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Wikipedia

Biodegradation

April 16, 2023

For the journal, see Biodegradation (journal).

Biodegradation is the breakdown of organic matter by microorganisms, such as bacteria and fungi.[a][2] It is generally assumed to be a natural process, which differentiates it from composting. Composting is a human-driven process in which biodegradation occurs under a specific set of circumstances.

Yellow slime mold growing on a bin of wet paper

The process of biodegradation is threefold: first an object undergoes biodeterioration, which is the mechanical weakening of its structure; then follows biofragmentation, which is the breakdown of materials by microorganisms; and finally assimilation, which is the incorporation of the old material into new cells.

In practice, almost all chemical compounds and materials are subject to biodegradation, the key element being time. Things like vegetables may degrade within days, while glass and some plastics take many millennia to decompose. A standard for biodegradability used by the European Union is that greater than 90% of the original material must be converted into CO2, water and minerals by biological processes within 6 months.

Mechanisms

The process of biodegradation can be divided into three stages: biodeterioration, biofragmentation, and assimilation.[3] Biodeterioration is sometimes described as a surface-level degradation that modifies the mechanical, physical and chemical properties of the material. This stage occurs when the material is exposed to abiotic factors in the outdoor environment and allows for further degradation by weakening the material's structure. Some abiotic factors that influence these initial changes are compression (mechanical), light, temperature and chemicals in the environment.[3] While biodeterioration typically occurs as the first stage of biodegradation, it can in some cases be parallel to biofragmentation.[4] Hueck,[5] however, defined Biodeterioration as the undesirable action of living organisms on Man's materials, involving such things as breakdown of stone facades of buildings,[6] corrosion of metals by microorganisms or merely the esthetic changes induced on man-made structures by the growth of living organisms.[6]

Biofragmentation of a polymer is the lytic process in which bonds within a polymer are cleaved, generating oligomers and monomers in its place.[3] The steps taken to fragment these materials also differ based on the presence of oxygen in the system. The breakdown of materials by microorganisms when oxygen is present is aerobic digestion, and the breakdown of materials when oxygen is not present is anaerobic digestion.[7] The main difference between these processes is that anaerobic reactions produce methane, while aerobic reactions do not (however, both reactions produce carbon dioxide, water, some type of residue, and a new biomass).[8] In addition, aerobic digestion typically occurs more rapidly than anaerobic digestion, while anaerobic digestion does a better job reducing the volume and mass of the material.[7] Due to anaerobic digestion's ability to reduce the volume and mass of waste materials and produce a natural gas, anaerobic digestion technology is widely used for waste management systems and as a source of local, renewable energy.[9]

In the assimilation stage, the resulting products from biofragmentation are then integrated into microbial cells.[3] Some of the products from fragmentation are easily transported within the cell by membrane carriers. However, others still have to undergo biotransformation reactions to yield products that can then be transported inside the cell. Once inside the cell, the products enter catabolic pathways that either lead to the production of adenosine triphosphate (ATP) or elements of the cells structure.[3]

 
Aerobic biodegradation formula
 
Anaerobic degradation formula

Factors affecting biodegradation rate

 
Average estimated decomposition times of typical marine debris items. Plastic items are shown in blue.

In practice, almost all chemical compounds and materials are subject to biodegradation processes. The significance, however, is in the relative rates of such processes, such as days, weeks, years or centuries. A number of factors determine the rate at which this degradation of organic compounds occurs. Factors include light, water, oxygen and temperature.[10] The degradation rate of many organic compounds is limited by their bioavailability, which is the rate at which a substance is absorbed into a system or made available at the site of physiological activity,[11] as compounds must be released into solution before organisms can degrade them. The rate of biodegradation can be measured in a number of ways. Respirometry tests can be used for aerobic microbes. First one places a solid waste sample in a container with microorganisms and soil, and then aerates the mixture. Over the course of several days, microorganisms digest the sample bit by bit and produce carbon dioxide – the resulting amount of CO2 serves as an indicator of degradation. Biodegradability can also be measured by anaerobic microbes and the amount of methane or alloy that they are able to produce.[12]

It's important to note factors that affect biodegradation rates during product testing to ensure that the results produced are accurate and reliable. Several materials will test as being biodegradable under optimal conditions in a lab for approval but these results may not reflect real world outcomes where factors are more variable.[13] For example, a material may have tested as biodegrading at a high rate in the lab may not degrade at a high rate in a landfill because landfills often lack light, water, and microbial activity that are necessary for degradation to occur.[14] Thus, it is very important that there are standards for plastic biodegradable products, which have a large impact on the environment. The development and use of accurate standard test methods can help ensure that all plastics that are being produced and commercialized will actually biodegrade in natural environments.[15] One test that has been developed for this purpose is DINV 54900.[16]

