Global Garbage News

Latest reports, research papers  and news stories about plastic can be found here, (other reports and statistics about other plastic related issues can be found here)

Thanks to Fabiano of www.globalgarbage.org for keeping us well informed.

 

, News, Marine Pollution Bulletin, Volume 102, Issue 1, 15 January 2016, Pages 4-8, ISSN 0025-326X,http://dx.doi.org/10.1016/j.marpolbul.2015.12.015.
(http://www.sciencedirect.com/science/article/pii/S0025326X15006360)

http://www.globalgarbage.org.br/mailinglist/S0025326X15006360.pdf

Tim Jesper Suhrhoff, Barbara M. Scholz-Böttcher, Qualitative impact of salinity, UV radiation and turbulence on leaching of organic plastic additives from four common plastics — A lab experiment, Marine Pollution Bulletin, Volume 102, Issue 1, 15 January 2016, Pages 84-94, ISSN 0025-326X,http://dx.doi.org/10.1016/j.marpolbul.2015.11.054.
(http://www.sciencedirect.com/science/article/pii/S0025326X15302010)
Abstract: Four common consumer plastic samples (polyethylene, polystyrene, polyethylene terephthalate, polyvinylchloride) were studied to investigate the impact of physical parameters such as turbulence, salinity and UV irradiance on leaching behavior of selected plastic components. Polymers were exposed to two different salinities (i.e. 0 and 35 g/kg), UV radiation and turbulence. Additives (e.g. bisphenol A, phthalates, citrates, and Irgafos® 168 phosphate) and oligomers were detected in initial plastics and aqueous extracts. Identification and quantification was performed by GC–FID/MS. Bisphenol A and citrate based additives are leached easier compared to phthalates. The print highly contributed to the chemical burden of the analyzed polyethylene bag. The study underlines a positive relationship between turbulence and magnitude of leaching. Salinity had a minor impact that differs for each analyte. Global annual release of additives from assessed plastics into marine environments is estimated to be between 35 and 917 tons, of which most are derived from plasticized polyvinylchloride.
Keywords: Consumer plastic; Leaching; Saltwater; Turbulence; UV; Additives

http://www.globalgarbage.org.br/mailinglist/S0025326X15302010.pdf

Outi Setälä, Joanna Norkko, Maiju Lehtiniemi, Feeding type affects microplastic ingestion in a coastal invertebrate community, Marine Pollution Bulletin, Volume 102, Issue 1, 15 January 2016, Pages 95-101, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.11.053.
(http://www.sciencedirect.com/science/article/pii/S0025326X15302009)
Abstract: Marine litter is one of the problems marine ecosystems face at present, coastal habitats and food webs being the most vulnerable as they are closest to the sources of litter. A range of animals (bivalves, free swimming crustaceans and benthic, deposit-feeding animals), of a coastal community of the northern Baltic Sea were exposed to relatively low concentrations of 10 μm microbeads. The experiment was carried out as a small scale mesocosm study to mimic natural habitat. The beads were ingested by all animals in all experimental concentrations (5, 50 and 250 beads mL− 1). Bivalves (Mytilus trossulus, Macoma balthica) contained significantly higher amounts of beads compared with the other groups. Free-swimming crustaceans ingested more beads compared with the benthic animals that were feeding only on the sediment surface. Ingestion of the beads was concluded to be the result of particle concentration, feeding mode and the encounter rate in a patchy environment.
Keywords: Microlitter; Bivalve; Crustacean; Ingestion; Coastal; Marine food web

http://www.globalgarbage.org.br/mailinglist/S0025326X15302009.pdf

Fabiana Tavares Moreira, Alessandro Lívio Prantoni, Bruno Martini, Michelle Alves de Abreu, Sérgio Biato Stoiev, Alexander Turra, Small-scale temporal and spatial variability in the abundance of plastic pellets on sandy beaches: Methodological considerations for estimating the input of microplastics, Marine Pollution Bulletin, Volume 102, Issue 1, 15 January 2016, Pages 114-121, ISSN 0025-326X,http://dx.doi.org/10.1016/j.marpolbul.2015.11.051.
(http://www.sciencedirect.com/science/article/pii/S0025326X15301983)
Abstract: Microplastics such as pellets have been reported for many years on sandy beaches around the globe. Nevertheless, high variability is observed in their estimates and distribution patterns across the beach environment are still to be unravelled. Here, we investigate the small-scale temporal and spatial variability in the abundance of pellets in the intertidal zone of a sandy beach and evaluate factors that can increase the variability in data sets. The abundance of pellets was estimated during twelve consecutive tidal cycles, identifying the position of the high tide between cycles and sampling drift-lines across the intertidal zone. We demonstrate that beach dynamic processes such as the overlap of strandlines and artefacts of the methods can increase the small-scale variability. The results obtained are discussed in terms of the methodological considerations needed to understand the distribution of pellets in the beach environment, with special implications for studies focused on patterns of input.
Keywords: Solid wastes; Input; Tidal cycle; Transect; Strandline

http://www.globalgarbage.org.br/mailinglist/S0025326X15301983.pdf

Christoph D. Rummel, Martin G.J. Löder, Nicolai F. Fricke, Thomas Lang, Eva-Maria Griebeler, Michael Janke, Gunnar Gerdts, Plastic ingestion by pelagic and demersal fish from the North Sea and Baltic Sea, Marine Pollution Bulletin, Volume 102, Issue 1, 15 January 2016, Pages 134-141, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.11.043.
(http://www.sciencedirect.com/science/article/pii/S0025326X15301922)
Abstract: Plastic ingestion by marine biota has been reported for a variety of different taxa. In this study, we investigated 290 gastrointestinal tracts of demersal (cod, dab and flounder) and pelagic fish species (herring and mackerel) from the North and Baltic Sea for the occurrence of plastic ingestion. In 5.5% of all investigated fishes, plastic particles were detected, with 74% of all particles being in the microplastic (< 5 mm) size range. The polymer types of all found particles were analysed by means of Fourier transform infrared (FT-IR) spectroscopy. Almost 40% of the particles consisted of polyethylene (PE). In 3.4% of the demersal and 10.7% of the pelagic individuals, plastic ingestion was recorded, showing a significantly higher ingestion frequency in the pelagic feeders. The condition factor K was calculated to test differences in the fitness status between individuals with and without ingested plastic, but no direct effect was detected.
Keywords: Marine debris; Plastic; Fish; Ingestion; North Sea; Baltic Sea

http://www.globalgarbage.org.br/mailinglist/S0025326X15301922.pdf

http://www.enveurope.com/content/28/1/2

Karen Duis and Anja Coors
Microplastics in the aquatic and terrestrial environment: sources (with a specific focus on personal care products), fate and effects
Environmental Sciences Europe 2016, 28:2
doi:10.1186/s12302-015-0069-y

Abstract
Due to the widespread use and durability of synthetic polymers, plastic debris occurs in the environment worldwide. In the present work, information on sources and fate of microplastic particles in the aquatic and terrestrial environment, and on their uptake and effects, mainly in aquatic organisms, is reviewed. Microplastics in the environment originate from a variety of sources. Quantitative information on the relevance of these sources is generally lacking, but first estimates indicate that abrasion and fragmentation of larger plastic items and materials containing synthetic polymers are likely to be most relevant. Microplastics are ingested and, mostly, excreted rapidly by numerous aquatic organisms. So far, there is no clear evidence of bioaccumulation or biomagnification. In laboratory studies, the ingestion of large amounts of microplastics mainly led to a lower food uptake and, consequently, reduced energy reserves and effects on other physiological functions. Based on the evaluated data, the lowest microplastic concentrations affecting marine organisms exposed via water are much higher than levels measured in marine water. In lugworms exposed via sediment, effects were observed at microplastic levels that were higher than those in subtidal sediments but in the same range as maximum levels in beach sediments. Hydrophobic contaminants are enriched on microplastics, but the available experimental results and modelling approaches indicate that the transfer of sorbed pollutants by microplastics is not likely to contribute significantly to bioaccumulation of these pollutants. Prior to being able to comprehensively assess possible environmental risks caused by microplastics a number of knowledge gaps need to be filled. However, in view of the persistence of microplastics in the environment, the high concentrations measured at some environmental sites and the prospective of strongly increasing concentrations, the release of plastics into the environment should be reduced in a broad and global effort regardless of a proof of an environmental risk.

Keywords: Plastic debris; Environmental concern; Persistence; Personal care products; Cosmetic products; Microplastic

http://www.enveurope.com/content/pdf/s12302-015-0069-y.pdf

http://www.enveurope.com/content/epub/s12302-015-0069-y.epub

http://www.enveurope.com/content/28/1/2/additional

Additional file 1: Table S1. Overview of ranges and mean or median values (underlined) of concentrations of microplastics (or, where specified, small plastic particles) in the marine environment based on Hidalgo-Ruz et al. [11] and selected recent publication. Table S2. Overview of ranges and mean or median values (underlined) of concentrations of microplastics (or, where specified, small plastic particles) in the freshwater environment. Table S3. Overview of effect concentrations derived in ecotoxicity tests with aquatic organisms exposed to microplastics.

Format: DOCX Size: 92KB Download file

http://www.enveurope.com/content/supplementary/s12302-015-0069-y-s1.docx

http://iopscience.iop.org/article/10.1088/1748-9326/10/12/124006

Erik van Sebille, Chris Wilcox, Laurent Lebreton, Nikolai Maximenko, Britta Denise Hardesty, Jan A van Franeker, Marcus Eriksen, David Siegel, Francois Galgani and Kara Lavender Law
A global inventory of small floating plastic debris
Environ. Res. Lett. 10 (2015) 124006
doi:10.1088/1748-9326/10/12/124006

Abstract
Microplastic debris floating at the ocean surface can harm marine life. Understanding the severity of this harm requires knowledge of plastic abundance and distributions. Dozens of expeditions measuring microplastics have been carried out since the 1970s, but they have primarily focused on the North Atlantic and North Pacific accumulation zones, with much sparser coverage elsewhere. Here, we use the largest dataset of microplastic measurements assembled to date to assess the confidence we can have in global estimates of microplastic abundance and mass. We use a rigorous statistical framework to standardize a global dataset of plastic marine debris measured using surface-trawling plankton nets and coupled this with three different ocean circulation models to spatially interpolate the observations. Our estimates show that the accumulated number of microplastic particles in 2014 ranges from 15 to 51 trillion particles, weighing between 93 and 236 thousand metric tons, which is only approximately 1% of global plastic waste estimated to enter the ocean in the year 2010. These estimates are larger than previous global estimates, but vary widely because the scarcity of data in most of the world ocean, differences in model formulations, and fundamental knowledge gaps in the sources, transformations and fates of microplastics in the ocean.

http://iopscience.iop.org/article/10.1088/1748-9326/10/12/124006/pdf

Supplementary data. (1.4 MB, pdf)

http://iopscience.iop.org/1748-9326/10/12/124006/media/erl124006_supdata.pdf

http://science.sciencemag.org/content/351/6269/aad2622

Colin N. Waters, Jan Zalasiewicz, Colin Summerhayes, Anthony D. Barnosky, Clément Poirier, Agnieszka Gałuszka, Alejandro Cearreta, Matt Edgeworth, Erle C. Ellis, Michael Ellis1, Catherine Jeandel, Reinhold Leinfelder, J. R. McNeill, Daniel deB. Richter, Will Steffen, James Syvitski, Davor Vidas, Michael Wagreich, Mark Williams, An Zhisheng, Jacques Grinevald, Eric Odada, Naomi Oreskes, Alexander P. Wolfe
The Anthropocene is functionally and stratigraphically distinct from the Holocene
Science  08 Jan 2016:
Vol. 351, Issue 6269, pp.
DOI: 10.1126/science.aad2622

Abstract
Human activity is leaving a pervasive and persistent signature on Earth. Vigorous debate continues about whether this warrants recognition as a new geologic time unit known as the Anthropocene. We review anthropogenic markers of functional changes in the Earth system through the stratigraphic record. The appearance of manufactured materials in sediments, including aluminum, plastics, and concrete, coincides with global spikes in fallout radionuclides and particulates from fossil fuel combustion. Carbon, nitrogen, and phosphorus cycles have been substantially modified over the past century. Rates of sea-level rise and the extent of human perturbation of the climate system exceed Late Holocene changes. Biotic changes include species invasions worldwide and accelerating rates of extinction. These combined signals render the Anthropocene stratigraphically distinct from the Holocene and earlier epochs.

http://www.globalgarbage.org.br/mailinglist/aad2622.pdf

, Earth’s oceans show decline in microscopic plant life, Marine Pollution Bulletin, Volume 100, Issue 1, 15 November 2015, Pages 1-4, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.10.048.
(http://www.sciencedirect.com/science/article/pii/S0025326X15005718)

http://www.globalgarbage.org.br/mailinglist/S0025326X15005718.pdf

http://www.globalgarbage.org.br/mailinglist/Micro2016_2ndCircular.pdf

Lanzarote, January 14th 2016

SECOND CIRCULAR: CALL FOR ABSTARCTS AND SIDE EVENTS

We are pleased to invite the scientific community and stakeholders to MICRO 2016, an international conference that will be hosted in Lanzarote, Spain, 25 – 27 May 2016:

Fate and Impact of Microplastics in Marine Ecosystems: From the Coastline to the Open Sea

MICRO 2016 provides an opportunity to share available knowledge, fill in gaps, identify new questions and research needs, and develop commitments to operationalize solutions.

http://www.weforum.org/reports/the-new-plastics-economy-rethinking-the-future-of-plastics

The New Plastics Economy: Rethinking the future of plastics

Today nearly everyone, everywhere, every day comes into contact with plastics. Plastics have become the ubiquitous workhorse material of the modern economy. And yet, while delivering many benefits, the current plastics economy has drawbacks that are becoming more apparent by the day.

