Plastics in the ocean
Since the 1950s, huge amounts of plastic have been produced worldwide. Plastic is a collective name for certain synthetic polymers, mainly polyurethane (PUR), polyethylene (PE), polyamide (PA), polyethylene terephthalate (PET), polystyrene (PS), polyvinyl chloride (PVC) and polypropylene (PP). Part of the plastic waste ends up in the oceans. This waste consists of plastic debris visible with the naked eye ('macroplastics' > 2.5 mm and 'mesoplastics' > 1 mm, according to the GESAMP expert group[1]) and microscopic pieces. At an international research workshop hosted by NOAA on the effects and fate of microplastic marine debris, participants suggested an upper size limit of 5 mm for microplastics[2]. Microplastics (MP) are particles that are either originally manufactured at micro size (primary MP) or are the result of physical, chemical and biological weathering and fragmentation of macroscopic debris (secondary MP). The smallest plastic fragments (< 1 μm) are called nanoplastics.
Microplastics occur in various shapes:[3] fragments (irregularly shaped pieces that result from the break down of larger plastic items), fibers (thin, elongated strands often originating from synthetic textiles or fishing nets), beads (small, spherical particles commonly found in personal care products like exfoliating scrubs and toothpaste), foams (lightweight, porous particles originating from products like polystyrene foam), films (thin, flat pieces that result from the degradation of plastic bags, wrappers, and similar items), pellets (pre-production plastic beads used in manufacturing, often spilled and dispersed into the environment).
Many studies have been conducted to determine the amount of plastic in the oceans and the effects on the marine ecosystem. This article summarizes some important results of these studies.
Contents
Budget of plastics in the ocean
The current (2024) global production of plastics is estimated at about 400 million tons. About 8-9 % of fossil fuels consumed annually are used in the manufacturing of plastics (4–5% as feedstock and 3–4% as energy[4]). Polyethylene (PE), polypropylene (PP), and polyvinyl chloride (PVC) are the most dominant plastics globally (80 % by weight). Products made of plastic or containing plastics eventually become waste. Most waste products are destroyed (incinerated) or stored in landfills, some are recycled and some are released in the natural environment (‘mismanaged’). A small fraction ends up in the ocean, mostly via rivers[5], but also via sea-based sources (mainly discarded fishing gear) and the atmosphere. About half of the plastic debris larger than 0.5 mm in the Great Pacific Garbage Patch originates from fishing gear[6]. Estimates of the amount of plastic waste entering the sea vary widely, from 0.5 Mton/yr to more than 10 Mton/yr [7][8][9][5]. The lower values likely underestimate the supply rates of plastics to the ocean. They do not include atmospheric inputs [10] and plastic fragments smaller than <300 μm [11]. Sea-based sources account for 10-20% of the total input of plastics[9].
There is also much uncertainty about the amount of plastic accumulated in the oceans since the mass production began in the 1950s. Early estimates for the total amount of plastic in the surface ocean water range from 0.1–0.8 Mton for microplastics and around 0.8 Mton for plastic macrodebris[12][13][9]. This is a very small amount compared to the total input of plastics to the oceans over the past 60 years. This total input has been estimated at around 25 Mton (4-5% of the mismanaged plastic waste generated in the period 1961-2017[9]), but could be an order of magnitude larger[11][14].
There is compelling evidence from observations and model simulations that the majority of the plastic waste entering the sea does not (directly) reach the global ocean, but is retained in the coastal zone[15][13][16]. Large debris are broken down by mechanical fracturing in high-energy coastal and shelf environments during bedload transport and buried in sediments. Buoyant plastic debris generally become stranded on beaches[17]. Another part of the plastic waste (estimated at about 3-11 Mton[18]) consists of microdebris accumulated on the ocean floor through the incorporation of plastics into sinking organic particles (e.g., marine snow and fecal material)[14].
Micro- and nanoplastics
Recent studies attribute the major contribution to ocean plastic pollution to smaller size classes of microplastic and nanoplastic. Using nets with a mesh size of 100 μm resulted in 2.5-fold and tenfold higher microplastic concentrations than with 333 μm and 500 μm meshes, respectively[19]. Samples from the 200 m surface layer of the Atlantic ocean were analyzed for the three polymer groups polyethylene, polypropylene and polystyrene. The majority of the microplastics were <100 μm, with the peak size distribution observed in the range 50–75 μm for all the polymer groups. Only a small fraction of all three polymer groups were >300 μm. The three polymer groups represented a weight estimated at 11.6–21.1 Mton for the whole Atlantic ocean[11]. According to these figures, concentrations of micro and nanoplastics in the oceans fall in the range 0.01-10 mg/m3.
Micro- and nanoplastics are likely to originate mainly from land-based sources: effluents from wastewater treatment plants (e.g. components of cosmetic and care products, fibres from washed synthetic clothing), grindings from synthetic materials (e.g. tyre wear, carpet wear) transported by run-off or airborne, weathering of plastic waste along beaches that is washed to sea, etc. [20]. Breakdown of microplastic debris in the ocean into nano-fibers is extremely slow and therefore considered less important[21]. Several studies report that the smaller the plastic particles, the more toxic they are to marine biota[22].