Approximated time for compounds to biodegrade in a marine environment[17]
Product Time to Biodegrade
Paper towel 2–4 weeks
Newspaper 6 weeks
Apple core 2 months
Cardboard box 2 months
Wax coated milk carton 3 months
Cotton gloves 1–5 months
Wool gloves 1 year
Plywood 1–3 years
Painted wooden sticks 13 years
Plastic bags 10–20 years
Tin cans 50 years
Disposable diapers 50–100 years
Plastic bottle 100 years
Aluminium cans 200 years
Glass bottles Undetermined
Time-frame for common items to break down in a terrestrial environment[14]
Vegetables 5 days – 1 month
Paper 2–5 months
Cotton T-shirt 6 months
Orange peels 6 months
Tree leaves 1 year
Wool socks 1–5 years
Plastic-coated paper milk cartons 5 years
Leather shoes 25–40 years
Nylon fabric 30–40 years
Tin cans 50–100 years
Aluminium cans 80–100 years
Glass bottles 1 million years
Styrofoam cup 500 years to forever
Plastic bags 500 years to forever

Plastics

Main article: Biodegradable plastic § Examples of biodegradable plastics

The term Biodegradable Plastics refers to materials that maintain their mechanical strength during practical use but break down into low-weight compounds and non-toxic byproducts after their use.[18] This breakdown is made possible through an attack of microorganisms on the material, which is typically a non-water-soluble polymer.[4] Such materials can be obtained through chemical synthesis, fermentation by microorganisms, and from chemically modified natural products.[19]

Plastics biodegrade at highly variable rates. PVC-based plumbing is selected for handling sewage because PVC resists biodegradation. Some packaging materials on the other hand are being developed that would degrade readily upon exposure to the environment.[20] Examples of synthetic polymers that biodegrade quickly include polycaprolactone, other polyesters and aromatic-aliphatic esters, due to their ester bonds being susceptible to attack by water. A prominent example is poly-3-hydroxybutyrate, the renewably derived polylactic acid. Others are the cellulose-based cellulose acetate and celluloid (cellulose nitrate).

 
Polylactic acid is an example of a plastic that biodegrades quickly.

Under low oxygen conditions plastics break down more slowly. The breakdown process can be accelerated in specially designed compost heap. Starch-based plastics will degrade within two to four months in a home compost bin, while polylactic acid is largely undecomposed, requiring higher temperatures.[21] Polycaprolactone and polycaprolactone-starch composites decompose slower, but the starch content accelerates decomposition by leaving behind a porous, high surface area polycaprolactone. Nevertheless, it takes many months.[22]

In 2016, a bacterium named Ideonella sakaiensis was found to biodegrade PET. In 2020, the PET degrading enzyme of the bacterium, PETase, has been genetically modified and combined with MHETase to break down PET faster, and also degrade PEF.[23][24][25] In 2021, researchers reported that a mix of microorganisms from cow stomachs could break down three types of plastics.[26][27]

Many plastic producers have gone so far even to say that their plastics are compostable, typically listing corn starch as an ingredient. However, these claims are questionable because the plastics industry operates under its own definition of compostable:

"that which is capable of undergoing biological decomposition in a compost site such that the material is not visually distinguishable and breaks down into carbon dioxide, water, inorganic compounds and biomass at a rate consistent with known compostable materials." (Ref: ASTM D 6002)[28]

The term "composting" is often used informally to describe the biodegradation of packaging materials. Legal definitions exist for compostability, the process that leads to compost. Four criteria are offered by the European Union:[29][30]

  1. Chemical composition: volatile matter and heavy metals as well as fluorine should be limited.
  2. Biodegradability: the conversion of >90% of the original material into CO2, water and minerals by biological processes within 6 months.
  3. Disintegrability: at least 90% of the original mass should be decomposed into particles that are able to pass through a 2x2 mm sieve.
  4. Quality: absence of toxic substances and other substances that impede composting.

Biodegradable technology

Biodegradable technology is established technology with some applications in product packaging, production, and medicine.[31] The chief barrier to widespread implementation is the trade-off between biodegradability and performance. For example, lactide-based plastics are inferior packaging properties in comparison to traditional materials.