Significant economic value is lost after each use, and given the projected growth in consumption, by 2050 oceans are expected to contain more plastics than fish (by weight), and the entire plastics industry will consume 20% of total oil production and 15% of the annual carbon budget. How can we turn the challenges of our current plastics economy into a global opportunity for innovation and value capture, resulting in stronger economies and better environmental outcomes?

Published
Tuesday 19 January 2016

http://www3.weforum.org/docs/WEF_The_New_Plastics_Economy.pdf

http://www.weforum.org/events/world-economic-forum-annual-meeting-2016/sessions/rethinking-plastics

2016-01-22 09:15

Issue Briefing: Rethinking Plastics

Learn first-hand how systemic change can create a New Plastics Economy, turning the $80-$120 billion worth of plastic packaging that is burnt, buried or dumped into the environment each year into an opportunity.

Speakers: Ellen MacArthur, Dominic Kailash Nath Waughray, Oliver Cann, Jean-Louis Chaussade

Topics: Global Economy

http://www.ellenmacarthurfoundation.org/news/new-plastics-economy-report-offers-blueprint-to-design-a-circular-future-for-plastics

NEW PLASTICS ECONOMY REPORT OFFERS BLUEPRINT TO DESIGN A CIRCULAR FUTURE FOR PLASTICS

JANUARY 19, 2016

Applying circular economy principles to global plastic packaging flows could transform the plastics economy and drastically reduce negative externalities such as leakage into oceans, according to the latest report by the World Economic Forum and Ellen MacArthur Foundation, with analytical support from McKinsey & Company.

The New Plastics Economy: Rethinking the future of plastics provides for the first time a vision of a global economy in which plastics never become waste, and outlines concrete steps towards achieving the systemic shift needed. The report, financially supported by the MAVA Foundation, was produced as part of Project MainStream, a global, multi-industry initiative that aims to accelerate business-driven innovations to help scale the circular economy.

http://www.ellenmacarthurfoundation.org/publications/the-new-plastics-economy-rethinking-the-future-of-plastics

http://www.ellenmacarthurfoundation.org/assets/downloads/publications/EllenMacArthurFoundation_TheNewPlasticsEconomy_19012016.pdf

http://www.ellenmacarthurfoundation.org/news/the-new-plastics-economy-rethinking-the-future-of-plastics-infographics

THE NEW PLASTICS ECONOMY: RETHINKING THE FUTURE OF PLASTICS – DOWNLOAD THE INFOGRAPHICS

JANUARY 19, 2016

View and download key infographics from The New Plastics Economy: Rethinking the future of plastics report by the World Economic Forum, the Ellen MacArthur Foundation, and McKinsey & Company. Simply click on an image to download it.

http://www.ellenmacarthurfoundation.org/assets/downloads/EllenMacArthurFoundation_NewPlasticsEconomy_1_02.jpg

http://www.ellenmacarthurfoundation.org/assets/downloads/EllenMacArthurFoundation_NewPlasticsEconomy_1_06.jpg

http://www.ellenmacarthurfoundation.org/assets/downloads/EllenMacArthurFoundation_NewPlasticsEconomy_1_08.jpg

http://www.ellenmacarthurfoundation.org/assets/downloads/EllenMacArthurFoundation_NewPlasticsEconomy_1_10.jpg

http://www.ellenmacarthurfoundation.org/assets/downloads/EllenMacArthurFoundation_NewPlasticsEconomy_1_14.jpg

http://www.ellenmacarthurfoundation.org/assets/downloads/EllenMacArthurFoundation_NewPlasticsEconomy_1_16.jpg

http://www.ellenmacarthurfoundation.org/assets/downloads/EllenMacArthurFoundation_NewPlasticsEconomy_1_36.jpg

http://marinedebris.noaa.gov/about-us/2016-2020-strategic-plan

2016-2020 Strategic Plan

Marine debris is a pervasive problem that threatens our oceans and coastal environments. Since the inception of the NOAA Marine Debris Program in 2006, we have strived to combat this issue by finding solutions through research, removal and prevention efforts. We have had many accomplishments during this time, including funding important and innovative research projects, removing a significant amount of coastal debris, and reaching thousands of students, teachers, and communities to bring the issue of marine debris to the forefront.

There is still a long way to go to solve this problem and we need to be strategic about our future priorities, so we have refined our vision and developed a strategic plan to lead us into the future and help us succeed in continuing to combat marine debris in the coming years. The NOAA Marine Debris Program will continue to take action to help protect our important natural resources.

Take a look at our 2016-2020 Strategic Plan to see some of our goals for the future.

http://marinedebris.noaa.gov/sites/default/files/Strategic%20Plan%202016.pdf

http://marinedebris.noaa.gov/our-work/fiscal-year-2015-accomplishments-report

Fiscal Year 2015 Accomplishments Report

It was a busy year for the NOAA Marine Debris Program. Throughout 2015, we continued our important work funding removal projects around the country as well as our efforts to remove debris connected to the tsunami in Japan and Hurricane Sandy. The Program also worked to prevent future debris by engaging in education and outreach focusing on behavior change, including funding the development of new curriculum, supporting outreach to teens and teacher workshops, and working with recreational fishermen. This year, we were particularly proud of our “Trash Talk” videos, a six-part educational series created with NOAA Ocean Today, which were designed to raise awareness on the issue of marine debris in a fun, visual, interesting way.

In 2015, we strove to continue to be at the forefront of the marine debris issue. We collaborated with various partners to develop regional marine debris plans and to create marine debris exhibits at visitor centers around the nation. We supported research to better understand the impacts and distribution of marine debris, including investigating the concentration of microplastics in the Gulf of Alaska and the Chesapeake Bay. In addition, we participated in the global marine debris discussion by participating in the G7 Summit and acting as Chair of the UN’s Environment Programme’s Global Partnership on Marine Litter. Looking to the future, we developed a new NOAA Marine Debris Program Strategic Plan, which outlines the Program’s goals and strategies for the coming years.

We’re proud of our efforts over the past year and are excited to present the NOAA Marine Debris Program’s 2015 Accomplishments Report, which highlights some of our major achievements over fiscal year 2015.

http://marinedebris.noaa.gov/sites/default/files/FY15%20Accomplishments%20Report.pdf

https://eia-international.org/time-to-turn-the-tide-of-plastic-waste-choking-our-oceans

Time to turn the tide of plastic waste choking our oceans

5th October, 2015

As a mandatory 5p charge for plastic bags comes into effect in England today, EIA releases a new report calling on governments, industry, retailers and consumers alike to help end the appalling damage plastic waste inflicts on marine environments.

Lost at Sea – The urgent need to tackle marine litter urges a focus on cutting single-use plastics, removing plastics from down-the-drain products and embracing circular economy principles to dramatically reduce and better recycle plastic products and packaging.

http://eia-global.org/images/uploads/EIA_Lost_at_Sea_-_FINAL.pdf

http://www.theguardian.com/environment/2016/jan/19/collecting-plastic-waste-near-coasts-is-most-effective-clean-up-method

Collecting plastic waste near coasts ‘is most effective clean-up method’

Analysis finds that placing plastic collectors near coasts would remove 31% of microplastics, versus 1% if they were all in the ‘Great Pacific Garbage patch’

Rebecca Smithers
Tuesday 19 January 2016 00.01 GMT

Dredging plastic waste from coastal locations rather than deep in the oceans is the the most efficient way to clean it up and avoid damaging global ecosystems, according to new analysis.

Floating plastic waste ranging from bags, bottles and caps, fibres and ‘microbeads’ wash out into the oceans from rivers and sewers, while larger plastics are broken down into smaller fragments that can last for hundreds to thousands of years. Fragments of all sizes are swallowed by marine life and enter the food chain, disrupting fragile ecosystems.

Researchers from Imperial College looked at the so-called Great Pacific garbage patch – an area of open ocean in the North Pacific – which has an unusually large area of microplastics. The patch is enclosed by ocean currents that concentrate the plastics into an area estimated to be larger than twice the size of the United Kingdom.

http://www.oceanconservancy.org/who-we-are/newsroom/2016/entangled-eaten.html

Entangled, Eaten, Contaminated: Ocean Conservancy and Commonwealth Scientific and Industrial Research Organization (CSIRO) Publish First Comprehensive Impact Assessment of Trash on Marine Wildlife

Study highlights critical need to ramp up local to global action to stem the tide of plastics into our ocean

Media Contact:

Julia Roberson
jroberson@oceanconservancy.org
202.351.0476

(Washington, D.C. – January 12, 2016) – A first-of-its-kind analysis of the impact of 20 ocean trash items on seabirds, marine mammals and sea turtles conducted using expert elicitation was published today in Marine Policy by Ocean Conservancy and Commonwealth Scientific and Industrial Research Organization (CSIRO). Until now, the impact of marine debris items, such as plastic bags and fishing gear, to populations of these animals has been far less clear.

An analysis based on a survey of 274 experts representing 19 fields of study assigned scores for entanglement, ingestions and contamination on a shortlist of items culled from 30 years of data from Ocean Conservancy’s International Coastal Cleanup. The study found that a wide variety of items pose threats to marine wildlife through entanglement, ingestion, or contamination, suggesting that a comprehensive approach to preventing plastics from entering the ocean is vitally needed. Among the items, abandoned and lost fishing gear like nets, fishing line and buoys were found to pose the greatest overall threat to marine wildlife, primarily because of entanglement. Plastic bags emerged as the second most harmful item as they are often confused for food by marine mammals. Smaller items like balloons were also found to be harmful.

http://blog.oceanconservancy.org/2016/01/12/entangled-eaten-contaminated/

Entangled, Eaten, Contaminated

Posted On January 12, 2016 by George Leonard

A comprehensive assessment of trash on marine wildlife

There is a vast sea of trash in our oceans. For the first time, we now have a comprehensive picture of the toll it is taking on seabirds, sea turtles and marine mammals.

A new study in Marine Policy by scientists at Ocean Conservancy and Commonwealth Scientific and Industrial Research Organisation (CSIRO) mapped impacts ranging from entanglement, ingestion and chemical contamination of the 20 most commonly found ocean debris like fishing gear, balloons, plastic bottles and bags and a range of other plastic garbage found regularly in the ocean. Our research was based on elicitation, a widely-used technique to rigorously quantify the professional judgement of a community of experts, representing 19 fields of study.

http://blog.oceanconservancy.org/2016/01/12/how-dangerous-is-ocean-plastic/

How Dangerous is Ocean Plastic? Insights From Global Experts on the Greatest Threat to Marine Wildlife

Posted On January 12, 2016 by Nick Mallos

By George H. Leonard, PhD and Nicholas J. Mallos MEM

Over the course of the 30-year history of the International Coastal Cleanup, volunteers have removed over 200 million items from beaches and waterways around the world.  The top-ten list of items removed includes items like plastics bottles, plastic bottle caps, aluminum cans, cigarette butts, derelict fishing gear and a range of disposable plastic goods and food packaging. The scientific literature is replete with anecdotal information of marine wildlife impacted by these marine debris items. Indeed, over 690 species (from the smallest of plankton to the largest of whales) have been documented to be negatively impacted by marine debris.

But until now, the consequence of different marine debris items to populations of these animals – and the mechanism by which they do so – has been far less clear. Experimentally testing the impact of plastic items to whole populations of marine wildlife is technically challenging (if not impossible) and for species that are of threatened or endangered status, legally prohibited as well as morally questionable. But we have just published a paper in Marine Policy along with our colleagues Drs. Chris Wilcox and Denise Hardesty at Commonwealth Scientific and Industrial Research Organisation (CSIRO) in Australia that uses elicitation techniques to overcome these challenges. Our analysis provides key insights into the relative threat of different debris items to a healthy ocean that should provide additional impetus to decision makers to tackle this growing problem.

http://www.theguardian.com/environment/2016/jan/07/human-impact-has-pushed-earth-into-the-anthropocene-scientists-say

Human impact has pushed Earth into the Anthropocene, scientists say

New study provides one of the strongest cases yet that the planet has entered a new geological epoch

Adam Vaughan
@adamvaughan_uk
Thursday 7 January 2016 19.00 GMT

There is now compelling evidence to show that humanity’s impact on the Earth’s atmosphere, oceans and wildlife has pushed the world into a new geological epoch, according to a group of scientists.

