (Brand et al., 2020) there is an ever-increasing need to value how ecosystems support human well-being and identify, which management practices and policies can help to reach sustainable development goals. Both terrestrial and aquatic ecosystems are under serious threat by increased human population resulting in cumulative impacts (e.g. development, pollution, climate change) that degrade ecosystem functions and services (Glynn et al., 2018;Popp et al., 2017). For example, over the last century, 1/3 of the European seagrass area has been lost due to disease, deteriorated water quality, and coastal development (de los Santos et al., 2019). More recently, the algal and bivalve beds have experienced similar losses (Beck et al., 2011;Steneck et al., 2002). To evaluate the impact of these losses, we need to understand their effect on the entire value chain from ecosystems via ecosystem service generation towards human well-being. Here, we utilize the concept of the value chain, a framework used to map and categorize processes that an ecosystem has to perform in order to deliver a valuable socio-economic product (i.e. goods and/or services) (Rawlins et al., 2018). To have a service (e.g. recreational fishing) or good (e.g. fish) for people to enjoy, a whole set of ecological functions have to take place (e.g. spawning habitat provided by macroalgae or food web interactions). The concept of the value chain approach emphasizes the importance of each step (or intermediate good or service) on the provision of the final benefits. Understanding the entire value chain from an ecosystem to the provided service is of utmost importance since management decisions have to target the ecosystem to preserve the provided final service.
The Baltic Seaa marine region of significant socio-economic importance in the northern hemispherecan serve as an excellent example and contribute towards a better quantification and valuation of coastal ecosystem services. This is because the Baltic stands out for providing a strong scientific foundation and accessibility to long-term data series that enable planning for holistic, sustainable and forward-looking management (Reusch et al., 2018). However, current research indicates that neither a common approach to classifying ecosystem services (Hummel et al., 2019) nor a widely accepted methodological framework for assessing their economic value exists (Sagebiel et al., 2016). Here, we focus on coastal ecosystems, an area where the interests of various stakeholders are often the strongest. This is because the coastal population is disproportionately larger compared to other areas and coastal regions are a focal point for international transport and trade (Small and Nicholls, 2003). This puts coastal habitats under direct and indirect anthropogenic pressures that threaten the important ecosystem services they provide (Harley et al., 2006). By now, scientists have studied these ecosystems for decades resulting in a respectable knowledge base that presents a unique opportunity to synthesize existing information and map ecosystem service benefits. Seagrasses, macroalgae and mussels are well-studied key coastal ecosystem elements for habitat provision, nutrient cycling, carbon storage and coastal filtration globally (Lovelock and Duarte, 2019;Norling and Kautsky, 2008). Blue mussels are of exceptional importance in mitigating eutrophication (Kotta et al., 2020;Rönnbäck et al., 2007). A rough estimate suggests that macroalgae could sequester a significant 173 TgC/yr of carbon (Krause-Jensen and . For seagrass-based ecosystems, a study estimated that it could contribute at least 31.5 million dollars to the annual fisheries economy in Australia (Jänes et al., 2020a). Furthermore, cultivated bivalves are known to globally remove 49,000 t of nitrogen and 6000 t of phosphorus with a potential value of $1.20 billion annually (van der Schatte et al., 2020). Important values of coastal ecosystems highlight the need to quantify and summarize ecosystem services of macroalgae, seagrass and mussel beds in the Baltic with a systematic and unified approach.
Here, we integrated five decades of published data  to synthesize the current knowledge of coastal ecosystem services and their values in the Baltic Sea with a main focus on seagrass, macroalgae and mussel beds. Specifically, our objectives were to (i) systematically gather and quantify the focus of studies about the ecological roles of seagrass, macroalgae and mussels; (ii) outline spatial variation of where ecosystem services have been mapped; (iii) assess current knowledge about ecosystem services and quantify the links between science and policy communication within the Baltic Sea and (iv) review the limitations as well as the potential for a wider application of studies that used economic valuation to address ecosystem services in the Baltic Sea.