Oxo-biodegradation is defined by CEN (the European Standards Organisation) as "degradation resulting from oxidative and cell-mediated phenomena, either simultaneously or successively." While sometimes described as "oxo-fragmentable," and "oxo-degradable" these terms describe only the first or oxidative phase and should not be used for material which degrades by the process of oxo-biodegradation defined by CEN: the correct description is "oxo-biodegradable." Oxo-biodegradable formulations accelerate the biodegradation process but it takes considerable skill and experience to balance the ingredients within the formulations so as to provide the product with a useful life for a set period, followed by degradation and biodegradation.[32]

Biodegradable technology is especially utilized by the bio-medical community. Biodegradable polymers are classified into three groups: medical, ecological, and dual application, while in terms of origin they are divided into two groups: natural and synthetic.[18] The Clean Technology Group is exploiting the use of supercritical carbon dioxide, which under high pressure at room temperature is a solvent that can use biodegradable plastics to make polymer drug coatings. The polymer (meaning a material composed of molecules with repeating structural units that form a long chain) is used to encapsulate a drug prior to injection in the body and is based on lactic acid, a compound normally produced in the body, and is thus able to be excreted naturally. The coating is designed for controlled release over a period of time, reducing the number of injections required and maximizing the therapeutic benefit. Professor Steve Howdle states that biodegradable polymers are particularly attractive for use in drug delivery, as once introduced into the body they require no retrieval or further manipulation and are degraded into soluble, non-toxic by-products. Different polymers degrade at different rates within the body and therefore polymer selection can be tailored to achieve desired release rates.[33]

Other biomedical applications include the use of biodegradable, elastic shape-memory polymers. Biodegradable implant materials can now be used for minimally invasive surgical procedures through degradable thermoplastic polymers. These polymers are now able to change their shape with increase of temperature, causing shape memory capabilities as well as easily degradable sutures. As a result, implants can now fit through small incisions, doctors can easily perform complex deformations, and sutures and other material aides can naturally biodegrade after a completed surgery.[34]

Biodegradation vs. composting

There is no universal definition for biodegradation and there are various definitions of composting, which has led to much confusion between the terms. They are often lumped together; however, they do not have the same meaning. Biodegradation is the naturally-occurring breakdown of materials by microorganisms such as bacteria and fungi or other biological activity.[35] Composting is a human-driven process in which biodegradation occurs under a specific set of circumstances.[36] The predominant difference between the two is that one process is naturally-occurring and one is human-driven.

Biodegradable material is capable of decomposing without an oxygen source (anaerobically) into carbon dioxide, water, and biomass, but the timeline is not very specifically defined. Similarly, compostable material breaks down into carbon dioxide, water, and biomass; however, compostable material also breaks down into inorganic compounds. The process for composting is more specifically defined, as it is controlled by humans. Essentially, composting is an accelerated biodegradation process due to optimized circumstances.[37] Additionally, the end product of composting not only returns to its previous state, but also generates and adds beneficial microorganisms to the soil called humus. This organic matter can be used in gardens and on farms to help grow healthier plants in the future.[38] Composting more consistently occurs within a shorter time frame since it is a more defined process and is expedited by human intervention. Biodegradation can occur in different time frames under different circumstances, but is meant to occur naturally without human intervention.

 
This figure represents the different paths of disposal for organic waste.[39]

Even within composting, there are different circumstances under which this can occur. The two main types of composting are at-home versus commercial. Both produce healthy soil to be reused - the main difference lies in what materials are able to go into the process.[37] At-home composting is mostly used for food scraps and excess garden materials, such as weeds. Commercial composting is capable of breaking down more complex plant-based products, such as corn-based plastics and larger pieces of material, like tree branches. Commercial composting begins with a manual breakdown of the materials using a grinder or other machine to initiate the process. Because at-home composting usually occurs on a smaller scale and does not involve large machinery, these materials would not fully decompose in at-home composting. Furthermore, one study has compared and contrasted home and industrial composting, concluding that there are advantages and disadvantages to both.[40]

The following studies provide examples in which composting has been defined as a subset of biodegradation in a scientific context. The first study, "Assessment of Biodegradability of Plastics Under Simulated Composting Conditions in a Laboratory Test Setting," clearly examines composting as a set of circumstances that falls under the category of degradation.[41] Additionally, this next study looked at the biodegradation and composting effects of chemically and physically crosslinked polylactic acid.[42] Notably discussing composting and biodegrading as two distinct terms. The third and final study reviews European standardization of biodegradable and compostable material in the packaging industry, again using the terms separately.[43]

The distinction between these terms is crucial because waste management confusion leads to improper disposal of materials by people on a daily basis. Biodegradation technology has led to massive improvements in how we dispose of waste; there now exist trash, recycling, and compost bins in order to optimize the disposal process. However, if these waste streams are commonly and frequently confused, then the disposal process is not at all optimized.[44] Biodegradable and compostable materials have been developed to ensure more of human waste is able to breakdown and return to its previous state, or in the case of composting even add nutrients to the ground.[45] When a compostable product is thrown out as opposed to composted and sent to a landfill, these inventions and efforts are wasted. Therefore, it is important for citizens to understand the difference between these terms so that materials can be disposed of properly and efficiently.