The question of whether humans’ combined environmental impact has tipped the planet into an “Anthropocene” – ending the current Holocene which began around 12,000 years ago – will be put to the geological body that formally approves such time divisions later this year.

The new study provides one of the strongest cases yet that from the amount of concrete mankind uses in building to the amount of plastic rubbish dumped in the oceans, Earth has entered a new geological epoch.

“We could be looking here at a stepchange from one world to another that justifies being called an epoch,” said Dr Colin Waters, principal geologist at the British Geological Survey and an author on the study published in Science on Thursday.

“What this paper does is to say the changes are as big as those that happened at the end of the last ice age . This is a big deal.”

http://www.portofamsterdam.com/Eng/Free-disposal-of-clean-plastic-waste-in-Rotterdam-and-Amsterdam-ports.html

Free disposal of clean plastic waste in Rotterdam and Amsterdam ports

Thursday, December 24, 2015

Sea-going vessels in the ports of Rotterdam Rijnmond and the North Sea Canal Area can dispose of plastic shipping waste free of charge on an unlimited basis starting 1 January 2016. This has been agreed between the port authorities of Rotterdam and Amsterdam and the waste collection companies. The waste must be segregated and clean at the time of disposal.

The new campaign is part of the Green Deal for the Ship Waste Chain that Minister Schultz van Haegen of Infrastructure and Environment signed with the industry on 10 September 2014. Signatories to the Green Deal include Port of Amsterdam, Zeeland Seaports, Groningen Seaports, Port of Den Helder, NVVS (ship suppliers), the Royal Association of Netherlands Ship Owners (KVNR), ship waste collection companies, ILT and The North Sea Foundation.

Nam Ngoc Phuong, Aurore Zalouk-Vergnoux, Laurence Poirier, Abderrahmane Kamari, Amélie Châtel, Catherine Mouneyrac, Fabienne Lagarde, Is there any consistency between the microplastics found in the field and those used in laboratory experiments?, Environmental Pollution, Volume 211, April 2016, Pages 111-123, ISSN 0269-7491, http://dx.doi.org/10.1016/j.envpol.2015.12.035.
(http://www.sciencedirect.com/science/article/pii/S0269749115302499)
Abstract: The ubiquitous presence and persistency of microplastics (MPs) in aquatic environments are of particular concern since they represent an increasing threat to marine organisms and ecosystems. Great differences of concentrations and/or quantities in field samples have been observed depending on geographical location around the world. The main types reported have been polyethylene, polypropylene, and polystyrene. The presence of MPs in marine wildlife has been shown in many studies focusing on ingestion and accumulation in different tissues, whereas studies of the biological effects of MPs in the field are scarce. If the nature and abundance/concentrations of MPs have not been systematically determined in field samples, this is due to the fact that the identification of MPs from environmental samples requires mastery and execution of several steps and techniques. For this reason and due to differences in sampling techniques and sample preparation, it remains difficult to compare the published studies.

Most laboratory experiments have been performed with MP concentrations of a higher order of magnitude than those found in the field. Consequently, the ingestion and associated effects observed in exposed organisms have corresponded to great contaminant stress, which does not mimic the natural environment. Medium contaminations are produced with only one type of polymer of a precise sizes and homogenous shape whereas the MPs present in the field are known to be a mix of many types, sizes and shapes of plastic. Moreover, MPs originating in marine environments can be colonized by organisms and constitute the sorption support for many organic compounds present in environment that are not easily reproducible in laboratory. Determination of the mechanical and chemical effects of MPs on organisms is still a challenging area of research. Among the potential chemical effects it is necessary to differentiate those related to polymer properties from those due to the sorption/desorption of organic compounds.
Keywords: Microplastics; Field samples; Laboratory exposures; Ingestion; Biological effects

http://www.globalgarbage.org.br/mailinglist/S0269749115302499.pdf

J.P.G.L. Frias, J. Gago, V. Otero, P. Sobral, Microplastics in coastal sediments from Southern Portuguese shelf waters, Marine Environmental Research, Volume 114, March 2016, Pages 24-30, ISSN 0141-1136, http://dx.doi.org/10.1016/j.marenvres.2015.12.006.
(http://www.sciencedirect.com/science/article/pii/S0141113615300866)
Abstract: Microplastics are well-documented pollutants in the marine environment that result from fragmentation of larger plastic items. Due to their long chemical chains, they can remain in the environment for long periods of time. It is estimated that the vast majority (80%) of marine litter derives from land sources and that 70% will sink and remain at the bottom of the ocean. Microplastics that result from fragmentation of larger pieces of plastic are common to be found in beaches and in the water surface. The most common microplastics are pellets, fragments and fibres.

This work provides original data of the presence of microplastics in coastal sediments from Southern Portuguese shelf waters, reporting on microplastic concentration and polymer types.

Microplastic particles were found in nearly 56% of sediment samples, accounting a total of 31 particles in 27 samples. The vast majority were microfibers (25), identified as rayon fibres, and fragments (6) identified as polypropylene, through infrared spectroscopy (μ-FTIR). The concentration and polymer type data is consistent with other relevant studies and reports worldwide.
Keywords: Marine litter; Microplastics; FTIR; MSFD; Algarve; Portugal

http://www.globalgarbage.org.br/mailinglist/S0141113615300866.pdf

Hindrik Bouwman, Steven W. Evans, Nik Cole, Nee Sun Choong Kwet Yive, Henrik Kylin, The flip-or-flop boutique: Marine debris on the shores of St Brandon’s rock, an isolated tropical atoll in the Indian Ocean, Marine Environmental Research, Volume 114, March 2016, Pages 58-64, ISSN 0141-1136, http://dx.doi.org/10.1016/j.marenvres.2015.12.013.
(http://www.sciencedirect.com/science/article/pii/S0141113615300921)
Abstract: Isolated coral atolls are not immune from marine debris accumulation. We identified Southeast Asia, the Indian sub-continent, and the countries on the Arabian Sea as most probable source areas of 50 000 items on the shores of St. Brandon’s Rock (SBR), Indian Ocean. 79% of the debris was plastics. Flip-flops, energy drink bottles, and compact fluorescent lights (CFLs) were notable item types. The density of debris (0.74 m−1 shore length) is comparable to similar islands but less than mainland sites. Intact CFLs suggests product-facilitated long-range transport of mercury. We suspect that aggregated marine debris, scavenged by the islands from currents and gyres, could re-concentrate pollutants. SBR islets accumulated debris types in different proportions suggesting that many factors act variably on different debris types. Regular cleaning of selected islets will take care of most of the accumulated debris and may improve the ecology and tourism potential. However, arrangements and logistics require more study.
Keywords: Plastic; Polyurethane foam; Mercury; Management; Wreck; Compact fluorescent light

http://www.globalgarbage.org.br/mailinglist/S0141113615300921.pdf

M. Moriarty, D. Pedreschi, D. Stokes, L. Dransfeld, D.G. Reid, Spatial and temporal analysis of litter in the Celtic Sea from Groundfish Survey data: Lessons for monitoring, Marine Pollution Bulletin, Available online 13 January 2016, ISSN 0025-326X,http://dx.doi.org/10.1016/j.marpolbul.2015.12.019.
(http://www.sciencedirect.com/science/article/pii/S0025326X15302241)
Abstract: The Marine Strategy Framework Directive requires EU Member States to sample and monitor marine litter. Criteria for sampling and detecting spatial and/or temporal variation in the amount of litter present have been developed and initiated throughout Europe. These include implementing standardised sampling and recording methods to enable cross-comparison and consistency between neighbours. Parameters of interest include; litter occurrence, composition, distribution and source. This paper highlights the litter-related initiatives occurring in Irish waters; presents an offshore benthic litter sampling series; provides a power analysis to determine trend detection thresholds; identifies areas and sources of litter; and proposes improvements to meet reporting obligations. Litter was found to be distributed throughout Irish waters with highest occurrences in the Celtic Sea. Over 50% of litter encountered was attributed to fishing activities: however only a small proportion of the variability in litter occurrence could be explained by spatial patterns in fishing effort. Issues in implementing standardised protocol were observed and addressed.
Keywords: Litter; Fishing; Celtic Sea; MSFD; Geostatistical analysis; Power analysis

http://www.globalgarbage.org.br/mailinglist/S0025326X15302241_In_Press_Corrected_Proof.pdf

Note to users:
Corrected proofs are Articles in Press that contain the authors’ corrections. Final citation details, e.g., volume and/or issue number, publication year and page numbers, still need to be added and the text might change before final publication.

Although corrected proofs do not have all bibliographic details available yet, they can already be cited using the year of online publication and the DOI , as follows: author(s), article title, Publication (year), DOI. Please consult the journal’s reference style for the exact appearance of these elements, abbreviation of journal names and use of punctuation.

When the final article is assigned to volumes/issues of the Publication, the Article in Press version will be removed and the final version will appear in the associated published volumes/issues of the Publication. The date the article was first made available online will be carried over.

Alice Nauendorf, Stefan Krause, Nikolaus K. Bigalke, Elena V. Gorb, Stanislav N. Gorb, Matthias Haeckel, Martin Wahl, Tina Treude, Microbial colonization and degradation of polyethylene and biodegradable plastic bags in temperate fine-grained organic-rich marine sediments, Marine Pollution Bulletin, Available online 12 January 2016, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.12.024.
(http://www.sciencedirect.com/science/article/pii/S0025326X15302277)
Abstract: To date, the longevity of plastic litter at the sea floor is poorly constrained. The present study compares colonization and biodegradation of plastic bags by aerobic and anaerobic benthic microbes in temperate fine-grained organic-rich marine sediments. Samples of polyethylene and biodegradable plastic carrier bags were incubated in natural oxic and anoxic sediments from Eckernförde Bay (Western Baltic Sea) for 98 days. Analyses included (1) microbial colonization rates on the bags, (2) examination of the surface structure, wettability, and chemistry, and (3) mass loss of the samples during incubation. On average, biodegradable plastic bags were colonized five times higher by aerobic and eight times higher by anaerobic microbes than polyethylene bags. Both types of bags showed no sign of biodegradation during this study. Therefore, marine sediment in temperate coastal zones may represent a long-term sink for plastic litter and also supposedly compostable material.
Keywords: Biodegradation; Biofilm; Microorganisms; Carrier bag; Compostable; Eckernförde Bay

http://www.globalgarbage.org.br/mailinglist/S0025326X15302277_In_Press_Corrected_Proof.pdf

S. Liubartseva, G. Coppini, R. Lecci, S. Creti, Regional approach to modeling the transport of floating plastic debris in the Adriatic Sea, Marine Pollution Bulletin, Available online 8 January 2016, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.12.031.
(http://www.sciencedirect.com/science/article/pii/S0025326X15302356)
Abstract: Sea surface concentrations of plastics and their fluxes onto coastlines are simulated over 2009–2015. Calculations incorporate combinations of terrestrial and maritime litter inputs, the Lagrangian model MEDSLIK-II forced by AFS ocean current simulations, and ECMWF wind analyses. With a relatively short particle half-life of 43.7 days, the Adriatic Sea is defined as a highly dissipative basin where the shoreline is, by construction, the main sink of floating debris. Our model results show that the coastline of the Po Delta receives a plastic flux of approximately 70 kg(km day)-1. The most polluted sea surface area (> 10 g km-2 floating debris) is represented by an elongated band shifted to the Italian coastline and narrowed from northwest to southeast. Evident seasonality is found in the calculated plastic concentration fields and the coastline fluxes. Complex source–receptor relationships among the basin’s subregions are quantified in impact matrices.
Keywords: Plastic debris inputs; Lagrangian model; Markov chain; Plastic fluxes onto coastline; Impact matrices

http://www.globalgarbage.org.br/mailinglist/S0025326X15302356_In_Press_Corrected_Proof.pdf

Steve A. Carr, Jin Liu, Arnold G. Tesoro, Transport and Fate of Microplastic Particles in Wastewater Treatment Plants, Water Research, Available online 7 January 2016, ISSN 0043-1354, http://dx.doi.org/10.1016/j.watres.2016.01.002.
(http://www.sciencedirect.com/science/article/pii/S0043135416300021)
Abstract: Municipal wastewater treatment plants (WWTPs) are frequently suspected as significant point sources or conduits of microplastics to the environment. To directly investigate these suspicions, effluent discharges from seven tertiary plants and one secondary plant in Southern California were studied. The study also looked at influent loads, particle size/type, conveyance, and removal at these wastewater treatment facilities. Over 0.189 million liters of effluent at each of the seven tertiary plants were filtered using an assembled stack of sieves with mesh sizes between 400 and 45 μm. Additionally, the surface of 28.4 million liters of final effluent at three tertiary plants was skimmed using a 125 μm filtering assembly. The results suggest that tertiary effluent is not a significant source of microplastics and that these plastic pollutants are effectively removed during the skimming and settling treatment processes. However, at a downstream secondary plant, an average of one micro-particle in every 1.14 thousand liters of final effluent was counted. The majority of microplastics identified in this study had a profile (color, shape, and size) similar to the blue polyethylene particles present in toothpaste formulations. Existing treatment processes were determined to be very effective for removal of microplastic contaminants entering typical municipal WWTPs.
Keywords: Microplastic pollutants; wastewater treatment; large-volume sampling; effluent discharge; cosmetic polyethylene; surface filtering

Note to users:
Accepted manuscripts are Articles in Press that have been peer reviewed and accepted for publication by the Editorial Board of this publication. They have not yet been copy edited and/or formatted in the publication house style, and may not yet have the full ScienceDirect functionality, e.g., supplementary files may still need to be added, links to references may not resolve yet etc. The text could still change before final publication.