Degradation of plastics in the marine environment
Degradation mechanisms for macroplastics occurring in the marine environment are: (i) colonization of plastics by microorganisms that form a biofilm on the polymer surface and induce biodegradation via surface erosion; (ii) depolymerization by abiotic hydrolysis of functional groups (esters, carbonates and amides), which causes molecular weight reduction; and (iii) photodegradation by exposure to UV light, resulting in molecular weight reduction and cracking of the material[23]. Microbes that degrade plastics attack plastics extracellularly to (partially) depolymerize the complex and large molecule into compounds that can be used as carbon and energy sources[24]. Fungi, like bacteria, can also use plastics as carbon source. Laccase enzymes play an important role in fungi attachment[23]. However, the energy yield of enzymatic degradation of microplastics is low, compared to the energy that can be retrieved from other carbon sources. The selective advantage for microbes to degrade microplastics is limited. This may explain why no significant adaptation of the ocean microbiome has occurred in spite of ubiquitous micro- and nanoplastics[25].
There is no firm evidence that the worldwide most produced synthetic polymers with a pure carbon backbone (including polypropylene (PP), polyethylene (PE), polyvinyl chloride (PVC) and polystyrene (PS)) can be degraded by microbes. No enzymes are known that act on these polymers[26][27]. Microbial degradation requires (artificially) aged polymer since physicochemical ageing processes increase the abundance of monomers and oligomers such that they may be degraded by microbial activity.
Weathering and photo-oxidation are generally considered to be the most important processes for the degradation of plastics. They result in a change in the chemical, physical and mechanical properties of the plastics and included chemical additives[28]. Abiotic factors, such as shear stress caused by wave action, ultraviolet radiation from the sun and heat make plastics brittle and break them up. Fragmentation of macroplastics results in micro- and nanoparticles. UV photodegradation breaks the polymer backbone of exposed plastics down, releasing low molecular-weight dissolved organic matter like carboxylic acids, monomers and more complex hydrocarbons or halogenated compounds[29]. These degradation products of UV radiation can be further decomposed by microbes. Chemical additives can also be a target for microbial degradation but may interfere with enzyme degradation processes[26]. Polystyrene can be completely mineralized by photooxidation[30].
Photodegradation is one of the major driving forces inducing the disintegration of plastics in the environment, including the reduction of chain length, surface oxidation, formation of microplastics and loss of mechanical properties[29]. It can be a key mechanism for fragmentation of plastic debris floating in the oceans. However, photo-oxidative fragmentation of plastic debris in the upper ocean layer is inhibited by several factors: short residence times before sinking, attenuation of UV radiation below the upper 1 meter, fouling by biota, low water temperature and low dissolved oxygen. This suggests that most of the abundant micro- and nanoplastics found in the oceans originate from primary sources (e.g. cosmetic products, washing/grinding of synthetic materials) or from photodegradation of macroplastic debris on land (especially stranded along shores) prior to reaching water[13][31].
Effective microbial degradation has been demonstrated for heterochain plastic polymers such as polylactic acid (PLA), polycaprolactone (PLC), polyurethane (PU) and polyethylene terephthalate (PET). These polymers contain oxygen, nitrogen or other heteroatoms in their backbone structure, which increases the susceptibility to degradation by biotic and abiotic hydrolysis reactions[27]. In the marine environment, bacteria found in association with polyethylene terephthalate (PET) and ester-based polyurethane (PUR) have genes encoding for monooxygenases, peroxidases and dehydrogenases, that can facilitate the initial degradation of these plastics[24]. However, currently known PUR- and PET-active enzymes and microorganisms have a very low conversion rate (on the order of decades to centuries[32]). Even for plastics marketed as biodegradable, such as PLA, prior treatment (such as heating) is necessary to accelerate microbial degradation[27].
Yoshida et al. (2016[33]) discovered that the bacterium Ideonella sakaiensis produces enzymes able to degrade polyethylene terephthalate (PET), using it as a carbon and energy source. However, only low-crystallinity PET can be degraded this way, whereas most PET water bottles have a high crystalline content which is not amenable to microbial degradation without prior treatment[34]. Another bacterium, Pseudalkalibacillus sp. MQ-1, has shown skill to increase the hydrophilicity of polyethylene and to decrease the crystallinity[35].
Ecosystem impacts
Some important observed impacts of plastics on marine ecosystems and fauna are:
- Macroplastics cause smothering of organisms when getting trapped in coastal ecosystems such as corals and mangroves. For example, corals can be detached from the hard substrate, with broken or dead branches. Exposure to light, oxygen exchange, prey capture and growth can be impaired and pathogens can get a foothold for invasion. On the other hand, plastic debris can provide a substrate for colonization by corals[36].