Environmental and social effects

Plastic pollution from illegal dumping poses health risks to wildlife. Animals often mistake plastics for food, resulting in intestinal entanglement. Slow-degrading chemicals, like polychlorinated biphenyls (PCBs), nonylphenol (NP), and pesticides also found in plastics, can release into environments and subsequently also be ingested by wildlife.[46]

These chemicals also play a role in human health, as consumption of tainted food (in processes called biomagnification and bioaccumulation) has been linked to issues such as cancers,[47] neurological dysfunction,[48] and hormonal changes. A well-known example of biomagnification impacting health in recent times is the increased exposure to dangerously high levels of mercury in fish, which can affect sex hormones in humans.[49]

In efforts to remediate the damages done by slow-degrading plastics, detergents, metals, and other pollutants created by humans, economic costs have become a concern. Marine litter in particular is notably difficult to quantify and review.[50] Researchers at the World Trade Institute estimate that cleanup initiatives' cost (specifically in ocean ecosystems) has hit close to thirteen billion dollars a year.[51] The main concern stems from marine environments, with the biggest cleanup efforts centering around garbage patches in the ocean. In 2017, a garbage patch the size of Mexico was found in the Pacific Ocean. It is estimated to be upwards of a million square miles in size. While the patch contains more obvious examples of litter (plastic bottles, cans, and bags), tiny microplastics are nearly impossible to clean up.[52] National Geographic reports that even more non-biodegradable materials are finding their way into vulnerable environments - nearly thirty-eight million pieces a year.[53]

Materials that have not degraded can also serve as shelter for invasive species, such as tube worms and barnacles. When the ecosystem changes in response to the invasive species, resident species and the natural balance of resources, genetic diversity, and species richness is altered.[54] These factors may support local economies in way of hunting and aquaculture, which suffer in response to the change.[55] Similarly, coastal communities which rely heavily on ecotourism lose revenue thanks to a buildup of pollution, as their beaches or shores are no longer desirable to travelers. The World Trade Institute also notes that the communities who often feel most of the effects of poor biodegradation are poorer countries without the means to pay for their cleanup.[51] In a positive feedback loop effect, they in turn have trouble controlling their own pollution sources.[56]

Etymology of "biodegradable"

The first known use of biodegradable in a biological context was in 1959 when it was employed to describe the breakdown of material into innocuous components by microorganisms.[57] Now biodegradable is commonly associated with environmentally friendly products that are part of the earth's innate cycles like the carbon cycle and capable of decomposing back into natural elements.

See also

Notes

  1. ^ The IUPAC defines biodegradation as "degradation caused by enzymatic process resulting from the action of cells" and notes that the definition is "modified to exclude abiotic enzymatic processes."[1]

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  54. ^ Gregory MR (July 2009). "Environmental implications of plastic debris in marine settings--entanglement, ingestion, smothering, hangers-on, hitch-hiking and alien invasions". Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences. 364 (1526): 2013–25. doi:10.1098/rstb.2008.0265. PMC 2873013. PMID 19528053.
  55. ^ Villarrubia-Gómez P, Cornell SE, Fabres J (2018-10-01). "Marine plastic pollution as a planetary boundary threat – The drifting piece in the sustainability puzzle". Marine Policy. 96: 213–220. doi:10.1016/j.marpol.2017.11.035.
  56. ^ Hajat A, Hsia C, O'Neill MS (December 2015). "Socioeconomic Disparities and Air Pollution Exposure: a Global Review". Current Environmental Health Reports. 2 (4): 440–50. doi:10.1007/s40572-015-0069-5. PMC 4626327. PMID 26381684.
  57. ^ "Definition of BIODEGRADABLE". www.merriam-webster.com. Retrieved 2018-09-24.