Systematic literature search and selection
Following a systematic quantitative literature review approach of Pickering and Byrne (2014), we used ISI Web of Science (WoS) to identify studies that investigated ecological services and valuation of seagrass, macroalgae and mussel beds in the Baltic Sea. The literature search was conducted on February 1, 2019, and was designed to identify knowledge across the entire value chain, starting from single habitats providing ecosystem services progressing towards the derived socioeconomic benefits. In WoS, a "Basic Search" selecting "All Databases" for "All years (1945-2019)" was applied. We formulated a search string that captured studies on coastal Baltic mussel beds, seagrass meadows or macroalgae that focused on ecosystem services in the Baltic Sea. Our search string (see data availability statement) resulted in 3089 findings. Since we are aware that the ecosystem service concept has changed over time, we made sure to also capture studies that did not mention the term "ecosystem service" specifically. Next, we carefully read each study and assessed whether the measured variables would be considered an ecosystem service by our current understanding of the ecosystem service concept. Therefore, we used a modified classification of ecosystem services from the Helsinki Commission (HELCOM, 2010). Grey literature was omitted from the downstream analysis.
The resulting hits were further filtered based on four inclusion criteria. We included studies that (i) were carried out in the Baltic Sea, Skagerrak or Kattegat, (ii) investigated mussel beds, seagrass or macroalgae, (iii) provided original data (e.g. experimental, observational or modelling but no reviews) and (iv) addressed ecosystem services. Since we were further interested in understanding the impact of anthropogenic pressures on the target habitats and associated impairments in ecosystem service provision under current and future climate conditions, we also included studies that (iv) addressed climate change effects on the target ecosystems. At first, 20 papers were randomly selected and each paper was evaluated by everyone involved in the literature review according to the workflow in Fig. 1 and the evaluation criteria (i)-(iv). Based on the evaluation results a Kappa test was carried out to test for similarity of the evaluations provided by the five people. Using the package irr v0.84.1 (Gamer et al., 2019) in R v3.6.1, this test resulted in a Kappa value of 0.793 (P < 0.001), which can be considered as "substantial agreement" (Landis and Koch, 1977). Based on the high Kappa value, we felt confident to split the remaining papers among all 5 evaluators. Next, we examined the titles and the abstracts of all 3089 papers and excluded 2176 that did not fulfil our inclusion criteria (see Supplementary Table S1). In the subsequent filtering process, the remaining 913 papers were read in detail and some were excluded when inclusion criteria were not met (Fig. 1). This systematic screening resulted in a total of 657 papers that fulfilled our inclusion criteria (see Supplementary Table S2).

Systematic extraction of information
The 657 selected papers contained information on study species, ecosystems and the type of ecosystem service provided. Further, the type of study design was categorized as observation, experimentation or modelling of data from an experimental facility or the field. The spatial variation of ecosystem services was mapped following the Helsinki Commission (HELCOM) subdivisions of the Baltic Sea (2018), using the coordinates or regions the samples were taken from. For each paper, we extracted information on the start and end year of the investigation and calculated the duration of the related studies. In case any pressures were mentioned to affect the ecosystem and ultimately the ecosystem service provided, we extracted the type of pressure (e.g. acidification, temperature change, boating/physical disturbance) and its effect on the ecosystem (see Supplementary Table S2). Further, we were interested if and how the ecosystem services were analyzed in terms of their impact on human well-being, especially through monetary (e.g. choice experiment, travel cost, abatement cost) or nonmonetary (e.g. performance value, ratings/indices or quantitative/ qualitative ranking) valuation methods.