Although accepted manuscripts do not have all bibliographic details available yet, they can already be cited using the year of online publication and the DOI, as follows: author(s), article title, Publication (year), DOI. Please consult the journal’s reference style for the exact appearance of these elements, abbreviation of journal names and use of punctuation.

When the final article is assigned to volumes/issues of the Publication, the Article in Press version will be removed and the final version will appear in the associated published volumes/issues of the Publication. The date the article was first made available online will be carried over.

http://www.globalgarbage.org.br/mailinglist/S0043135416300021_In_Press_Accepted_Manuscript.pdf

Lídia Nicolau, Ana Marçalo, Marisa Ferreira, Sara Sá, José Vingada, Catarina Eira, Ingestion of marine litter by loggerhead sea turtles, Caretta caretta, in Portuguese continental waters, Marine Pollution Bulletin, Available online 4 January 2016, ISSN 0025-326X,http://dx.doi.org/10.1016/j.marpolbul.2015.12.021.
(http://www.sciencedirect.com/science/article/pii/S0025326X15302228)
Abstract: The accumulation of litter in marine and coastal environments is a major threat to marine life. Data on marine litter in the gastrointestinal tract of stranded loggerhead turtles, Caretta caretta, found along the Portuguese continental coast was presented. Out of the 95 analysed loggerheads, litter was present in 56 individuals (59.0%) and most had less than 10 litter items (76.8%) and less than 5 g (dm) (96.8%). Plastic was the main litter category (frequency of occurrence = 56.8%), while sheet (45.3%) was the most relevant plastic sub-category. There was no influence of loggerhead stranding season, cause of stranding or size on the amount of litter ingested (mean number and dry mass of litter items per turtle). The high ingested litter occurrence frequency in this study supports the use of the loggerhead turtle as a suitable tool to monitor marine litter trends, as required by the European Marine Strategy Framework Directive.
Keywords: Marine turtles; Plastic; Gut content analysis; Pollution; Marine Strategy Framework Directive

http://www.globalgarbage.org.br/mailinglist/S0025326X15302228_In_Press_Corrected_Proof.pdf

Daniele de A. Miranda, Gustavo Freire de Carvalho-Souza, Are we eating plastic-ingesting fish?, Marine Pollution Bulletin, Available online 4 January 2016, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.12.035.
(http://www.sciencedirect.com/science/article/pii/S0025326X15302393)
Abstract: Yes, we are eating plastic-ingesting fish. A baseline assessment of plastic pellet ingestion by two species of important edible fish caught along the eastern coast of Brazil is described. The rate of plastic ingestion by king mackerel (Scomberomorus cavalla) was quite high (62.5%), followed by the Brazilian sharpnose shark (Rhizoprionodon lalandii, 33%). From 2 to 6 plastic resin pellets were encountered in the stomachs of each fish, with sizes of from 1 to 5 mm, and with colors ranging from clear to white and yellowish. Ecological and health-related implications are discussed and the potential for transferring these materials through the food-chain are addressed. Further research will be needed of other species harvested for human consumption.
Keywords: Marine debris; Pellets; Predator fishes; Artisanal fisheries

http://www.globalgarbage.org.br/mailinglist/S0025326X15302393_In_Press_Corrected_Proof.pdf

Dennis Brennecke, Bernardo Duarte, Filipa Paiva, Isabel Caçador, João Canning-Clode, Microplastics as vector for heavy metal contamination from the marine environment, Estuarine, Coastal and Shelf Science, Available online 4 January 2016, ISSN 0272-7714,http://dx.doi.org/10.1016/j.ecss.2015.12.003.
(http://www.sciencedirect.com/science/article/pii/S027277141530158X)
Abstract: The permanent presence of microplastics in the marine environment is considered a global threat to several marine animals. Heavy metals and microplastics are typically included in two different classes of pollutants but the interaction between these two stressors is poorly understood.

During 14 days of experimental manipulation, we examined the adsorption of two heavy metals, copper (Cu) and zinc (Zn), leached from an antifouling paint to virgin polystyrene (PS) beads and aged polyvinyl chloride (PVC) fragments in seawater. We demonstrated that heavy metals were released from the antifouling paint to the water and both microplastic types adsorbed the two heavy metals. This adsorption kinetics was described using partition coefficients and mathematical models. Partition coefficients between pellets and water ranged between 650 and 850 for Cu on PS and PVC, respectively. The adsorption of Cu was significantly greater in PVC fragments than in PS, probably due to higher surface area and polarity of PVC. Concentrations of Cu and Zn increased significantly on PVC and PS over the course of the experiment with the exception of Zn on PS. As a result, we show a significant interaction between these types of microplastics and heavy metals, which can have implications for marine life and the environment. These results strongly support recent findings where plastics can play a key role as vectors for heavy metal ions in the marine system. Finally, our findings highlight the importance of monitoring marine litter and heavy metals, mainly associated with antifouling paints, particularly in the framework of the Marine Strategy Framework Directive (MSFD).
Keywords: Heavy metals; Microplastics; Adsorption; Antifouling substances; Polystyrene; Polyvinyl chloride

http://www.globalgarbage.org.br/mailinglist/S027277141530158X_In_Press_Corrected_Proof.pdf

Bum Gun Kwon, Koshiro Koizumi, Seon-Yong Chung, Yoichi Kodera, Jong-Oh Kim, Katsuhiko Saido, Global styrene oligomers monitoring as new chemical contamination from polystyrene plastic marine pollution, Journal of Hazardous Materials, Volume 300, 30 December 2015, Pages 359-367, ISSN 0304-3894, http://dx.doi.org/10.1016/j.jhazmat.2015.07.039.
(http://www.sciencedirect.com/science/article/pii/S0304389415005762)
Abstract: Polystyrene (PS) plastic marine pollution is an environmental concern. However, a reliable and objective assessment of the scope of this problem, which can lead to persistent organic contaminants, has yet to be performed. Here, we show that anthropogenic styrene oligomers (SOs), a possible indicator of PS pollution in the ocean, are found globally at concentrations that are higher than those expected based on the stability of PS. SOs appear to persist to varying degrees in the seawater and sand samples collected from beaches around the world. The most persistent forms are styrene monomer, styrene dimer, and styrene trimer. Sand samples from beaches, which are commonly recreation sites, are particularly polluted with these high SOs concentrations. This finding is of interest from both scientific and public perspectives because SOs may pose potential long-term risks to the environment in combination with other endocrine disrupting chemicals. From SOs monitoring results, this study proposes a flow diagram for SOs leaching from PS cycle. Using this flow diagram, we conclude that SOs are global contaminants in sandy beaches around the world due to their broad spatial distribution.
Keywords: Styrene oligomers; Polystyrene; Plastic pollution; Leaching; Persistent

http://www.globalgarbage.org.br/mailinglist/S0304389415005762.pdf

Thomas C. Erren, J. Valérie Groß, Frank Steffany, V. Benno Meyer-Rochow, “Plastic ocean”: What about cancer?, Environmental Pollution, Volume 207, December 2015, Pages 436-437, ISSN 0269-7491, http://dx.doi.org/10.1016/j.envpol.2015.05.025.
(http://www.sciencedirect.com/science/article/pii/S0269749115002596)
Keywords: Plastic; Synthetic polymer; Styrene; Vinyl chloride; Bisphenol A; IARC; Toxicology; Cancer; Public health; Fetal exposure; Neonatal exposure

http://www.globalgarbage.org.br/mailinglist/S0269749115002596.pdf

, Grace silica gels provide an alternative to microplastic exfoliating agents for personal care industry, Focus on Surfactants, Volume 2015, Issue 12, December 2015, Page 4, ISSN 1351-4210, http://dx.doi.org/10.1016/j.fos.2015.11.016.
(http://www.sciencedirect.com/science/article/pii/S1351421015003376)

http://www.globalgarbage.org.br/mailinglist/S1351421015003376.pdf

http://grace.com/en-us/Pages/Products.aspx#syntheticsilicas

https://grace.com/personal-care/en-US/exfoliants

https://grace.com/personal-care/en-US/Documents/Grace%20Exfoliating%20Silicas_TI_5_2015.pdf

Cristina Munari, Corinne Corbau, Umberto Simeoni, Michele Mistri, Marine litter on Mediterranean shores: Analysis of composition, spatial distribution and sources in north-western Adriatic beaches, Waste Management, Available online 22 December 2015, ISSN 0956-053X,http://dx.doi.org/10.1016/j.wasman.2015.12.010.
(http://www.sciencedirect.com/science/article/pii/S0956053X15302440)
Abstract: Marine litter is one descriptor in the EU Marine Strategy Framework Directive (MSFD). This study provides the first account of an MSFD indicator (Trends in the amount of litter deposited on coastlines) for the north-western Adriatic. Five beaches were sampled in 2015. Plastic dominated in terms of abundance, followed by paper and other groups. The average density was 0.2 litter items m−2, but at one beach it raised to 0.57 items m−2. The major categories were cigarette butts, unrecognizable plastic pieces, bottle caps, and others. The majority of marine litter came from land-based sources: shoreline and recreational activities, smoke-related activities and dumping. Sea-based sources contributed for less. The abundance and distribution of litter seemed to be particularly influenced by beach users, reflecting inadequate disposal practices. The solution to these problems involves implementation and enforcement of local educational and management policies.
Keywords: Marine litter; Marine Strategy Framework Directive; In situ deposition; Adriatic Sea

http://www.globalgarbage.org.br/mailinglist/S0956053X15302440_In_Press_Corrected_Proof.pdf

http://onlinelibrary.wiley.com/doi/10.1890/150017/full

http://onlinelibrary.wiley.com/wol1/doi/10.1890/150017/abstract

Amaral-Zettler, L. A., Zettler, E. R., Slikas, B., Boyd, G. D., Melvin, D. W., Morrall, C. E., Proskurowski, G. and Mincer, T. J. (2015), The biogeography of the Plastisphere: implications for policy. Frontiers in Ecology and the E, 13: 541–546. doi: 10.1890/150017

Abstract
Microplastics (particles less than 5 mm) numerically dominate marine debris and occur from coastal waters to mid-ocean gyres, where surface circulation concentrates them. Given the prevalence of plastic marine debris (PMD) and the rise in plastic production, the impacts of plastic on marine ecosystems will likely increase. Microscopic life (the “Plastisphere”) thrives on these tiny floating “islands” of debris and can be transported long distances. Using next-generation DNA sequencing, we characterized bacterial communities from water and plastic samples from the North Pacific and North Atlantic subtropical gyres to determine whether the composition of different Plastisphere communities reflects their biogeographic origins. We found that these communities differed between ocean basins – and to a lesser extent between polymer types – and displayed latitudinal gradients in species richness. Our research reveals some of the impacts of microplastics on marine biodiversity, demonstrates that the effects and fate of PMD may vary considerably in different parts of the global ocean, and suggests that PMD mitigation will require regional management efforts.

http://www.globalgarbage.org.br/mailinglist/150017.pdf

http://www.globalgarbage.org.br/mailinglist/150017_Supplemental_information.pdf

http://pubs.acs.org/doi/abs/10.1021/acs.est.5b04663

Dorte Herzke, Tycho Anker-Nilssen, Therese Haugdahl Nøst, Arntraut Götsch, Signe Christensen-Dalsgaard, Magdalene Langset, Kirstin Fangel, and Albert A. Koelmans
Negligible Impact of Ingested Microplastics on Tissue Concentrations of Persistent Organic Pollutants in Northern Fulmars off Coastal Norway
Environ. Sci. Technol., Article ASAP
DOI: 10.1021/acs.est.5b04663
Publication Date (Web): December 22, 2015

Abstract
The northern fulmar (Fulmarus glacialis) is defined as an indicator species of plastic pollution by the Oslo-Paris Convention for the North-East Atlantic, but few data exist for fulmars from Norway. Moreover, the relationship between uptake of plastic and pollutants in seabirds is poorly understood. We analyzed samples of fulmars from Norwegian waters and compared the POP concentrations in their liver and muscle tissue with the corresponding concentrations in the loads of ingested plastic in their stomachs, grouped as “no”, “medium” (0.01–0.21 g; 1–14 pieces of plastic), or “high” (0.11–0.59 g; 15–106 pieces of plastic). POP concentrations in the plastic did not differ significantly between the high and medium plastic ingestion group for sumPCBs, sumDDTs, and sumPBDEs. By combining correlations among POP concentrations, differences in tissue concentrations of POPs between plastic ingestion subgroups, fugacity calculations, and bioaccumulation modeling, we showed that plastic is more likely to act as a passive sampler than as a vector of POPs, thus reflecting the POP profiles of simultaneously ingested prey.

http://pubs.acs.org/doi/pdfplus/10.1021/acs.est.5b04663

http://pubs.acs.org/doi/pdf/10.1021/acs.est.5b04663

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b04663

Supporting Information
Negligible Impact of Ingested Microplastics on Tissue Concentrations of Persistent Organic Pollutants in Northern Fulmars off Coastal Norway

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.est.5b04663.