Standards by ASTM International

  • D5210- Standard Test Method for Determining the Anaerobic Biodegradation of Plastic Materials in the Presence of Municipal Sewage Sludge
  • D5526- Standard Test Method for Determining Anaerobic Biodegradation of Plastic Materials Under Accelerated Landfill Conditions
  • D5338- Standard Test Method for Determining Aerobic Biodegradation of Plastic Materials Under Controlled Composting Conditions, Incorporating Thermophilic Temperatures
  • D5511- Standard Test Method for Determining Anaerobic Biodegradation of Plastic Materials Under High-Solids Anaerobic-Digestion Conditions
  • D5864- Standard Test Method for Determining Aerobic Aquatic Biodegradation of Lubricants or Their Components
  • D5988- Standard Test Method for Determining Aerobic Biodegradation of Plastic Materials in Soil
  • D6139- Standard Test Method for Determining the Aerobic Aquatic Biodegradation of Lubricants or Their Components Using the Gledhill Shake Flask
  • D6006- Standard Guide for Assessing Biodegradability of Hydraulic Fluids
  • D6340- Standard Test Methods for Determining Aerobic Biodegradation of Radiolabeled Plastic Materials in an Aqueous or Compost Environment
  • D6691- Standard Test Method for Determining Aerobic Biodegradation of Plastic Materials in the Marine Environment by a Defined Microbial Consortium or Natural Sea Water Inoculum
  • D6731-Standard Test Method for Determining the Aerobic, Aquatic Biodegradability of Lubricants or Lubricant Components in a Closed Respirometer
  • D6954- Standard Guide for Exposing and Testing Plastics that Degrade in the Environment by a Combination of Oxidation and Biodegradation
  • D7044- Standard Specification for Biodegradable Fire Resistant Hydraulic Fluids
  • D7373-Standard Test Method for Predicting Biodegradability of Lubricants Using a Bio-kinetic Model
  • D7475- Standard Test Method for Determining the Aerobic Degradation and Anaerobic Biodegradation of Plastic Materials under Accelerated Bioreactor Landfill Conditions
  • D7665- Standard Guide for Evaluation of Biodegradable Heat Transfer Fluids