The Eco-GAME matrix
To assess the current state of knowledge and enhance communication between science-policy interactions, ecosystem services were assessed according to the Eco-GAME matrix (Table 1). GAME stands for Governance Assessment Matrix Exercise (Sajeva et al., 2020), which is used as an evaluation tool in different contexts, such as sustainability, social learning, or ecosystem services. Based on expert opinions, the Eco-GAME matrix links ecological and socio-economic systems and evaluates the current level of knowledge within and between these systems in four dimensions: natural, economic, human and social (Table 2,  Supplementary Table S3). This is done by scoring how the studied ecological processes translate into ecosystem services in each publication ( Table 1). The Eco-GAME matrix scores range from 0 (knowledge gap) to 7 (identification of a future vision and a policy to reach UN Sustainable Development Goals) and each ecosystem service was scored in all four dimensions. For example, a study that assessed the biomass and monetary value of a mussel bed would be ranked as 3 (natural and economic dimension), while an additional quantification of impacts on human well-being is ranked as 4 (human and social dimension). Details on the scores within each dimension and examples can be found in the Supplementary Table S3. Ultimately, the Eco-GAME matrix provides a practical tool for assessing and categorizing the current state of knowledge about coastal ecosystem services in the Baltic Sea. By applying the Eco-GAME matrix, we can provide an overview of the robustness of both ecological and socio-economic knowledge to inform stakeholders about knowledge gaps that need to be addressed in order to proceed towards evidence-based sustainable decision-making.

Data visualization
All results were analyzed and plotted using R v3.6.1. The packages  (Supplementary Table S2).

Results
Overall, 1740 individual indicators of ecosystem services were recorded (hereafter ecosystem service records, ESR). Several of the 657 papers identified multiple ESR, since they investigated more than one ecosystem service or assessed more than one species (mean = 2.6 ESR/paper). The geographic locations of these 1740 ESR were unevenly distributed among the Baltic Sea HELCOM regions with some regions such as the Gdansk Basin (218 ESR) and the Kiel Bay (213 ESR) occurring more often compared to the Bothnian Bay (0 ESR), The Quark (8 ESR) or The Sound (16 ESR). Some studies covered more than one HELCOM region or were assessed Baltic Sea wide (Fig. 2). The reviewed studies were conducted between the years 1883 and 2018 with a duration ranging from 1 to 60 years ( Fig. 3A). Furthermore, 37 modelling studies were reviewed. Two of these modelled future scenarios starting in 2050 and 2070, while others modelled periods of up to 100 years, starting in the present and reaching into 2100-2113. Out of the 1740 ESR, 1067 were related to macroalgae, 215 to seagrass and 458 to mussels (Fig. 3B). The higher number of studies addressing macroalgae or mussel beds compared to seagrass is likely related to their more frequent, and widespread occurrence in the Baltic Sea. In total, 103 different genera were investigated, with the most common being Mytilus (mussel beds), Fucus (macroalgae) and Zostera (seagrass).
In total, we identified 20 different ecosystem services related to macroalgae, seagrass and mussel beds in the Baltic Sea (Fig. 3C). These services included six provisioning, six regulating, seven supporting services but only one cultural service (Fig. 3C, Table 3). The cultural service was "education and scientific information", as species were used as biomarkers or bioindicators for nutrients or toxins. The most frequently reported ecosystem services were the provisioning service "raw material" (533 ESR), the supporting service "providing habitat" (262 ESR) and the regulating service "regulation of pollutants" (215 ESR). "Education and scientific information", the only cultural service, resulted in 169 ESR.
The meta-evaluation via the Eco-GAME matrix revealed a strongly skewed knowledge distribution towards the natural dimension mostly reaching a knowledge level of 3 and 4, while the other dimensions were mostly scored between 0 and 2. This outcome was expected, considering that we investigated the value chain of ecosystem services starting from the species level, which is often not directly considered in studies with a socio-economic focus. For the natural dimension, this means that most ecosystem services were quantitatively assessed (Eco-GAME score 3) and their interactions with other ecosystem elements and/or dimensions (Eco-GAME score 4) are established. For instance, we have a quantitative understanding of the biomass/raw material that is provided and how this biomass is used by other organisms as habitat and food or utilized by humans as biomedical products or in human food production. However, for most of these ecosystem services, we identified a knowledge gap in the value chain towards assessments of economic, societal and individual values (score 0). Only for 140 ESR was a qualitative understanding of potential economic values reached resulting in a score of 2 in the economic dimension. The evaluated study by Risén et al., 2017 obtained the highest Eco-GAME matrix scores (economic dimension: 6, natural dimension: 5, social dimension: 4, human dimension: 4) as it defined future goals for the use of macroalgae biomass in the form of beach cast removal.