Text, figures, and tables addressing (i) the model parameters, least-squares used in the modeling approach, (ii) illustrating the further validation of the model, (iii) giving loss rate constants (kloss) estimated for PCBs, based on bioaccumulation data without plastic ingested, and (iv) presenting the Muscle–Plastic Fugacity ratios for selected individual birds. (PDF)

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b04663/suppl_file/es5b04663_si_001.pdf

http://pubs.acs.org/doi/abs/10.1021/acs.est.5b02781

Heng-Xiang Li, Gordon J. Getzinger, P. Lee Ferguson, Beatriz Orihuela, Mei Zhu, and Daniel Rittschof
Effects of Toxic Leachate from Commercial Plastics on Larval Survival and Settlement of the Barnacle Amphibalanus amphitrite
Environ. Sci. Technol., Article ASAP
DOI: 10.1021/acs.est.5b02781
Publication Date (Web): December 14, 2015

Abstract
Plastic pollution represents a major and growing global problem. It is well-known that plastics are a source of chemical contaminants to the aquatic environment and provide novel habitats for marine organisms. The present study quantified the impacts of plastic leachates from the seven categories of recyclable plastics on larval survival and settlement of barnacle Amphibalanus (=Balanus) amphitrite. Leachates from plastics significantly increased barnacle nauplii mortality at the highest tested concentrations (0.10 and 0.50 m2/L). Hydrophobicity (measured as surface energy) was positively correlated with mortality indicating that plastic surface chemistry may be an important factor in the effects of plastics on sessile organisms. Plastic leachates significantly inhibited barnacle cyprids settlement on glass at all tested concentrations. Settlement on plastic surfaces was significantly inhibited after 24 and 48 h, but settlement was not significantly inhibited compared to the controls for some plastics after 72–96 h. In 24 h exposure to seawater, we found larval toxicity and inhibition of settlement with all seven categories of recyclable commercial plastics. Chemical analysis revealed a complex mixture of substances released in plastic leachates. Leaching of toxic compounds from all plastics should be considered when assessing the risks of plastic pollution.

http://www.globalgarbage.org.br/mailinglist/5b02781_Article_ASAP.pdf

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b02781

Supporting Information
Effects of Toxic Leachate from Commercial Plastics on Larval Survival and Settlement of the Barnacle Amphibalanus amphitrite

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.est.5b02781.

Information on the sources of new plastic products (Table S1). The water quality measured before and after leaching (Table S2). Gradient elution conditions for HPLC-HR/AM MS (Table S3). The nauplii mortality and cyprid settlement in different leachates from glass coverslip, polystyrene Petri dish, and wax (Figure S1) (PDF)

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b02781/suppl_file/es5b02781_si_001.pdf

http://pubs.acs.org/doi/abs/10.1021/acs.est.5b02431

Lars Gutow, Antonia Eckerlebe, Luis Giménez, and Reinhard Saborowski
Experimental Evaluation of Seaweeds as a Vector for Microplastics into Marine Food Webs
Environ. Sci. Technol., Article ASAP
DOI: 10.1021/acs.est.5b02431
Publication Date (Web): December 11, 2015

Abstract
The ingestion of microplastics has been shown for a great variety of marine organisms. However, benthic marine mesoherbivores such as the common periwinkle Littorina littorea have been largely disregarded in studies about the effects of microplastics on the marine biota, probably because the pathway for microplastics to this functional group of organisms was not obvious. In laboratory experiments we showed that the seaweed Fucus vesiculosus retains suspended microplastics on its surface. The numbers of microplastics that adhered to the algae correlated with the concentrations of suspended particles in the water. In choice feeding assays L. littorea did not distinguish between algae with adherent microplastics and clean algae without microplastics, indicating that the snails do not recognize solid nonfood particles in the submillimeter size range as deleterious. In periwinkles that were feeding on contaminated algae, microplastics were found in the stomach and in the gut. However, no microplastics were found in the midgut gland, which is the principle digestive organ of gastropods. Microplastics in the fecal pellets of the periwinkles indicate that the particles do not accumulate rapidly inside the animals but are mostly released with the feces. Our results provide the first evidence that seaweeds may represent an efficient pathway for microplastics from the water to marine benthic herbivores.

http://www.globalgarbage.org.br/mailinglist/5b02431_Article_ASAP.pdf

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b02431

Supporting Information
Experimental Evaluation of Seaweeds as a Vector for Microplastics into Marine Food Webs

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.est.5b02431.

Figures showing the distribution of standardized errors across microplastic concentration levels and different types of microplastics and contamination and decontamination treatments. (PDF)

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b02431/suppl_file/es5b02431_si_001.pdf

http://pubs.acs.org/doi/abs/10.1021/acs.est.5b04026

Andrew J. R. Watts, Mauricio A. Urbina, Shauna Corr, Ceri Lewis, and Tamara S. Galloway
Ingestion of Plastic Microfibers by the Crab Carcinus maenas and Its Effect on Food Consumption and Energy Balance
Environ. Sci. Technol., 2015, 49 (24), pp 14597–14604
DOI: 10.1021/acs.est.5b04026

Abstract
Microscopic plastic fragments (<5 mm) are a worldwide conservation issue, polluting both coastal and marine environments. Fibers are the most prominent plastic type reported in the guts of marine organisms, but their effects once ingested are unknown. This study investigated the fate of polypropylene rope microfibers (1–5 mm in length) ingested by the crab Carcinus maenas and the consequences for the crab’s energy budget. In chronic 4 week feeding studies, crabs that ingested food containing microfibers (0.3–1.0% plastic by weight) showed reduced food consumption (from 0.33 to 0.03 g d–1) and a significant reduction in energy available for growth (scope for growth) from 0.59 to −0.31 kJ crab d–1 in crabs fed with 1% plastic. The polypropylene microfibers were physically altered by their passage through the foregut and were excreted with a smaller overall size and length and amalgamated into distinctive balls. These results support of the emerging paradigm that a key biological impact of microplastic ingestion is a reduction in energy budgets for the affected marine biota. We also provide novel evidence of the biotransformations that can affect the plastics themselves following ingestion and excretion.

http://www.globalgarbage.org.br/mailinglist/5b04026.pdf

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b04026

Supporting Information
Ingestion of Plastic Microfibers by the Crab Carcinus maenas and Its Effect on Food Consumption and Energy Balance

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.est.5b04026.

Figures SI.1 and SI.2 and Tables SI.1 and SI.2 (PDF)

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b04026/suppl_file/es5b04026_si_001.pdf

http://pubs.acs.org/doi/abs/10.1021/acs.est.5b04099

Matthew Cole and Tamara S. Galloway
Ingestion of Nanoplastics and Microplastics by Pacific Oyster Larvae
Environ. Sci. Technol., 2015, 49 (24), pp 14625–14632
DOI: 10.1021/acs.est.5b04099

Abstract
Plastic debris is a prolific contaminant effecting freshwater and marine ecosystems across the globe. Of growing environmental concern are “microplastics”and “nanoplastics” encompassing tiny particles of plastic derived from manufacturing and macroplastic fragmentation. Pelagic zooplankton are susceptible to consuming microplastics, however the threat posed to larvae of commercially important bivalves is currently unknown. We exposed Pacific oyster (Crassostrea gigas) larvae (3–24 d.p.f.) to polystyrene particles spanning 70 nm-20 μm in size, including plastics with differing surface properties, and tested the impact of microplastics on larval feeding and growth. The frequency and magnitude of plastic ingestion over 24 h varied by larval age and size of polystyrene particle (ANOVA, P < 0.01), and surface properties of the plastic, with aminated particles ingested and retained more frequently (ANOVA, P < 0.01). A strong, significant correlation between propensity for plastic consumption and plastic load per organism was identified (Spearmans, r = 0.95, P < 0.01). Exposure to 1 and 10 μm PS for up to 8 days had no significant effect on C. gigas feeding or growth at <100 microplastics mL–1. In conclusion, whil micro- and nanoplastics were readily ingested by oyster larvae, exposure to plastic concentrations exceeding those observed in the marine environment resulted in no measurable effects on the development or feeding capacity of the larvae over the duration of the study.

http://pubs.acs.org/doi/pdfplus/10.1021/acs.est.5b04099

http://pubs.acs.org/doi/pdf/10.1021/acs.est.5b04099

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b04099

Supporting Information
Ingestion of Nanoplastics and Microplastics by Pacific Oyster Larvae

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.est.5b04099.

Additional information as noted in the text (PDF)

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b04099/suppl_file/es5b04099_si_001.pdf

http://pubs.acs.org/doi/abs/10.1021/acs.est.5b03163

Dongqi Yang, Huahong Shi, Lan Li, Jiana Li, Khalida Jabeen, and Prabhu Kolandhasamy
Microplastic Pollution in Table Salts from China
Environ. Sci. Technol., 2015, 49 (22), pp 13622–13627
DOI: 10.1021/acs.est.5b03163

Abstract
Microplastics have been found in seas all over the world. We hypothesize that sea salts might contain microplastics, because they are directly supplied by seawater. To test our hypothesis, we collected 15 brands of sea salts, lake salts, and rock/well salts from supermarkets throughout China. The microplastics content was 550–681 particles/kg in sea salts, 43–364 particles/kg in lake salts, and 7–204 particles/kg in rock/well salts. In sea salts, fragments and fibers were the prevalent types of particles compared with pellets and sheets. Microplastics measuring less than 200 μm represented the majority of the particles, accounting for 55% of the total microplastics, and the most common microplastics were polyethylene terephthalate, followed by polyethylene and cellophane in sea salts. The abundance of microplastics in sea salts was significantly higher than that in lake salts and rock/well salts. This result indicates that sea products, such as sea salts, are contaminated by microplastics. To the best of our knowledge, this is the first report on microplastic pollution in abiotic sea products.

http://www.globalgarbage.org.br/mailinglist/5b03163.pdf

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b03163

Supporting Information
Microplastic Pollution in Table Salts from China

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.est.5b03163.

Figure S1, sources of table salts tested in this study; Figure S2, spectra of the 15 packages of table salts; Table S1, eight nonplastic particles identified with micro-FT-IR (PDF)

http://pubs.acs.org/doi/suppl/10.1021/acs.est.5b03163/suppl_file/es5b03163_si_001.pdf

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Sara Sá, Jorge Bastos-Santos, Hélder Araújo, Marisa Ferreira, Virginia Duro, Flávia Alves, Bruno Panta-Ferreira, Lídia Nicolau, Catarina Eira, José Vingada, Spatial distribution of floating marine debris in offshore continental Portuguese waters, Marine Pollution Bulletin, Available online 15 January 2016, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2016.01.011.
(http://www.sciencedirect.com/science/article/pii/S0025326X1630011X)
Abstract: This study presents data on abundance and density of macro-floating marine debris (FMD), including their composition, spatial distribution and potential sources off continental Portugal. FMD were assessed by shipboard visual surveys covering ± 252,833 km2 until the 220 nm limit. The FMD average density was 2.98 items/km2 and abundance amounted to 752,740 items. Unidentified plastics constitute the major bulk of FMD (density = 0.46 items/km2; abundance = 117,390 items), followed by styrofoam, derelict or lost materials from fisheries, paper/cardboard and wood material. The North sector of the area presents higher FMD diversity and abundances, probably as a result of the high number of navigation corridors and fisheries operating in that sector. Most FMD originate from local sources, namely discharges from vessels and derelict material from fisheries. Considering the identifiable items, cables and fishing lines were the only fishing related items among the top ten FMD items in Portuguese offshore waters.
Keywords: Floating marine debris; Density estimate; Distance sampling; Plastics; Portugal

http://www.globalgarbage.org.br/mailinglist/S0025326X1630011X_In_Press_Corrected_Proof.pdf

Note to users:
Corrected proofs are Articles in Press that contain the authors’ corrections. Final citation details, e.g., volume and/or issue number, publication year and page numbers, still need to be added and the text might change before final publication.