External links

  • European Bioplastics Association
  • Biodegradable Plastic Definition

April 16, 2023
biodegradation, journal, journal, breakdown, organic, matter, microorganisms, such, bacteria, fungi, generally, assumed, natural, process, which, differentiates, from, composting, composting, human, driven, process, which, biodegradation, occurs, under, specif. For the journal see Biodegradation journal Biodegradation is the breakdown of organic matter by microorganisms such as bacteria and fungi a 2 It is generally assumed to be a natural process which differentiates it from composting Composting is a human driven process in which biodegradation occurs under a specific set of circumstances Yellow slime mold growing on a bin of wet paper The process of biodegradation is threefold first an object undergoes biodeterioration which is the mechanical weakening of its structure then follows biofragmentation which is the breakdown of materials by microorganisms and finally assimilation which is the incorporation of the old material into new cells In practice almost all chemical compounds and materials are subject to biodegradation the key element being time Things like vegetables may degrade within days while glass and some plastics take many millennia to decompose A standard for biodegradability used by the European Union is that greater than 90 of the original material must be converted into CO2 water and minerals by biological processes within 6 months Contents 1 Mechanisms 2 Factors affecting biodegradation rate 3 Plastics 4 Biodegradable technology 5 Biodegradation vs composting 6 Environmental and social effects 7 Etymology of biodegradable 8 See also 9 Notes 10 References 10 1 Standards by ASTM International 11 External linksMechanisms EditThe process of biodegradation can be divided into three stages biodeterioration biofragmentation and assimilation 3 Biodeterioration is sometimes described as a surface level degradation that modifies the mechanical physical and chemical properties of the material This stage occurs when the material is exposed to abiotic factors in the outdoor environment and allows for further degradation by weakening the material s structure Some abiotic factors that influence these initial changes are compression mechanical light temperature and chemicals in the environment 3 While biodeterioration typically occurs as the first stage of biodegradation it can in some cases be parallel to biofragmentation 4 Hueck 5 however defined Biodeterioration as the undesirable action of living organisms on Man s materials involving such things as breakdown of stone facades of buildings 6 corrosion of metals by microorganisms or merely the esthetic changes induced on man made structures by the growth of living organisms 6 Biofragmentation of a polymer is the lytic process in which bonds within a polymer are cleaved generating oligomers and monomers in its place 3 The steps taken to fragment these materials also differ based on the presence of oxygen in the system The breakdown of materials by microorganisms when oxygen is present is aerobic digestion and the breakdown of materials when oxygen is not present is anaerobic digestion 7 The main difference between these processes is that anaerobic reactions produce methane while aerobic reactions do not however both reactions produce carbon dioxide water some type of residue and a new biomass 8 In addition aerobic digestion typically occurs more rapidly than anaerobic digestion while anaerobic digestion does a better job reducing the volume and mass of the material 7 Due to anaerobic digestion s ability to reduce the volume and mass of waste materials and produce a natural gas anaerobic digestion technology is widely used for waste management systems and as a source of local renewable energy 9 In the assimilation stage the resulting products from biofragmentation are then integrated into microbial cells 3 Some of the products from fragmentation are easily transported within the cell by membrane carriers However others still have to undergo biotransformation reactions to yield products that can then be transported inside the cell Once inside the cell the products enter catabolic pathways that either lead to the production of adenosine triphosphate ATP or elements of the cells structure 3 Aerobic biodegradation formula Anaerobic degradation formulaFactors affecting biodegradation rate Edit Average estimated decomposition times of typical marine debris items Plastic items are shown in blue In practice almost all chemical compounds and materials are subject to biodegradation processes The significance however is in the relative rates of such processes such as days weeks years or centuries A number of factors determine the rate at which this degradation of organic compounds occurs Factors include light water oxygen and temperature 10 The degradation rate of many organic compounds is limited by their bioavailability which is the rate at which a substance is absorbed into a system or made available at the site of physiological activity 11 as compounds must be released into solution before organisms can degrade them The rate of biodegradation can be measured in a number of ways Respirometry tests can be used for aerobic microbes First one places a solid waste sample in a container with microorganisms and soil and then aerates the mixture Over the course of several days microorganisms digest the sample bit by bit and produce carbon dioxide the resulting amount of CO2 serves as an indicator of degradation Biodegradability can also be measured by anaerobic microbes and the amount of methane or alloy that they are able to produce 12 It s important to note factors that affect biodegradation rates during product testing to ensure that the results produced are accurate and reliable Several materials will test as being biodegradable under optimal conditions in a lab for approval but these results may not reflect real world outcomes where factors are more variable 13 For example a material may have tested as biodegrading at a high rate in the lab may not degrade at a high rate in a landfill because landfills often lack light water and microbial activity that are necessary for degradation to occur 14 Thus it is very important that there are standards for plastic biodegradable products which have a large impact on the environment The development and use of accurate standard test methods can help ensure that all plastics that are being produced and commercialized will actually biodegrade in natural environments 15 One test that has been developed for this purpose is DINV 54900 16 Approximated time for compounds to biodegrade in a marine environment 17 Product Time to BiodegradePaper towel 2 4 weeksNewspaper 6 weeksApple core 2 monthsCardboard box 2 monthsWax coated milk carton 3 monthsCotton gloves 1 5 monthsWool gloves 1 yearPlywood 1 3 yearsPainted wooden sticks 13 yearsPlastic bags 10 20 yearsTin cans 50 yearsDisposable diapers 50 100 yearsPlastic bottle 100 yearsAluminium cans 200 yearsGlass bottles UndeterminedTime frame for common items to break down in a terrestrial environment 14 Vegetables 5 days 1 monthPaper 2 5 monthsCotton T shirt 6 monthsOrange peels 6 monthsTree leaves 1 yearWool socks 1 5 yearsPlastic coated paper milk