The vertical distribution and biological transport of marine microplastics across the epipelagic and mesopelagic water column.

Plastic waste has been documented in nearly all types of marine environments and has been found in species spanning all levels of marine food webs. Within these marine environments, deep pelagic waters encompass the largest ecosystems on Earth. We lack a comprehensive understanding of the concentrations, cycling, and fate of plastic waste in sub-surface waters, constraining our ability to implement effective, large-scale policy and conservation strategies. We used remotely operated vehicles and engineered purpose-built samplers to collect and examine the distribution of microplastics in the Monterey Bay pelagic ecosystem at water column depths ranging from 5 to 1000 m. Laser Raman spectroscopy was used to identify microplastic particles collected from throughout the deep pelagic water column, with the highest concentrations present at depths between 200 and 600 m. Examination of two abundant particle feeders in this ecosystem, pelagic red crabs (Pleuroncodes planipes) and giant larvaceans (Bathochordaeus stygius), showed that microplastic particles readily flow from the environment into coupled water column and seafloor food webs. Our findings suggest that one of the largest and currently underappreciated reservoirs of marine microplastics may be contained within the water column and animal communities of the deep sea

Author Correction: The vertical distribution and biological transport of marine microplastics across the epipelagic and mesopelagic water column.

An amendment to this paper has been published and can be accessed via a link at the top of the paper

Far from a distraction: Plastic pollution and the planetary emergency

Pollution of the environment with plastics has garnered significant public attention, but the topic has also been the focus of controversy, including assertions that resources are better spent on other topics, such as global warming. Here, we argue that plastic pollution and climate change are fundamentally linked, from the extraction of fossil fuels to the production of plastics, and eventual disposal. We demonstrate how plastics research and funding currently lag significantly behind that of climate change and conclude by advocating for a more integrated approach to addressing pressing conservation issues in the time of a planetary emergency.This is an open access article, available to all readers online, published under a creative commons licensing (https://creativecommons.org/licenses/by/4.0/). The attached file is the published version of the article

Non-invasive fecal analysis to evaluate stress in vulnerable marine mammals

A growing number of anthropogenic stressors have been found to impact marine mammals, leading to deleterious effects at both the individual and sometimes population-level. Hormones are an important facet of wildlife health, and can be used to quantify a range of anthropogenic stressors such as vessel noise, habitat disturbance, and pollution. Fecal analysis provides a non-invasive form of stress assessment that allows for evaluation of hormone levels, which can be utilized for marine mammal species whose feces float. Fecal analysis, mostly targeting the glucocorticoid hormone cortisol and its metabolites, has been widely employed in the terrestrial animal realm and is now being extended to marine systems. Here, we reviewed all known studies that have employed fecal analysis on threatened or endangered marine mammals. We found that large whales, both baleen and toothed, have been sampled comparatively more than other vulnerable marine mammal species, with no dolphin and few pinniped species being sampled. Non-invasive fecal analysis remains largely underutilized on vulnerable marine mammals due to logistical difficulties associated with obtaining marine fecal matter, coupled with logistical challenges associated with fecal processing. We opportunistically interviewed experts working with threatened or endangered marine mammal species that have not been targeted for fecal analysis to obtain information on whether or not those species would be potential candidates for fecal stress research. We then draw on various anthropogenic interactions that have been documented on vulnerable marine mammals that would warrant additional hormonal scat research to gain a better understanding of animal physiology and behavior. We chronicle the evolution of fecal analysis for cortisol as a viable technique for stress evaluation, and highlight future challenges and potential opportunities to expand this approach to studying other vulnerable marine mammals

Keepin’it real: London youth hip hop as an authentic performance of belief

Hip hop is a global cultural phenomenon that encompasses rap music, dance, graffiti art, and fashion as well as particular ways of being. One sub-genre of hip hop is Gospel rap, in which Christian rappers attempt to represent the truth of God as a tangible reality, thereby keepin it real. This study investigates how young British Jamaican male adults in the Brixton area of London appropriate hip hop for their own ends. Based on original raps authored and performed by these young people, the research finds that their representations of spiritual reality are influenced by the conventions and boundaries of professional Gospel rap. The study describes how youth incorporate religious hip hop into their everyday lives and argues that in some cases hip hop performance becomes a method for pedagogically reshaping the body, giving religious beliefs an embodied authenticity