For many ESR a qualitative understanding (score 2) of the collective (687 on social dimension) and individual (678 on human dimension) human preferences and needs was reached. While most provisioning and supporting services were scored 0 (no knowledge) in the human and social dimension, cultural services were by definition always scored 2 (qualitative knowledge). Regulating services were most often scored 2 in both dimensions. Another study that obtained high Eco-GAME matrix scores (Lindegarth et al., 2014) assessed different management scenarios of macroalgae (Fucus vesiculosus) and seagrass (Zostera marina), which provide food and habitat for other organisms and further promote fisheries. This study was scored 5 (multi-dimensional interaction knowledge) on the human dimension, because humans use this ecosystem service and adjust their management accordingly.
We identified a total of 38 pressures impacting ecosystem services (Fig. S1, Table S2). As pressures, we considered any direct (e.g. boating/physical disturbance) or indirect (e.g. acidification, warming) anthropogenic effects. Out of the 1740 ESR, 1100 were assessed in the context of pressures on species and the services they provide. The most commonly addressed pressures in the context of coastal ecosystem services in the Baltic Sea were toxins (356), nutrients (302) and the change in salinity (94) as predicted for this region (Meier et al., 2006). Multiple stressors with potential interacting effects have been assessed in the context of 177 ESRs. Here, it is important to note that the most recurrent assessed pressures might not necessarily represent the most severe threats to coastal ecosystems and their services (Fig. 5).

Discussion
This study systematically reviewed Baltic Sea mussel bed, macroalgal and seagrass habitats and meta-evaluated their associated ecosystem services along natural and socio-economic dimensions. Among 657 papers in total, we quantified how well links between Table 1 Eco-GAME matrix scoring system for the level of knowledge on ecosystem services (adapted from Sajeva et al., 2020). For the detailed information see also supplementary  Table S3.
Eco-GAME levels of knowledge on ecosystem service     ecosystems and their derived socio-economic benefits were established. To this end, we scored the level of interaction between natural and socio-economic dimensions and the applicability for management practices and policies using the Eco-GAME matrix. This analysis revealed relatively good quantitative information on the ecological foundation of ecosystem services (Eco-GAME scores 2-3, Fig. 4). At the same time, the knowledge status on the complete value chain from the ecosystem to the derived socio-economic benefits and potential management implications was poor (Eco-GAME scores 4-7). In the following paragraphs, we outline all ecosystem services that were identified, elaborate on the missing links within the value chain and propose a framework to overcome these issues. Of the 20 different ecosystem services identified in this survey, macroalgae were recognized to provide 19 ecosystem services with seagrass and mussel beds each providing 15 (Fig. 3C, Table 3). All three coastal habitats provide a variety of raw materials in the form of biomass, chemical and genetic resources and other organisms make use of this biomass as food or habitat. In total, only a small amount of ESR were related to seagrass (13%) despite a growing recognition of their role in carbon storage and sequestration (Duarte et