cartons 5 yearsLeather shoes 25 40 yearsNylon fabric 30 40 yearsTin cans 50 100 yearsAluminium cans 80 100 yearsGlass bottles 1 million yearsStyrofoam cup 500 years to foreverPlastic bags 500 years to foreverPlastics EditMain article Biodegradable plastic Examples of biodegradable plastics The term Biodegradable Plastics refers to materials that maintain their mechanical strength during practical use but break down into low weight compounds and non toxic byproducts after their use 18 This breakdown is made possible through an attack of microorganisms on the material which is typically a non water soluble polymer 4 Such materials can be obtained through chemical synthesis fermentation by microorganisms and from chemically modified natural products 19 Plastics biodegrade at highly variable rates PVC based plumbing is selected for handling sewage because PVC resists biodegradation Some packaging materials on the other hand are being developed that would degrade readily upon exposure to the environment 20 Examples of synthetic polymers that biodegrade quickly include polycaprolactone other polyesters and aromatic aliphatic esters due to their ester bonds being susceptible to attack by water A prominent example is poly 3 hydroxybutyrate the renewably derived polylactic acid Others are the cellulose based cellulose acetate and celluloid cellulose nitrate Polylactic acid is an example of a plastic that biodegrades quickly Under low oxygen conditions plastics break down more slowly The breakdown process can be accelerated in specially designed compost heap Starch based plastics will degrade within two to four months in a home compost bin while polylactic acid is largely undecomposed requiring higher temperatures 21 Polycaprolactone and polycaprolactone starch composites decompose slower but the starch content accelerates decomposition by leaving behind a porous high surface area polycaprolactone Nevertheless it takes many months 22 In 2016 a bacterium named Ideonella sakaiensis was found to biodegrade PET In 2020 the PET degrading enzyme of the bacterium PETase has been genetically modified and combined with MHETase to break down PET faster and also degrade PEF 23 24 25 In 2021 researchers reported that a mix of microorganisms from cow stomachs could break down three types of plastics 26 27 Many plastic producers have gone so far even to say that their plastics are compostable typically listing corn starch as an ingredient However these claims are questionable because the plastics industry operates under its own definition of compostable that which is capable of undergoing biological decomposition in a compost site such that the material is not visually distinguishable and breaks down into carbon dioxide water inorganic compounds and biomass at a rate consistent with known compostable materials Ref ASTM D 6002 28 The term composting is often used informally to describe the biodegradation of packaging materials Legal definitions exist for compostability the process that leads to compost Four criteria are offered by the European Union 29 30 Chemical composition volatile matter and heavy metals as well as fluorine should be limited Biodegradability the conversion of gt 90 of the original material into CO2 water and minerals by biological processes within 6 months Disintegrability at least 90 of the original mass should be decomposed into particles that are able to pass through a 2x2 mm sieve Quality absence of toxic substances and other substances that impede composting Biodegradable technology EditBiodegradable technology is established technology with some applications in product packaging production and medicine 31 The chief barrier to widespread implementation is the trade off between biodegradability and performance For example lactide based plastics are inferior packaging properties in comparison to traditional materials Oxo biodegradation is defined by CEN the European Standards Organisation as degradation resulting from oxidative and cell mediated phenomena either simultaneously or successively While sometimes described as oxo fragmentable and oxo degradable these terms describe only the first or oxidative phase and should not be used for material which degrades by the process of oxo biodegradation defined by CEN the correct description is oxo biodegradable Oxo biodegradable formulations accelerate the biodegradation process but it takes considerable skill and experience to balance the ingredients within the formulations so as to provide the product with a useful life for a set period followed by degradation and biodegradation 32 Biodegradable technology is especially utilized by the bio medical community Biodegradable polymers are classified into three groups medical ecological and dual application while in terms of origin they are divided into two groups natural and synthetic 18 The Clean Technology Group is exploiting the use of supercritical carbon dioxide which under high pressure at room temperature is a solvent that can use biodegradable plastics to make polymer drug coatings The polymer meaning a material composed of molecules with repeating structural units that form a long chain is used to encapsulate a drug prior to injection in the body and is based on lactic acid a compound normally produced in the body and is thus able to be excreted naturally The coating is designed for controlled release over a period of time reducing the number of injections required and maximizing the therapeutic benefit Professor Steve Howdle states that biodegradable polymers are particularly attractive for use in drug delivery as once introduced into the body they require no retrieval or further manipulation and are degraded into soluble non toxic by products Different polymers degrade at different rates within the body and therefore polymer selection can be tailored to achieve desired release rates 33 Other biomedical applications include the use of biodegradable elastic shape memory polymers Biodegradable implant materials can now be used for minimally invasive surgical procedures through degradable thermoplastic polymers These polymers are now able to change their shape with increase of temperature causing shape memory capabilities as well as easily degradable sutures As a result implants can now fit through small incisions doctors can easily perform complex deformations and sutures and other material aides can naturally biodegrade after a completed surgery 34 Biodegradation vs composting EditThere is no universal definition for biodegradation and there are various definitions of composting which has led to much confusion between the terms They are often lumped together however they do not have the same meaning Biodegradation is the naturally occurring breakdown of materials by microorganisms such as bacteria and fungi or other biological activity 35 Composting is a human driven process in which biodegradation occurs under a specific set of circumstances 36 The predominant difference between the two is that one process is naturally occurring and one is human driven Biodegradable material is capable of decomposing without an oxygen source anaerobically into carbon dioxide water and biomass but the timeline is not very specifically defined Similarly compostable material breaks down into