Although corrected proofs do not have all bibliographic details available yet, they can already be cited using the year of online publication and the DOI , as follows: author(s), article title, Publication (year), DOI. Please consult the journal’s reference style for the exact appearance of these elements, abbreviation of journal names and use of punctuation.

When the final article is assigned to volumes/issues of the Publication, the Article in Press version will be removed and the final version will appear in the associated published volumes/issues of the Publication. The date the article was first made available online will be carried over.

Cánovas-Molina Almudena, Monica Montefalcone, Giorgio Bavestrello, Angelo Cau, Carlo Nike Bianchi, Carla Morri, Simonepietro Canese, Marzia Bo, A new ecological index for the status of mesophotic megabenthic assemblages in the mediterranean based on ROV photography and video footage, Continental Shelf Research, Available online 15 January 2016, ISSN 0278-4343, http://dx.doi.org/10.1016/j.csr.2016.01.008.
(http://www.sciencedirect.com/science/article/pii/S0278434316300085)
Abstract: A new index of ecological status, named Mesophotic Assemblages Ecological Status (MAES) index, was elaborated on the basis of ROV (Remotely Operated Vehicle) photography and video footage in order to assess the status of mesophotic megabenthic assemblages from hard bottom. The index was tested on seven sites located between 50 and 150 m depth in the Ligurian and Tyrrhenian seas (western Mediterranean Sea). The MAES index considers three main parameters: i) the community structure (number of megabenthic taxa, percent biotic cover in the basal layer, density of erect species); ii) the condition of the dominant erect species (average height, percent of colonies with epibiosis/necrosis); iii) the visible human impact (density of marine litter, including lost fishing gears). Two versions of the index have been elaborated, the complete version (MAES) and the quick version (q-MAES), which showed comparable results, therefore suggesting the possibility of fastening assessment times. The sensitivity of the MAES index was correlated with the putative human pressure acting upon the site (semi-quantitatively assessed considering fishing effort and coastal urbanisation). A standard working protocol related to the evaluation of the MAES index is here proposed with the intent to create an effective monitoring tool for the assessment of the ecological status of mesophotic assemblages on a large scale, as required by the EU Marine Strategy Framework Directive. MAES index will enhance the comprehension of the dynamics of mesophotic Mediterranean megabenthic assemblages with respect to human pressures and will also provide marine scientists and managers with a valuable tool specifically designed for the conservation of such vulnerable marine ecosystems.
Keywords: Mesophotic assemblages; Ecological status; Mediterranean Sea; MAES index; ROV

http://www.globalgarbage.org.br/mailinglist/S0278434316300085_In_Press_Accepted_Manuscript.pdf

Note to users:
Accepted manuscripts are Articles in Press that have been peer reviewed and accepted for publication by the Editorial Board of this publication. They have not yet been copy edited and/or formatted in the publication house style, and may not yet have the full ScienceDirect functionality, e.g., supplementary files may still need to be added, links to references may not resolve yet etc. The text could still change before final publication.

Although accepted manuscripts do not have all bibliographic details available yet, they can already be cited using the year of online publication and the DOI, as follows: author(s), article title, Publication (year), DOI. Please consult the journal’s reference style for the exact appearance of these elements, abbreviation of journal names and use of punctuation.

When the final article is assigned to volumes/issues of the Publication, the Article in Press version will be removed and the final version will appear in the associated published volumes/issues of the Publication. The date the article was first made available online will be carried over.

Tomoya Kataoka, Hirofumi Hinata, Shigeru Kato, Backwash process of marine macroplastics from a beach by nearshore currents around a submerged breakwater, Marine Pollution Bulletin, Volume 101, Issue 2, 30 December 2015, Pages 539-548, ISSN 0025-326X,http://dx.doi.org/10.1016/j.marpolbul.2015.10.060.
(http://www.sciencedirect.com/science/article/pii/S0025326X15301387)
Abstract: A key factor for determining the residence time of macroplastics on a beach is the process by which the plastics are backwashed offshore (backwash process). Here, we deduced the backwash process of plastic fishing floats on Wadahama Beach based on the analysis of two-year mark-recapture experiments as well as nearshore current structures revealed by sequential images taken by za webcam installed at the edge of a cliff behind the beach. The analysis results revealed the occurrence of a combination of offshore currents and convergence of alongshore currents in the surf zone in storm events around a submerged breakwater off the northern part of the beach, where 48% of the backwashed floats were last found. We conclude that the majority of the floats on the beach were transported alongshore and tended to concentrate in the convergence zone, from where they were backwashed offshore by the nearshore currents generated in the events.
Keywords: Marine macroplastics; Residence time; Submerged breakwater; Nearshore current; Mark-recapture experiment

http://www.globalgarbage.org.br/mailinglist/S0025326X15301387.pdf

Catharina Pieper, Maria A. Ventura, Ana Martins, Regina T. Cunha, Beach debris in the Azores (NE Atlantic): Faial Island as a first case study, Marine Pollution Bulletin, Volume 101, Issue 2, 30 December 2015, Pages 575-582, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.10.056.
(http://www.sciencedirect.com/science/article/pii/S0025326X15301272)
Abstract: Marine debris is widely recognised as a global environmental problem. This study assesses density, type, and temporal trends of marine debris in two sandy beaches of Faial Island (Azores, NE-Atlantic). During seven months (six days per month) the beaches were surveyed by performing 10 random transects at each site. Recorded items within the range 2–30 cm were organised into seven categories. Densities of total debris varied from 0 to 1.940 items m− 2, with plastics dominating both areas. Both beaches, presented the highest debris abundance in February, most probably related to prevailing winds and swell. Location and/or time of year also seemed to influence the type of debris present. These findings provide new insights into debris accumulation rates in the Azores, where no previous studies were made. It also confirms the global trend of increased plastics accumulation on shorelines, highlighting the need for further research in remote islands.
Keywords: Marine pollution; Solid waste; Plastics; Remote islands; Azores Archipelago

http://www.globalgarbage.org.br/mailinglist/S0025326X15301272.pdf

Atsuhiko Isobe, Keiichi Uchida, Tadashi Tokai, Shinsuke Iwasaki, East Asian seas: A hot spot of pelagic microplastics, Marine Pollution Bulletin, Volume 101, Issue 2, 30 December 2015, Pages 618-623, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.10.042.
(http://www.sciencedirect.com/science/article/pii/S0025326X15301168)
Abstract: To investigate concentrations of pelagic micro- (< 5 mm in size) and mesoplastics (> 5 mm) in the East Asian seas around Japan, field surveys using two vessels were conducted concurrently in summer 2014. The total particle count (pieces km− 2) was computed based on observed concentrations (pieces m− 3) of small plastic fragments (both micro- and mesoplastics) collected using neuston nets. The total particle count of microplastics within the study area was 1,720,000 pieces km− 2, 16 times greater than in the North Pacific and 27 times greater than in the world oceans. The proportion of mesoplastics increased upstream of the northeastward ocean currents, such that the small plastic fragments collected in the present surveys were considered to have originated in the Yellow Sea and East China Sea southwest of the study area.
Keywords: Microplastics; Mesoplastics; Field survey; Total particle count

http://www.sciencedirect.com/science/article/pii/S0025326X15301168/pdfft?md5=75e455f3bf340467949184559a7456b8&pid=1-s2.0-S0025326X15301168-main.pdf

Robson Henrique de Carvalho, Pedro Dutra Lacerda, Sarah da Silva Mendes, Bruno Corrêa Barbosa, Mariana Paschoalini, Fabio Prezoto, Bernadete Maria de Sousa, Marine debris ingestion by sea turtles (Testudines) on the Brazilian coast: an underestimated threat?, Marine Pollution Bulletin, Volume 101, Issue 2, 30 December 2015, Pages 746-749, ISSN 0025-326X, http://dx.doi.org/10.1016/j.marpolbul.2015.10.002.
(http://www.sciencedirect.com/science/article/pii/S0025326X1530076X)
Abstract: Assessment of marine debris ingestion by sea turtles is important, especially to ensure their survival. From January to December 2011, 23 specimens of five species of sea turtles were found dead or dying after being rehabilitated, along the coast of the municipality of Rio de Janeiro, Brazil. To detect the presence of marine debris in the digestive tract of these turtles, we conducted a postmortem examination from the esophagus until the distal portion of the large intestine for each specimen. Of the total number of turtles, 39% had ingested marine debris such as soft plastic, hard plastic, metal, polyethylene terephthalate (PET) bottle caps, human hair, tampons, and latex condoms. Five of the seven sea turtles species are found along the Brazilian coast, where they feed and breed. A large number of animals are exposed to various kinds of threats, including debris ingestion.
Keywords: Plastic; Pollution; Waste; Rio de Janeiro; Chelonia mydas; Caretta caretta

http://www.globalgarbage.org.br/mailinglist/S0025326X1530076X.pdf

http://micro2016.sciencesconf.org/page/registration

ABSTRACT SUBMISSION AND CONFERENCE REGISTRATION

Abstract Submission Deadline: 31 March 2016

Prior to submitting abstracts and registering for the conference, attendees must create an account. To do this, go to “Create an Account” in the “My Space” menu.

Once your account is created, the menu links for “registration” and “submission” will become available. Then, follow the instructions on the corresponding pages to register for the conference and submit your presentation abstract online.

Attendees are invited to submit an abstract for an oral or poster presentation on the following MICRO 2016 topics:

* From macro- to microplastics: Weathering and fragmentation processes

* From source to sink: Occurrence and distribution of microplastics in fresh water bodies, coastal zones and the open ocean

* Impacts of microplastics on marine life

* Microplastics as vectors of biological and chemical contaminants

* Socioeconomic impacts of microplastics

* Citizen science, outreach, education and communication

* Solutions and next steps

Abstracts should be submitted in English and should be no more than 300 words long with 1 figure.

Please state your preference for an oral or poster presentation. The scientific committee reserves the right to ask that an oral presentation be changed to a poster or vice versa, to help ensure balanced thematic sessions.

After submitting your abstract, you will receive a confirmation e-mail.

All abstracts, both oral and poster, will be published in the book of abstracts.

If you would like to propose a side event, please directly contact the organizers: micro2016<AT>sciencesconf.org

Instructions for oral presentations:
Supporting material for all oral presentations must be given to the technical staff by 5 pm the day before the presentation, please use pdf format. Each oral presentation is limited to 15 minutes.

Instructions for posters:
A permanent poster exhibition will be displayed at the Cabildo de Lanzarote. Poster boards will be available for displaying your poster.  The size of the poster should not exceed 80 cm wide/110 cm high, so as to be compatible with the panels of the poster stands. If you have a particular request, please contact the organizers.

No Conference Registration Fee.

———- Forwarded message ———-
From: Johnny Gasperi <gasperi@u-pec.fr>
Date: 2016-01-05 11:06 GMT+01:00
Subject: Post-doc fellowship at the UPEC university (France)
To: “fabianobarretto@googlemail.com” <fabianobarretto@googlemail.com>
Cc: “XTERIEUR bruno.tassin” <bruno.tassin@enpc.fr>

Dear Fabiano,

First, I wish you my best wishes for 2016!

Can you please share this update using your mail list (MailingList@globalgarbage.org)
Many thanks,
Best regards,
Johnny

“Dear all,

Bruno Tassin and I are working on microplastics in Paris (France). Maybe some of you already know our works on the Seine River and the recent papers published (https://www.researchgate.net/profile/Johnny_Gasperi).

My university (Université Paris-Est – UPEC) offers an internal post-doc fellowship, which could start in September 2016 for one year. We would like to support any application dealing with microplastics to join our research group.

Eligibility
EU Member States or French candidate can apply. Any post-doc level researcher is eligible but he/she do not have resided or carried out his/her main activity in France for more than 12 months in the last three years. As this fellowship is coupled to the PRESTIGE post-doc program (which is a co-financing program), more details can be found on the eligibility criteria (http://www.campusfrance.org/en/prestige).

Application
A first application to the university is required. The deadline is February, 1st 2016. A pre-selection of candidate by the university will be made in March 2016. The pre-selected candidate will then apply to the PRESTIGE post-doc program. In case of acceptance, this could provide extra funds for research and living allowance. In case of not acceptance by the PRESTIGE program, the university would employ the candidate according to conventional living allowance.

Don’t hesitate to contact us for further information.

Best regards,

Johnny Gasperi (gasperi@u-pec.fr) and Bruno Tassin (tassin@enpc.fr)”

Johnny Gasperi
Maitre de conférence – HDR – LEESU
Faculté de Sciences et Technologie
Université Paris Est – Créteil
61 Avenue du Général De Gaulle
94010 Créteil cedex, France.
Tel : 01.45.17.16.21
Fax : 01.45.17.16.27
E-mail : gasperi@u-pec.fr

post

Carpets

“The chemicals used in the manufacturing of carpet, interior furnishings and building materials may release volatile organic compounds (VOCs) through a process known as off-gassing. Carpet can release volatile organic compounds into the air, especially when first installed. Emissions from new carpet are among the lowest of any household’s indoor furnishings and the most important potential source of VOCs is a component (styrene) of the latex used for the carpet’s backing. Other, less significant sources are dyestuffs and textile auxiliaries, if these have not been completely rinsed out during the process.”