al., 2005;Röhr et al., 2016), coastal protection (Fonseca and Cahalan, 1992;Orth et al., 2006) and fisheries production (Jänes et al., 2020a;Jänes et al., 2020b). We are specifically lacking information on the extent to which seagrass meadows can be utilized in food and feed production, as fertilizer or in biomedical products. In food production for humans, the other coastal ecosystems play a key role since they can be directly consumed or processed and used in agar production (Tuvikene et al., 2010). In agriculture and aquaculture, macroalgae can be used as feed for pigs (Michalak et al., 2015) and as a mineral feed supplement for livestock (Chojnacka, 2008), while mussels can be used as feed for fish and hens (Carlberg et al., 2015;Carlberg et al., 2018;Jönsson, 2009;Vidakovic et al., 2016). Baltic seagrass and mussel beds are involved in sediment retention through biodeposition and erosion control (Alexandrowicz, 1977;Joensuu et al., 2018;Reusch et al., 1994). However, it has been shown that filamentous and small branched algae can also increase sediment retention in the northern Great Barrier Reef (Purcell, 2000) indicating a potential role for Baltic macroalgae. Thus far, within the Baltic Sea, only macroalgae have been investigated for their properties to serve as biomedical products. For example, the extracts of macroalgae show antimicrobial and anti-inflammatory activity (Goecke et al., 2012;Grünewald et al., 2009), and inhibit the viability of pancreatic cancer cell lines (Geisen et al., 2015). Interestingly, seagrass species from the South East Coast of India have shown antibiotic activity against human pathogenic bacteria and fungi (Ravikumar et al., 2010). In Portugal, the eelgrass Zostera marina has been shown to selectively decrease the viability of tumorous neuronal cells (Custódio et al., 2016). Considering these findings, we argue that there is a great potential for the use of marine natural products of seagrass from the Baltic Sea in the field of biomedicine. Considering biotechnological products, macroalgae, also in the form of beach cast, have shown a potential application as biogas and biofuel (Barbot et al., 2015;Bucholc et al., 2014;Kaspersen et al., 2016;Plis et al., 2015;Risén et al., 2014;Wollak et al., 2018), while seagrass and mussels can be utilized for biomethane production (Kaspersen et al., 2016;Wollak et al., 2018). While we identified 20 important ecosystem services of coastal Baltic ecosystems that support human needs and well-being, the studies mentioned above, particularly on seagrass, indicate that many more are currently not recognized. The information about ecosystem services is unevenly distributed geographically, with clear research hotspots in the western and central Baltic such as Gdansk and Kiel Bay (Fig. 2), similar results have been found previously (Sagebiel et al., 2016). At the same time, there were only a few studies from the northern Baltic Sea. While a reduced number of studies in the margins of the Baltic Sea might partially be explained by the lack of some of our target species in these regions (seagrass and mussels), research hotspots were observed close to research institutions. Such uneven spatial resolution has important implications as the Baltic Sea is characterized by a multitude of gradients and its sub-basins strongly differ from each other (Ojaveer et al., 2010). Therefore, if some areas are understudied we are not able to characterize ecosystem services and make scenario-specific predictions in those areas.
