Front. Environ. Sci.Frontiers in Environmental ScienceFront. Environ. Sci.2296-665XFrontiers Media S.A.10.3389/fenvs.2021.676011Environmental ScienceEditorialEditorial: Microplastics in the Marine Environment: Sources, Distribution, Biological Effects and Socio-Economic ImpactsFriasJoão P.1*†Ivar do SulJuliana A.2*†PantiCristina3*†LimaAndré R. A.4*†1Marine and Freshwater Research Centre (MFRC), Galway-Mayo Institute of Technology (GMIT), Galway, Ireland2Leibniz Institute for Baltic Sea Research, Rostock, Germany3Department of Physical, Earth and Environmental Sciences, University of Siena, Siena, Italy4Department of Biosciences, Marine and Environmental Sciences Centre (MARE), University Institute of Psychological, Social and Life Sciences (ISPA), Lisbon, Portugal
Edited and reviewed by: Oladele Ogunseitan, University of California, Irvine, United States
*Correspondence: João P. Frias joao.frias@gmit.ieJuliana A. Ivar do Sul julianasul@gmail.comCristina Panti panti4@unisi.itAndré R. A. Lima andre.ricardoaraujolima@gmail.com
This article was submitted to Toxicology, Pollution and the Environment, a section of the journal Frontiers in Environmental Science
†These authors have contributed equally to this work
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Editorial on the Research Topic Microplastics in the Marine Environment: Sources, Distribution, Biological Effects, and Socio-Economic Impactsplastic pollutionenvironmental monitoringecotoxicologywaste managementpolicy recommendations
From all the synthetic materials ever produced, plastic is the most versatile, overthrowing both glass and metal in many applications, due to its low weight and cost. Global plastic production started shortly after WWII, around the 1950's (PlasticsEurope, 2010), and became a popular household item around the same time (Time, 1955). Since then, global production has been exponentially increasing at a rate of 8% per annum (PlasticsEurope, 2020). Notably, it took only 10 (1965) to 17 (1972) years until researchers started noticing the first evidence of plastics in the marine environment (Carpenter and Smith, 1972; Ryan, 2015). Between the 1960's and the 1990's, several studies reported direct consequences of plastic interaction with vessels, particularly entanglement of propellers, and with wildlife, via entanglement or ingestion (Ryan, 2015). Consistent findings throughout the world led to calls for action, due to the likelihood that over time the problem would be amplified by fragmentation of larger plastic items into smaller pieces (Carpenter and Smith, 1972). Microplastic research is now a well-established research field, with at least 2,500 papers published so far on this topic (Zhang et al., 2020).
Despite being a relatively recent research field, microplastic pollution has gone beyond the realm of academia into the general public. Several stakeholders with different vested interests are involved in this topic, from standardization bodies to grassroot movements, from national agencies to research institutions. Plastic has become a social issue, due to its economic and environmental consequences, which affect human activities and the natural cycles of the planet. In order to contribute to the debate, this Research Topic (RT) highlights recent research developments in the microplastic field, in a diverse set of topics that cover relevant aspects from methodologies to modeling, and from impacts on fauna to legislation. A total of 23 research papers from 43 primary and partner institutions, in four continents and spread across 15 countries (Figure 1A), reveal the prevalence of this global problem, and report on some of the solutions ahead.
(A) Number of institutions primary and partner institutions per manuscript (N = 43) contributing to this RT. (B) Distance-base map (based on association strength) of a set of 67 keywords retrieved from 21 papers. Keywords are grouped into 9 clusters of different colors.
A Short Bibliometric Analysis of Papers Published in This RT
The author's keywords from each paper were compiled and analyzed in the software VOS viewer to illustrate the diversity of topics explored here (Van Eck and Waltman, 2010). The set of 21 papers (with their final versions published by 01.03.2021) in this RT had a total of 152 keywords. To standardize keywords describing the same concept, a thesaurus was created (Table 1). For example, polyethylene, polypropylene and other polymer types were all grouped under the keyword “polymers.” As such, a total of 67 keywords are presented in the final set. The most popular keyword is “microplastics” (N = 10 occurrences), followed by “fish” (N = 5), “plastic pollution” and “plastic ingestion” (N = 4). The keywords “polymers,” “spectroscopy,” and “marine debris” appeared in three papers each (N = 3). All other keywords appeared in one or two publications only, indicating a generally very low frequency of used keywords and therefore a variety of studied topics (Figure 1B).
Thesaurus of alphabetical ordered author's keywords (“Label”) and standardized concepts.
Label
Replace by
Anthropogenic litter
Marine debris
Atlantic chub mackerel
Fish
Atlantic salmon (Salmo salar L.)