Read more here

RUBBER UNDERLAY

Rubber underlays
“between three main types, namely waffle rubber, sponge rubber and dense rubber.
The waffle and sponge rubber underlays are often graded by their roll weight per 15 square metres, typically as 60lb, 80lb, 100lb and so on, up to around 130lb,
the greater the weight, the more durable and hardwearing the product is, giving longer life to your carpet. Duralay and Tredaire both offer a number of products of this type ranging from 60lb upwards. AirLuxe offer their comprehensive Colourways range covering weights of 100lb up to 150lb for heavier wear areas, or their Footsteps range for the more price conscious.

Dense Rubber underlays are usually graded by their thickness rather than weight, these underlays being a little firmer underfoot than the waffle and sponge rubber varieties, but giving excellent carpet support, especially in heavy foot traffic areas. Duralay Treadmore and Endurance are excellent value products.”

Read more here

The manufacturing process – from Interflor

“The styro butadiene synthetic rubber (SBR) is blended with oils, blowing agents and fillers to create the desired performance characteristics. This is followed by a process called calendarising, where the mix is converted to a smooth and consistent paste.

Once the paste is ready it is rolled into a wide thin sheet, and this in turn is rolled onto a chain to produce the desired profile of either a ‘flat’ or ‘waffle’ underlay. The sheet is then heated at temperatures up to 250˚c and blown, cured and allowed to cool. Finally it is trimmed, cut, rolled and wrapped into branded polythene packaging.

The rubber comes from used car tyres, so the basic raw material comes from 100% recycled sources. Every square metre of crumb rubber underlay contains the rubber of at least one car tyre!

The used car tyres are ground and processed to produce tiny crumbs. These are mixed with latex foam, and the mixture is then poured on to various types of backing material

Vocs from rubber & plastic http://discovery.ucl.ac.uk/1400852/1/2047058413Y.0000000125.pdf

To briefly address some of your questions:

Recycled rubber flooring is very green as it diverts used products from the landfill, and isa durable, renewable material.
There can be off-gassing of VOCs which could be harmful if one has sensitivities.These odors will dissipate over time into the atmosphere.
Manufacturers’ products vary in their environmental and health impacts.
FloorScore is a certification program that tests resilient flooring products, like rubber flooring, for Indoor AirQuality.FloorScore certified products work well for a basement with the proper installation
read more here

Duralay, Tredair and Interflor

Interfloor, part of the Victoria plc group of companies, was created by the merger of Tredaire and Duralay in 2002 but our heritage dates back to the 1940s when Duralay began manufacturing the first carpet underlays in the UK.

We are Europe’s largest manufacturer of carpet underlay and flooring accessories and we supply our products to flooring retailers, distributors and flooring contractors in the UK and around the world.

Duralay quality carpet underlay made in UK. Underlay for durability low-tog high dB rating hard wearing contract flooring specified international certificated.

Crumb Rubber is environmentally friendly as it is made made from recycled rubber.

Wilsons Underlays Ltd
Address: Ravenswharf Rd, Dewsbury WF13 3RD

Recycling synthetic carpets is not only possible but cost effective too!

Each year 400,000 tonnes of carpet waste is buried in UK landfill

Increasingly, businesses, householders and local authorities are looking for better alternatives for the recycling of unwanted carpet materials. We help ensure that the growing demand for carpet recycling services is met.

Carpets are made from natural and synthetic fibres, which still have a value once the carpet is no longer wanted; they can be used in a wide range of applications from sports surfaces to insulation.

Carpet Recycling UK is a not for profit membership association working to increase the recycling of carpet waste across the UK

Check out the website

Recycle your own plastic…

Just read this article in Recycle Reminders  about Dutch designer Dave Hakkens. He has just gone and made himself a plastic recycling machine that  combines “a plastic shredder, extruder, injection moulder, and rotation moulder to create bins, lampshades, candle holders, and other knick-knacks from waste plastic. “I wanted to make my own tools so that I could use recycled plastic locally,” he said.”

Course you did, who doesnt? And he is not just clever but generous. Check this out.

“He plans to upload the blue prints of his project online, so that people the world over can set up their own recycling workshops and create new products from neighborhood waste. He hopes that ideas generated due to crowdsourcing can help improvise the prototype.”

Do read the full article … and if you have any spare change…… And you can visit his precious plastic project here and see his other projects here.

 

Of course the best solution is not to make any plastic waste at all.

 

Recycling… a post code lottery

I knew that council recycling provision and services varied across the UK but while I have been abroad, it seems those differences have developed into rifts of enormous proportions.

Here in Huddersfield we have a green bin collection for recyclables. However the only plastic packaging they take  is plastic bottles. Other types of plastic such as yoghurt pots, margarine tubs, plastic trays, polystyrene, plastic carriers and film are specifically banned.

This does not mean these products cannot be recycled but, for a number of reasons, it is not always viable to do. As the British Plastics Federation explains: “Nearly all types of plastics can be recycled, however the extent to which they are recycled depends upon technical, economic and logistic factors.” Their extremely interesting website goes on to note that “As a valuable and finite resource, the optimum recovery route for most plastic items at the ‘end-of-life’ is to be recycled, preferably back into a product that can then be recycled again and again and so on. The UK uses over 5 million tonnes of plastic each year of which an estimated 24% is currently being recovered or recycled.” !!!!

If all plastics can be recycled, and recycling is the ideal option, why does Huddersfield Council only collect bottles? Well, while private companies might invest in the more esoteric forms of plastic recycling and undertake research, local councils, for technical, economic and logistical reasons, have tended to stick to recycling simple plastic. For sure some councils  do more than others but as  Lets Recycle notes “local authorities are responding to the pleas of residents to allow them to recycle mixed plastics, such as yogurt pots, but the practice is still relatively rare due to the volatility of end markets and lack of UK processing capacity for mixed plastic material. ”

Basically, you know where you are PET bottles, they are easy to recycle and there is a good end market for the recycled product. Plus the problems with mixed plastic recycling are many. For instance food containers are banned from many recycling schemes because dirty plastic can contaminate the load, the payback is low and workers don’t want to work with rotting and smelly food wraps. While plastic recyclers are working on ways to deal with dirty plastic, the new technology is expensive and the market for the end product still uncertain.

The other  problem is identification. To recycle plastic you have to know what plastic you are dealing with. Different polymers need to be recycled differently. It was in recognition of this that the plastic code system (where different types of plastic are identified with a number) was implemented. However this is not compulsory. Furthermore there are now more plastics then there are numbers with more complex plastics are being developed daily. A plastic recycling batch can contain 5% of unknown plastic and no more – so you can see the problem with recycling unidentified plastics.

It is possible to identify unmarked plastic using light beams. I came across this technology when I wanted some plastic film identifying. The company I used told me the process was extremely expensive and so only used for research purposes. Consequently, most U.K. based plastic-recycling plants tend to rely on the numbering system. Which limits where they collect their plastic from. They want big batches of known plastic not piles of unidentified rubbish. They usually take industrial waste and offcuts and, of course, the easily collected and identified plastic bottles.

To see how a pretty-basic, fairly standard, plastic recycle plant works you can read up on my visit to Lynwood Plastics where I saw them making recycled plastic lumber and buckets.

This is how it is in Huddersfield. In Sussex you can recycle all  waste plastics including food wrappers and unidentified plastic objects through the council recycling scheme! Though you are supposed to wash the food containers first, it must be assumed that the system can deal with those who don’t. And apparently the recycling plant uses light technology to identify rogue plastics. This works on all except black plastic as the darker dies stops the light beams from passing through. In short they have a new and state of the art recycling plant which recycles pretty much everything but polystyrene, fruit nets, blister packs, crisps, sweets, biscuit wrappers and pet food pouches. You can read all about their super-duper recycling plant

Recycle-get this...

Recycle-get this… (Photo credit: practicalowl)

here .

So are times are changing? Well the  government wants to “move towards a ‘zero waste economy’.” Which, as they explain, “doesn’t mean that no waste exists – it’s a society where resources are fully valued, financially and environmentally. It means we reduce, reuse and recycle all we can, and throw things away only as a last resort…. and some councils are better at it than others.”

Better than others? That is putting it rather mildly. Recycling provision, for plastic at least, varies wildly across the UK. Despite being concerned with the levels of rubbish produced, the UK government, unlike some other parts of Europe, has no standardized way of collecting or managing household waste. Nor does it specify how recycling targets should be met

Rather, as this recycling guide explains,

it’s up to the local authority to implement schemes suited to their area. Services and facilities thus vary greatly, from separated waste collection to the single kerbside “green box” system. Variation seems endless, and it’s due to the following:

Cost – Investment in new recycling facilities is expensive, so cash-strapped councils stick to established recycling processes, (paper, glass).
Targets – Statutory recycling targets are weight-based, shifting focus onto heavier waste streams (glass, metal) at the expense of lighter plastics.
Logistics – Collection can be problematic in rural (long distances between homes, scarcity of recycling facilities) and urban areas (limited space, tower blocks).
No nationwide framework – Industry bodies, charities and campaign groups encourage best practice but there is still a lack of government guidance.

Hmmmm. You can find more information on different recycle services here, and see how good your council is with this interactive map.   Karen Cannard is, as ever, a wonderful rubbish resource. You can read her post on plastic recycling here.

But of course the best way to deal with plastic trash is to not create it in the first place!

Mascara

Pull off the silver casing covering the “well” of the mascara. Don’t be afraid to pull hard!

Mascara Refills Step 2

STEP 2

Now do the same for the mascara wand casing.

Mascara Refill Module Step 3

STEP 3

Unwrap your new mascara refill, and insert into each part of the casing. You should feel it “click” into place. The refill can be recycled, and your Kjaer Weis makeup is now ready to use!

Its seems that this comes in plastic free packaging and while the product its self is not plastic free, it is recyclable and represents a huge reduction in plastic. I am investigating. For more details visit https://kjaerweis.com/about/intelligent-refill-system

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Which plastics are collected for recycling in the UK

Please bear in mind that plastic recycling is a fast moving world with new advances being made all the time. By the time you read this, it may be out of date! Also when oil prices are low plastic is cheap and recycling is hardly profitable.

While most plastics can be recycled, not all of them are. As the British Plastics Federation explains: ” the extent to which they [plastics] are recycled depends upon technical, economic and logistic factors.” Their extremely interesting website goes on to note that “As a valuable and finite resource, the optimum recovery route for most plastic items at the ‘end-of-life’ is to be recycled, preferably back into a product that can then be recycled again and again and so on.”

While considering this, it is worth remembering that the UK uses over 5 million tonnes of plastic each year of which an estimated 24% is currently being recycled.

But just because these products are collected for recycling it does not mean that they will be recycled in the U.K. or even recycled as you might consider it to be.

The term recycling is used to describe a wide range of options including reselling to be recycled. This is a controversial process whereby plastic is collected in one country and sold to others for recycling.

It is also used when plastic is used as fuel in electricity producing incinerators.

You can read more about the different methods of “recycling” here.

Most plastics are marked with a plastic code  or a number identifying the type of plastic. This information is used by recyclers.These types of plastics are currently collected for recycling in the UK but check with your local governments recycling scheme for updated info or the bank locator on recycle-more.co.uk.

1,2 & 3

1 PET Polyethylene Terepthalate
Fizzy drinks Mineral water bottles Squashes Cooking oils
Recycling points are located throughout the UK

2 HDPE High Density Polyethylene
Milk bottles Juice bottles Washing up liquid Bath & shower bottles
Recycling points are located throughout the UK

3 PVC Polyvinyl Chloride
Usually in bottle form however not that common these days
Some Recycling points in the UK

4,5,6 & 7

4 LDPE Low Density Polyethylene
5 PP Polypropylene
6 PS Polystyrene
7 OTHER

Many types of packaging are made from these materials, for example, plastic formed around meats and vegetables. Due to the mixture of compounds these plastic types are hard to recycle and not generally recycled in the UK.

From recycle more

Read up about the different types of plastic here

The best response to plastic trash is to  REFUSE IT and find a compostable alternative.

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Coconut Oil

Is a hard oil which has a very low melting point.
When the weather gets warm it will get liquid.

I use it….

to remove eye make up and clean crusty eyes.
as a conditioner. I have very oily hair so I rub it on my hair before showering, leave for 5 minutes then shampoo off. Afterwards my hair is lovely and silky. Village boy has very dry hair so he applies a little after showering. His hair is nice and smooth.
as a general moisturiser. Just slap it on, it is nice and light.
in my homemade creams
as an after sun treatment use it neat or with a few drops of lavender essential oil to help heal sun damage
as a lubricant with these biodegradable condoms

More

Other people use it to do rude things, for cooking and lots of other stuff.