Considering the ongoing intensification and diversification of human pressures, we must further understand how different ecosystem elements are linked and how vulnerable they are to direct and indirect anthropogenic pressures. Experimental studies can help us in this endeavor since they allow us to build cause-effect relationships and predict spatiotemporal patterns of ecosystem services. Overall, we encountered a high proportion of experimental studies (>90%) compared to any other type of study (field study or modelling approach). However, these experiments mostly dealt with one or two species at a time, leaving most links within the natural system understudied. Further, only 70 out of 1740 ESR were assessed with multiple pressures in an experimental context. Our systematic assessment of ecosystem vulnerability identified excess nutrients together with toxic substances to be among the major pressures with high impact on the Baltic Sea ecosystems (Andersen et al., 2011;Conley et al., 2007;Korpinen et al., 2012). Anthropogenic nutrient inputs and associated eutrophication result in the loss of keystone macroalgae and seagrass, rapid growth of filamentous algae, decreased water transparency, and cause anoxia that often leads to the collapse of benthic communities (Andersen et al., 2011;Baden et al., 2012;Conley et al., 2007;Korpinen et al., 2012; Nielsen et al., 2003;Schubert et al., 2013). By taking up nutrients and filtering plankton, seagrass, macroalgae and mussel beds increase water clarity and counteract eutrophication (Austin et al., 2017;Kotta et al., 2020;Lindahl et al., 2005). This ecosystem service can actively be used through, for instance, mussel farming, which has been shown to remove up to 1000 t of nitrogen and 70 t of phosphorus per year (Schernewski et al., 2012). As a result of increased nutrient loads, the biomass of macroalgae and mussel species can increase in certain areas, for instance, at sewage treatment plants (Anger, 1977;Berezina et al., 2017). Furthermore, healthy ecosystems can contribute to the maintenance of ecosystem resilience by increasing community variability and stability (Kraufvelin, 2007), supporting recolonization (Anthony and Svane, 1995) and promoting gene flow (Arroyo et al., 2006). However, sensitive species vanish quickly when turbidity increases resulting in decreased biodiversity, which in turn reduces ecosystem resilience and impairs ecosystem services (Hansen and Snickars, 2014;Oliver et al., 2015). In the context of ecosystem services, the pollution with toxins and hazardous substances constitutes a severe threat (Bełdowska et al., 2015;Mazur-Marzec et al., 2007;Olenycz et al., 2015;Railo et al., 2018). These substances not only accumulate in mussels, macroalgae and seagrass, which constantly take them up from the water, but also enter the food web ultimately affecting humans (Stoeppler and Brandt, 1979). Overall, this highlights an urgent need to curb pollution and reduce other pressures on the Baltic Sea ecosystems and approach a good environmental status (GES) as a prerequisite for humans to benefit from the full range of ecosystem services. Understanding the value of ecosystem services has been proven to be important for decision making (Watson et al., 2016) and useful for raising awareness and communicating complex knowledge to the wider public (Bagstad et al., 2013;Risén et al., 2017). By anchoring our literature search on three coastal habitats we found that only eight studies (1.2%) investigated the entire value chain by applying economic valuation methods to link the ecosystems via their provided services with the derived socio-economic benefits. This finding is in line with a previous review concluding that Baltic marine ecosystem services have rarely been economically valued (Sagebiel et al., 2016). Furthermore, this knowledge gap is even apparent in the ecosystem service classification systems, which miss the connection between ecological and socio-economic attributes (Hummel et al., 2019). Considering this issue, we assessed the methodological approaches to economic valuation used in these eight papers in more detail (Table 4). While all eight studies have made a great effort to evaluate ecosystem services, most of them could only cover a section of the value chain from ecosystems to socio-economic benefits. This also demonstrates the lack of data and the complexity of ecological functions. Additional attempts to link ecological properties with socio-economic measures have been made by some recent studies capturing people's perceptions, choices and willingness-to-pay for maintaining or enhancing marine ecosystem services (Ahtiainen et al., 2014;Bateman et al., 2011;Kosenius and Markku, 2015). Since human perceptions are often affected by cultural aspects (Ahtiainen et al., 2014), past experiences or education, we argue that these methods will need to be backed-up by integrative assessments allowing for a more objective service valuation. Therefore, research efforts need to be devoted to addressing the interface between ecosystem biology and functional biodiversity research and how this translates into concrete societal implications including economic benefits. More specifically, if we want to develop appropriate valuation studies and deliver the results in policies, it is fundamental to better understand the contribution of different species to provide various ecosystem services and the roles of environmental factors to modulate the intensities of these services (e.g. seagrasses to capture and store carbon; (Röhr et al., 2016;Stål et al., 2008)). This makes an economic valuation of supporting and regulating ecosystem services and intermediate goods much more challenging but of utmost importance compared to the valuation of final provisioning services (Beaumont et al., 2007).