Fish
Benzo(a)pyrene
Hydrophobic organic chemicals
Chlorpyrifos
Hydrophobic organic chemicals
Combined sewer overflow
Wastewater
Cost-effective marine litter monitoring method
Monitoring
EE2
Hydrophobic organic chemicals
Extraction techniques
Methods
FT-IR spectroscopy
Spectroscopy
GIT analysis
Plastic ingestion
Horse mackerel
Fish
Hydrodynamic dispersion model
Model
Hydrodynamic model
Model
Infrared imaging
Spectroscopy
Ingestion
Plastic ingestion
Lates calcarifer
Fish
Long-term monitoring
Monitoring
Lutjanus argentimaculatus
Fish
Marine litter
Marine debris
Microplastic
Microplastics
Microplastic (MP)
Microplastics
Microplastic pollution
Microplastics
pe
Polymers
Peppery furrow shell
Bivalve
Pet
Polymers
Plastic and plastics
Plastic pollution
Plastic polymers
Polymers
Plectropomus leopardus
Fish
Polyethylene
Polymers
Polyethylene terephthalate
Polymers
Polyethylene(PE)
Polymers
Polypropylene
Polymers
Polystyrene
Polymers
Polystyrene(PS)
Polymers
pp
Polymers
Reflectance micro-FTIR
Spectroscopy
Sand
Reference material
Selachians
Fish
Silica
Reference material
Sodium iodide
Density separation solution
SPM
Particulate matter
Stickleback
Fish
Storage
Methods
Suspended matter
Particulate matter
Three-spined stickleback (Gasterosteus aculeatus)
Fish
Top marine beach litter items
Marine debris
Uptake
Plastic ingestion
Wastewater treatment plant (WWTP)
Wastewater
Wastewater treatment plants
Wastewater
Zebrafish
Fish
Authors keywords are listed in alphabetical order.
This RT included a relatively high number of papers using fish as a model organism (see “fish” in Figure 1B), either by exploring combined effects of (nano-micro) plastics and organic pollutants in teleost (Trevisan et al.; Bour et al.; Ašmonaite et al.; Abihssira-García et al.) or by improving extraction and analysis methods for predicting plastic ingestion in fish (Dawson et al.; Pedà et al.; Pequeno et al.). In the same cluster, the keyword “plastic ingestion” included papers that explored the transfer of microplastics particles among successive levels in marine trophic webs or potential transfer of plastic additives and chemicals from plastics to biota when ingested (Costa et al.; Kühn et al.). Also grouped together are papers using the keyword “polymers” showing works that explore polymer-specific effects of particles in model-animals (Santana et al.).
Papers with more general approaches are clustered around keywords such as “plastic pollution” and “marine debris” (Figure 1B, in yellow). These are papers related to legislations to mitigate plastic (marine) pollution (Da Costa et al.; Galaiduk et al.), potential bioindicators of (micro)plastic pollution (Reichelt and Gorokhova; Fossi et al.), but also to method development with potential to be used over large geographical areas (Enders et al.; Haseler et al.; Rodrigues et al.; Tagg et al.) and modeling of microplastic sources into the environment (Balthazar-Silva et al.; Gorman et al.; Schernewski et al.; Piehl, Atwood et al.; Piehl, Hauk et al.).
Conclusion
We considered this special issue to be very successful both in terms of number of papers published and variety of studies targeting several microplastic pollution issues. Notorious research advancements and science breakthroughs, as well as technological developments, are highlighted here based on the efforts of the microplastic scientific community over recent years. Manuscripts in this RT aim at fulfilling knowledge gaps while creating new research questions to fully understand the ubiquitousness of plastics in the environment. Although there is still a long way to go within this research extensive knowledge gathered so far [see for example Galgani et al. (2021)] will allow decision makers to make better decisions surrounding this global problem, while consolidating microplastic pollution as a permanent research field.
Plastic pollution is intrinsically linked to consumption habits and waste management practices globally. Therefore, recommendations need to be aligned with regulations and with the adequate use of market-based instruments, so that solving this problem is addressed holistically. One thing that the global pandemic brought to sight is that behavior change is possible, and when we work together reduction and prevention can be achieved. For example, understanding how to tackle losses and emission throughout the entire supply-chain will effectively reduce the abundances of plastic marine litter in the environment. That is an excellent way to start to flatten the current plastic pollution scenario worldwide.
Author Contributions
All authors listed have made a substantial, direct and intellectual contribution to the work, and approved it for publication.
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
The authors acknowledge the support of the Frontiers in Environmental Science Editorial Office, particularly Andrea Lazenby, considering the unusual circumstances related to the global COVID-19 outbreak.
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