- Macroplastics can cause entanglement of marine animals. This happens especially for abandoned fishing gear (74% of the cases). Entanglements causing the amputation of limbs have been reported in all species of sea turtles. Entanglement with and ingestion of plastic debris have been reported in 35 species including dolphins, whales, seals, sea lions, sea otters, polar bears and manatees[36].
- The ingestion of macroplastics or microplastics can cause injury to the intestines of species and accumulate in the animal's organs, causing blockages of the gut tract that result in pseudo-satiety sensation and physiological stress, alteration of the feeding and retardation of growth, reduction in fertility, fecundity and survival rate of progeny[37]. A compilation of a large number of studies shows that on average 39% of all examined seabirds had ingested macroplastics, and on average 33% microplastics, while ingested microplastics where found in all sea turtles sampled in the Atlantic, Mediterranean and Pacific[36]. (Substantially lower percentages were reported in another literature survey[38]) There is evidence of the ingestion of microplastics by marine zooplankton, as well as the transfer of microplastic particles from mesozooplankton to macrozooplankton. Therefore a real risk exists of microplastics invading marine food webs[39]. Microplastics impair the capability of fish larvae to evade predators[40]. As these organisms are more likely to be eaten, the concentration of microplastics in their predators will be biomagnified[41]. As an example of biomagnification, a krill-feeding blue whale consumes 2.51 to 43.6 kg of microplastics per day[42].
- Micro and nanoplastics can cross cell membranes[26]. Adverse effects have been observed in many organisms exposed to synthetic fibres, particularly in species at the lower end of the food chain. Laboratory studies on the exposure of marine biota to microplastics report, among other things, reduced fitness of zooplankton populations, reduced filtration rates of bivalves, increased mortality in crabs and gill damage in fish, together with increased oxidative stress and altered metabolism[43].
- Chemical additives or pollutants adsorbed to plastic debris from seawater can become bioavailable when ingested by organisms. Adsorbed contaminants such as pesticides, herbicides and heavy metals (e.g. Al, Cd, Co, Cr, Cu, Fe, Hg, Mn, Pb and Zn) can lead to changes in metabolic and reproductive activity, impaired immune response, oxidative stress, cellular or subcellular toxicity, inflammation and cancer[37]. Micro- and nanoplastics have a high surface area to volume ratio and can therefore adsorb greater amounts of hydrophobic contaminants from the environment than macroplastics. They can also be taken up by a much wider range of species, so their potential to enter marine food webs and move up trophic levels through predation is higher. Especially filter-feeding animals, from small mussels to large whale sharks, can ingest considerable amounts of micro- nanoplastics[36]. On the other hand, chemicals accumulated in the body can adsorb to microplastics and be excreted, reducing the burden on the organism. Similarly, plastics in water can accumulate chemicals, leading to a lower concentration of chemicals in the water[36].
Toxic leachates
During manufacture, plastics are commonly provided with additives to impart desirable and beneficial properties. In some cases, additives represent up to 30% of the plastic weight[27]. Release of these additives is boosted by UV weathering[29]. Frequently added chemicals include bisphenol-A (BPA), per- and polyfluoroalkyl (PFAS), brominated flame retardants, PCBs and a group of substances called phthalates[44]. For example, PFASs are added for water, heat, and grease resistance, while bisphenols are added for flexibility properties. These chemicals belong to the so-called endocrine disruptors, which disrupt the hormonal functions of animals (including humans). In zooplankton, exposure to PFAS yields developmental retardation, reduced fecundity, oxidative stress, irregular apoptosis, cellular proliferation, and generates reactive oxidative species (ROS) which further damages DNA[43]. Bisphenols have significant negative impacts on reproductive function in marine animals, where males experience more prominent and lasting effects. Other added endocrine disruptors have similar detrimental effects when they enter the gastrointestinal tract of organisms after leaching from ingested microplastics. They affect movement, behavior, sexual development, growth (including growth abnormalities), survival and reproduction. They can bioaccumulate in organisms such as fish and tadpoles. Early life stages, amphibians, fish and invertebrates are particularly sensitive[36]. Additives also include toxicologically relevant trace metals and metalloids such as As, Cd, Sb, Sn or Pb [29]
It must be noted that not all fibres in the environment are of synthetic origin. Fibres of natural origin (e.g. cotton, viscose) are also widespread. These natural fibres are often chemically treated with dyes, additives, and flame retardants and therefore pose a similar threat[43].
To date (2022), the problem of micro- and nanoplastic effects in the marine environment has been assessed almost exclusively on the basis of laboratory exposure studies. These studies typically look at concentrations of micro- and nanoplastics that are much higher (up to g/l) than concentrations in the natural marine environment (< 10 µg/l) [45][3]. It was shown, for example, that at such high concentrations, plastic leachates impair photosynthesis in common picophytoplankton species, such as Prochlorococcus [46], whereas no effect of microplastics on photosynthesis was found in studies with naturally occurring concentrations[47]. Linking laboratory results to natural exposure levels is essential to avoid overestimation of the problem. Improvement of existing techniques is needed to obtain reliable and reproducible information on exposure levels in natural environments[48].
Related articles
References
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