We suggest that any future quantitative information on ecosystem services in the Baltic Sea should be combined with socio-economic information, with the ultimate goal to transfer knowledge among disciplines. In particular, we recommend to consider the following issues: (i) knowledge on ecosystem services in the Baltic Sea and elsewhere could be assessed using Eco-GAME or similar tools to systematically map best practices for interdisciplinary knowledge transfer; (ii) the interdependencies of ecosystem elements in generating a service need to be evaluated; (iii) methodologies need to be applied systematically within but also between scientific fields to assess how ecosystems translate into socio-economic benefits via the functions and services they provide; (iv) data-driven and easy-to-use tools of cumulative impact assessment of human pressures on ecosystem services should be developed that can inform managers and policy makers (Franke et al., 2020).
For instance, a recent Mapping Ocean Wealth project in Australia (Carnell et al., 2019) provides a great conceptual example how existing information about ecosystems and ecological processes was used to construct spatially explicit mathematical models with a capability of predicting the social and economic benefits provided by coastal Table 4 Summary table on economic valuation methods that have been used to link the studied habitats (seagrass, mussels, macroalgae) via their provided services with the derived socio-economic benefits.

Definition
Context References

Market price
The market price method uses the prices of goods and services that are bought and sold in commercial markets to determine the value of an ecosystem service.
Provisioning ecosystem services (e.g. mussels) used in food production have markets, and market prices can be used for valuation. (Gren et al., 2009;Lindahl et al., 2005;Schernewski et al., 2012) Preference-based methods The revealed preference approaches extrapolate the individual willingness to pay or accept by examining the choices that they make within a market. The stated preference approaches of ecosystem valuation survey individuals to find out what they state as their value of the ecosystem attributes, good, and services.
Non-market ecosystem services provide immediate benefits (or harms) to people and here revealed preference quantify value (of e.g. beach cast removal or good water quality) through actual behavior and stated preference through potential futures. (Lindegarth et al., 2014;Risén et al., 2017;Stål et al., 2008) Cost-based methods Cost-based methods estimate values based on the costs of avoiding damages due to lost services, the cost of replacing environmental assets, or the cost of providing substitute goods.
Quantifying land-and sea-based mitigation measures to reduce adverse effects of eutrophication showed that mussel farming is a cost-efficient abatement method in terms of net cost saving. Suitable to evaluate intermediate goods and services. (Gren et al., 2018) Interdisciplinary methods Insights from ecology and environmental economics are synthesized to provide a unifying perspective of the value of ecosystem services.
Valuing ecosystem services by quantifying the linkage between human-induced pressures, habitat characteristics, ecological functions and services they provide. (Lindegarth et al., 2014;Stål et al., 2008) Benefit transfer Available information from other studies and/or other areas are transferred to estimate economic values of ecosystem services.
The value of carbon storage and sequestration capacity of Baltic Sea seagrass meadows was partly based on ecological and economic parameters from other regions. ecosystems. This model was subsequently applied in the context of carbon sequestration and fisheries production. Based on the Eco-GAME analysis matrix, the Mapping Ocean Wealth project would have been the highest-scoring individual study effectively transferring knowledge between natural, economic, social and human dimensions. As such it provides a robust framework that can be adapted for use in the Baltic Sea and globally.

Conclusions
Science-based decisions on the sustainable management of ecosystems and the services they provide require a deep understanding of the inter-relationships between ecosystems, natural and social sciences and how these impinge upon human well-being. By synthesizing information on ecosystem services provided by coastal Baltic Sea ecosystems, this study has contributed to the growing need for integrative data for sustainable marine resource management. Despite the significant amount of extracted information, only 8 out of 657 studies provided insights into the links between ecosystems, services and the socio-economic benefits. Furthermore, these studies differed in terms of economic valuation methods, highlighting the lack of a systematic methodological framework, measuring cross-comparable units, that could inform collective decision-making. To close this knowledge gap, we propose an analytical framework that is capable of directly linking existing quantitative information about ecosystem service generation with human benefit and informs policy makers for meeting the UN Sustainable Development Goals.

Declaration of competing interest
The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.