Alternative and legacy flame retardants in marine mammals from three northern ocean regions

Flame retardants are globally distributed contaminants that have been linked to negative health effects in humans and wildlife. As top predators, marine mammals bioaccumulate flame retardants and other contaminants in their tissues which is one of many human-imposed factors threatening population health. While some flame retardants, such as the polybrominated diphenyl ethers (PBDE), have been banned because of known toxicity and environmental persistence, limited data exist on the presence and distribution of current-use alternative flame retardants in marine mammals from many industrialized and remote regions of the world. Therefore, this study measured 44 legacy and alternative flame retardants in nine marine mammal species from three ocean regions: the Northwest Atlantic, the Arctic, and the Baltic allowing for regional, species, age, body condition, temporal, and tissue comparisons to help understand global patterns. PBDE concentrations were 100–1000 times higher than the alternative brominated flame retardants (altBFRs) and Dechloranes. 2,2′,4,5,5′-pentabromobiphenyl (BB-101) and hexabromobenzene (HBBZ) were the predominant altBFRs, while Dechlorane-602 was the predominant Dechlorane. This manuscript also reports only the second detection of hexachlorocyclopentadienyl-dibromocyclooctane (HCDBCO) in marine mammals. The NW Atlantic had the highest PBDE concentrations followed by the Baltic and Arctic which reflects greater historical use of PBDEs in North America compared to Europe and greater industrialization of North America and Baltic countries compared to the Arctic. Regional patterns for other compounds were more complicated, and there were significant interactions among species, regions, body condition and age class. Lipid-normalized PBDE concentrations in harbor seal liver and blubber were similar, but HBBZ and many Dechloranes had higher concentrations in liver, indicating factors other than lipid dynamics affect the distribution of these compounds. The health implications of contamination by this mixture of compounds are of concern and require further research

Author Correction: The vertical distribution and biological transport of marine microplastics across the epipelagic and mesopelagic water column.

An amendment to this paper has been published and can be accessed via a link at the top of the paper

The vertical distribution and biological transport of marine microplastics across the epipelagic and mesopelagic water column

Plastic waste has been documented in nearly all types of marine environments and has been found in species spanning all levels of marine food webs. Within these marine environments, deep pelagic waters encompass the largest ecosystems on Earth. We lack a comprehensive understanding of the concentrations, cycling, and fate of plastic waste in sub-surface waters, constraining our ability to implement effective, large-scale policy and conservation strategies. We used remotely operated vehicles and engineered purpose-built samplers to collect and examine the distribution of microplastics in the Monterey Bay pelagic ecosystem at water column depths ranging from 5 to 1000 m. Laser Raman spectroscopy was used to identify microplastic particles collected from throughout the deep pelagic water column, with the highest concentrations present at depths between 200 and 600 m. Examination of two abundant particle feeders in this ecosystem, pelagic red crabs (Pleuroncodes planipes) and giant larvaceans (Bathochordaeus stygius), showed that microplastic particles readily flow from the environment into coupled water column and seafloor food webs. Our findings suggest that one of the largest and currently underappreciated reservoirs of marine microplastics may be contained within the water column and animal communities of the deep sea

The vertical distribution and biological transport of marine microplastics across the epipelagic and mesopelagic water column.

Plastic waste has been documented in nearly all types of marine environments and has been found in species spanning all levels of marine food webs. Within these marine environments, deep pelagic waters encompass the largest ecosystems on Earth. We lack a comprehensive understanding of the concentrations, cycling, and fate of plastic waste in sub-surface waters, constraining our ability to implement effective, large-scale policy and conservation strategies. We used remotely operated vehicles and engineered purpose-built samplers to collect and examine the distribution of microplastics in the Monterey Bay pelagic ecosystem at water column depths ranging from 5 to 1000 m. Laser Raman spectroscopy was used to identify microplastic particles collected from throughout the deep pelagic water column, with the highest concentrations present at depths between 200 and 600 m. Examination of two abundant particle feeders in this ecosystem, pelagic red crabs (Pleuroncodes planipes) and giant larvaceans (Bathochordaeus stygius), showed that microplastic particles readily flow from the environment into coupled water column and seafloor food webs. Our findings suggest that one of the largest and currently underappreciated reservoirs of marine microplastics may be contained within the water column and animal communities of the deep sea