Buy

I buy mine great big glass jar at Kadims, the Asian Supermarket on Blacker Road Huddersfield. You can also get it in a glass bottle from Tescos and of course on line. You can get organic coconut oil from the Half Moon Health shop in Huddersfield.

NB Not quite plastic free as the lid is plastic lined, but as close as you will get.

Buy Online

Biona Org Odourless Coconut Oil 610 ML x 1
Biona Org Odourless Coconut Oil 610 ML x 1
£10.00
Amazon Products

Being committed to local shopping, I prefer to buy that way whenever possible. I would encourage you to do the same. One of the joys of living plastic free is mooching round the local shops seeing what you can source. But sometimes you can’t buy local so I have put together an Amazon catalogue.

Yes we do get an affiliation fee for this, and no we are not entirely happy with Amazons recent history. However, we have always found their service to be good and their packaging usually compostable.

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Ecoforce -recycled cleaning products

Increasing the use of recycled plastic products
EcoForce’s mission is to replace products made from ‘virgin’ raw materials with those made from recycled plastic and is committed to bringing affordable, practical recycled items to the general public.

We live in a world of finite resources and this is not going to change. Making recycled plastic uses 70% less energy than making virgin plastic, reduces landfill and conserves precious resources. It makes plain common sense to use recycled products for everyday tasks, especially if these produts work just as well, if not better, than alternatives made from raw materials. EcoForce is determined to help you run a greener home without it costing the earth.

Links / featured posts
www.ecoforce.co.uk

A bit more…

This post was written by the contributor. It is a PfU.K. Directory submission.

And the Pf U.K. Directory is…?

…a directory of UK-based groups, organisations businesses and individuals who are responding to the problems presented by the misuse of plastic. That does not anti-plastic necessarily but certainly plastic-problem aware.

The DIRECTORY is to promote their fantastic work. Read more here…

Got a project?
It is very easy to get a project featured. Each contributor submits a short synopsis of their project, focussing on the plastic aware element and I post it. You can read the submission guidelines here.

 

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Mandy Barker photographer

Mandy Barker Photographer – Fine Art

My work aims to engage with and stimulate an emotional response in the viewer by combining a contradiction between initial aesthetic attraction and the subsequent message of awareness. All plastics photographed have existed in the sea and have been collected from beaches around the world.

Collect/clean plastic debris from beaches. Photograph collected debris for images to provide awareness to a wider audience about issue of marine plastic debris.

Recent project image, ‘Tide Time’ to promote the Environmental Social Responsibility programme for The Schofield Watch Company. (see link)

Find me
website; www.mandy-barker.com

Follow me posting a piece of marine plastic debris EVERYDAY
blog; mandy-barker.blogspot.co.uk
twitter; @plasticpieces

More

This post was written by the contributor and is  a PfU.K. Directory submission.

The Pf U.K. Directory is…?

…a directory of UK-based groups, organisations businesses and individuals who are responding to the problems presented by the misuse of plastic. That does not mean anti-plastic necessarily but certainly plastic-problem aware.

The DIRECTORY is to promote their work not mine. Read more here…

Got a project?
It is very easy to get a project featured. Each contributor submits a short synopsis of their project, focussing on the plastic aware element and I post it. You can read the submission guidelines here.

Follow us on facebook here

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Eating plastic free from supermarkets

Supermarkets
The Co-op in the UK is owned by it’s members. That’s you. So do use that whenever possible. Sadly they are bad for packaging. Write and tell them.
Waitrose is owned by staff in the John Lewis Partnership and has some kind of deal with the workers whereby they share some of the profits. They do some excellent plastic free buns and bread and is one of the few places you can still get butter in paper.
Buy British – you might want to choose a mostly British owned company to shop with.
Tesco
Sainsburys
Morrison plc are listed on the London stock exchange. Whilst the majority of investors are British or British companies or pension funds, these investments can be held by anyone around

Eating Plastic Free Food 

Plastic free food is food that is unwrapped  but for me it also includes

From Supermarkets!

Now many people think you cannot be plastic free and shop from supermarkets. I agree it is not easy

And let me say right now I don’t like supermarkets. They are killing off the local shops and take money out of the community. But for many people they are the only option. Because they have killed off local shops. Vicious circle. But this is about plastic-free food NOT supermarket politics so I am going to prove that you can eat plasticless and shop at supermarkets.

How to do it…

If prepared to eat seasonally, traditionally (think meat and two veg with spuds), and cook from scratch, supermarkets if they are big enough to have meat and fish counters can supply you with a fair variety of food. If you are depending on Tesco Express you are going to go hungry.

Bring Your Own Bags

You will also need to take your own packaging. Check out the plastic-free shopping kit here.

Ingredients for a week

I got an a big sack of unpackaged fruit & veg from Tesco,

It included leeks, potatoes, onions, carrots, broccoli, courgettes, peppers. apples, a melon, mushrooms and bananas.

Apart from the peppers (Holland), and Melon (Spain), and bananas (forgot to look), it was all grown in the U.K.

I got loose ginger and garlic from Tesco. The chiles I bought a while ago from the Asian shop but I have seen them loose in Morrisons.

Eggs & oats in a cardboard box.

Back to Tesco’s for lard in paper. Sainsbury’s and the Co-op do butter in paper.

Meat and fish can be bought unpackaged from the counters but I ask that they use our own compostable biobags.

The brown rice I bought loose from Wholefood market sometime ago. White rice can be bought in a box from Lidles.

We also get some cheddar cheese from Tesco. It was cut off the (plastic – wrapped) block but wrapped in our own packaging. The plastic is not in our bin. You can read up on how we feel about this, here.

You can get bread rolls loose from Tesco but I don’t like them much, the co-ops are much better. Lidles and Waitrose do loose loaves of bread. Almost everywhere does croissants. I also used my bread machine and plastic wrapped dried yeast.

More information on all of the above can be found here…

Non Supermarket Beverages

Drinks were

Tea you can buy loose PG Tips from supermarkets but I had loads in anyway.
Coffee which you can’t get plastic free at the supermarket. I get mine from Coffeevolution
Milk was from the milkman. Read on…

Fizzy drinks were carbonated water made with the sodastream mixed with homemade ginger and lemon syrup.Read on…

Meals For the Week

Breakfast
Porridge with bananas

Toast and butter
Croissants and fruit
Omelette and other forms of egg

Lunch

 

  • Butties from the shop
  • Butties made at home
  • Veg soup – anything that is looking a bit sad and needs eating up thickened with potatoes. I would prefer to use lentils but I cannot get them .

 

Dinners
Day One Stir Fry left over steak from Sunday, lots of veg in a spicy tomato sauce served with rice.

Day Two Roast chicken and veg with home made gravy from chicken juices and flour. Wine (plastic lined screw top), was added.

Day Three a rich and meaty stew made with stewing steak served with boiled potatoes. Meat and veg were from Tesco’s.

Day Four Bangers and mash made with Tesco’s chippolata sausages – the only ones they had loose.

Day Five Mushrooms and peppers were added to the left over day three stew to make a rich goulash that was served with rice.

Day Six Bacon ribs from Stockport Market – yes I know its not a supermarket but I felt so sorry for them. Stockport Market used to be huge spreading across the square and down the side streets. Now there are hardly any stalls outside. The indoor market was open for business but there were not many shoppers. I bought some meat, veg and loose sweets. Such a shame.

Day Seven pork from Tesco’s used in a stir fry made with coconut powder that is not plastic free. It comes in a plastic sachet. BUT I made my own noodles. First time ever. So easy!

You can see photos over on Facebook
More info

The Plastic Free Cookbook

A discussion of supermarkets here http://plasticisrubbish.com/2016/03/27/lyn-bulls-supermarket-research/

Which Shop

Use your local shops Reasons why here.

Buy British and cut those air miles. Some ideas HERE

Food Here is a list of food types category with purchase details

Loose Food
Find out if a shop near you sells bulk food loose. This is stuff that that normally comes plastic packaged. A list of towns with shops selling loose food.


Milk 
Delivered in glass bottles but double check before you order

 

Help

Trying to go plastic-free – try the plastic is rubbish support group. Follow the Facebook link.

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Who owns what

This infographic is from reddit  and I have no idea if it is true or not! But there is no doubt that very few companies own an awful lot of stuff.

 

Boycotting plastic means buying unwrapped which often means buying local – from the butcher, the green grocer and the baker.

Which takes back some control and keeps money in the community.

Just another reason we do it

Who owns your daily news……
With thanks to Left foot forward
Newspaper(s)
Combined print and online readership
(In brackets print alone)
Effective owner/s
Information about effective owner/s
Political orientation of newspaper/s
% of combined print and online (Print alone)
The Sun/The Sun on Sunday
13,674,000
(12,765,000)
Rupert Murdoch
Billionaire. Lives in US.
Alleged tax avoider.
Supported Tories in 2010
18.6%
(20.7%)
The Mail/ Mail on Sunday
12,188,000
(9,534,000)
Lord Rothermere
Billionaire. Lives in France.
Non-domiciled for UK tax
Supported Tories in 2010
16.5%
(15.5%)
Metro
7,986,000
(7,597,000)
Lord Rothermere
Billionaire. Lives in France.
Non-domiciled for UK tax
Supported Tories in 2010
10.8%
(12.3%)
Mirror/Sunday Mirror/ People
7,874,000
(7,063,000)
Trinity Mirror plc
Public Limited Company
Supported Labour in 2010
10.7%
(11.4%)
The Guardian/The Observer
5,342,000
(2,898,000)
Scott Trust Ltd
A company with purpose “to secure Guardian’s independence”
Supported Lib Dems in 2010
7.3%
(4.7%)
Telegraph/ Sunday Telegraph
4,998,000
(3,128,000)
David and Frederick Barclay
Billionaires. Live on private island near Sark.
Alleged tax avoiders.
Supported Tories in 2010
6.8%
(5.1%)
The Times/ Sunday Times
4,608,000
(4,418,000)
Rupert Murdoch
Billionaire. Lives in US.
Alleged tax avoider.
Supported Tories in 2010
6.3%
(7.2%)
The Independent/ i/Independent on Sunday
4,002,000
(2,770,000)
Alexander (father)and Evgeny (son) Lebedev
Alexander is a billionaire, ex-KGB and lives in Russia. Evgeny lives in the UK
Supported anti-Tory tactical voting in 2010
5.4%
(4.5%)
London Evening Standard
3,850,000
(3,443,000)
Alexander and Evgeny Lebedev
Alexander is billionaire, ex-KGB and lives in Russia. Evgeny lives in UK
Supported Tories in 2010
5.2%
(5.6%)
Daily Express/Sunday Express
3,118,000
(2,756,000)
Richard Desmond
Billionaire pornographer.
Alleged tax avoider.
Supported Tories in 2010
4.2%
(4.5%)
Daily Star/Daily Star Sunday
2,972,000
(2,873,000)
Richard Desmond
Billionaire pornographer.
Alleged tax avoider.
Supported Tories in 2010
4.0%
(4.7%)
Daily Record/ Sunday Mail
1,719,000
(1,527,000)
Trinity Mirror plc
Public limited company
Supported Labour in 2010
2.3%
(2.5%)
Financial Times
1,339,000
(928,000)
Pearson plc
Public limited company
Supported Tories in 2010
1.8%
(1.5%)
TOTALS
73,670,000
(61,700,000)
Readership of UK press (for papers over 1 million) in March 2013 by effective owners
Effective owner(s)
% of combined print and online (print alone)
Lord Rothermere
27.3 (27.8)
Rupert Murdoch
24.9 (27.9)
Trinity Mirror plc
13.0 (13.9)
Alexander and Evgeny Lebedev
10.6 (10.1)
Richard Desmond
8.2 (9.2)
Scott Trust
7.3 (4.7)
David and Frederick Barclay
6.8 (5.1)
Pearson plc
1.8 (1.5)
Over a quarter (27.3 per cent) of the press is owned by Lord Rothermere and 24.9 per cent by Rupert Murdoch – between them these two men have over 50 per cent of the printed press.

Over three quarters (77.8 per cent) of the press is owned by a handful of billionaires. There are only 88 billionaires among the 63 million people in the UK and most of the barons do not even live in the UK.

recycling rates down this year

…oh dear – NOT going to meet the 2020 targets and waste creation on the rise. It’s one hell of a mess!

CIWM notes the disappointing trend in recycling performance across councils in England, recently released by Defra in the Statistics on Waste Management by Local Authorities in England 2012/13 report. This trend has been evident and commented upon by CIWM over the last couple of years and Defra now admit that this rate of increase is insufficient to meet the 50% EU target by 2020.

CIWM sees this as a direct result of the increasing financial pressures on local government. These are examples of authorities either pulling back from the improvements to waste services (e.g. introducing food waste collection), curtailing existing services (e.g. charging for green waste collection) or reducing their communications programmes. Taken together, the net effect of these spending constraints is showing itself in this loss of momentum in household recycling improvement across England.