carbon dioxide water and biomass however compostable material also breaks down into inorganic compounds The process for composting is more specifically defined as it is controlled by humans Essentially composting is an accelerated biodegradation process due to optimized circumstances 37 Additionally the end product of composting not only returns to its previous state but also generates and adds beneficial microorganisms to the soil called humus This organic matter can be used in gardens and on farms to help grow healthier plants in the future 38 Composting more consistently occurs within a shorter time frame since it is a more defined process and is expedited by human intervention Biodegradation can occur in different time frames under different circumstances but is meant to occur naturally without human intervention This figure represents the different paths of disposal for organic waste 39 Even within composting there are different circumstances under which this can occur The two main types of composting are at home versus commercial Both produce healthy soil to be reused the main difference lies in what materials are able to go into the process 37 At home composting is mostly used for food scraps and excess garden materials such as weeds Commercial composting is capable of breaking down more complex plant based products such as corn based plastics and larger pieces of material like tree branches Commercial composting begins with a manual breakdown of the materials using a grinder or other machine to initiate the process Because at home composting usually occurs on a smaller scale and does not involve large machinery these materials would not fully decompose in at home composting Furthermore one study has compared and contrasted home and industrial composting concluding that there are advantages and disadvantages to both 40 The following studies provide examples in which composting has been defined as a subset of biodegradation in a scientific context The first study Assessment of Biodegradability of Plastics Under Simulated Composting Conditions in a Laboratory Test Setting clearly examines composting as a set of circumstances that falls under the category of degradation 41 Additionally this next study looked at the biodegradation and composting effects of chemically and physically crosslinked polylactic acid 42 Notably discussing composting and biodegrading as two distinct terms The third and final study reviews European standardization of biodegradable and compostable material in the packaging industry again using the terms separately 43 The distinction between these terms is crucial because waste management confusion leads to improper disposal of materials by people on a daily basis Biodegradation technology has led to massive improvements in how we dispose of waste there now exist trash recycling and compost bins in order to optimize the disposal process However if these waste streams are commonly and frequently confused then the disposal process is not at all optimized 44 Biodegradable and compostable materials have been developed to ensure more of human waste is able to breakdown and return to its previous state or in the case of composting even add nutrients to the ground 45 When a compostable product is thrown out as opposed to composted and sent to a landfill these inventions and efforts are wasted Therefore it is important for citizens to understand the difference between these terms so that materials can be disposed of properly and efficiently Environmental and social effects EditPlastic pollution from illegal dumping poses health risks to wildlife Animals often mistake plastics for food resulting in intestinal entanglement Slow degrading chemicals like polychlorinated biphenyls PCBs nonylphenol NP and pesticides also found in plastics can release into environments and subsequently also be ingested by wildlife 46 These chemicals also play a role in human health as consumption of tainted food in processes called biomagnification and bioaccumulation has been linked to issues such as cancers 47 neurological dysfunction 48 and hormonal changes A well known example of biomagnification impacting health in recent times is the increased exposure to dangerously high levels of mercury in fish which can affect sex hormones in humans 49 In efforts to remediate the damages done by slow degrading plastics detergents metals and other pollutants created by humans economic costs have become a concern Marine litter in particular is notably difficult to quantify and review 50 Researchers at the World Trade Institute estimate that cleanup initiatives cost specifically in ocean ecosystems has hit close to thirteen billion dollars a year 51 The main concern stems from marine environments with the biggest cleanup efforts centering around garbage patches in the ocean In 2017 a garbage patch the size of Mexico was found in the Pacific Ocean It is estimated to be upwards of a million square miles in size While the patch contains more obvious examples of litter plastic bottles cans and bags tiny microplastics are nearly impossible to clean up 52 National Geographic reports that even more non biodegradable materials are finding their way into vulnerable environments nearly thirty eight million pieces a year 53 Materials that have not degraded can also serve as shelter for invasive species such as tube worms and barnacles When the ecosystem changes in response to the invasive species resident species and the natural balance of resources genetic diversity and species richness is altered 54 These factors may support local economies in way of hunting and aquaculture which suffer in response to the change 55 Similarly coastal communities which rely heavily on ecotourism lose revenue thanks to a buildup of pollution as their beaches or shores are no longer desirable to travelers The World Trade Institute also notes that the communities who often feel most of the effects of poor biodegradation are poorer countries without the means to pay for their cleanup 51 In a positive feedback loop effect they in turn have trouble controlling their own pollution sources 56 Etymology of biodegradable EditThe first known use of biodegradable in a biological context was in 1959 when it was employed to describe the breakdown of material into innocuous components by microorganisms 57 Now biodegradable is commonly associated with environmentally friendly products that are part of the earth s innate cycles like the carbon cycle and capable of decomposing back into natural elements See also Edit Ecology portal Environment portalAnaerobic digestion Assimilation biology Bioaccumulation Biodegradability prediction Biodegradable electronics Biodegradable polythene film Biodegradation journal Biomagnification Bioplastic biodegradable bio based plastics Bioremediation Decomposition reduction of the body of a formerly living organism into simpler forms of matter Landfill gas monitoring List of environment topics Microbial biodegradation PhotodegradationNotes Edit The IUPAC defines biodegradation as degradation caused by enzymatic process resulting from the action of cells and notes that the definition is modified to exclude abiotic enzymatic processes 1 References Edit Vert M Doi Y Hellwich KH Hess M Hodge P Kubisa P Rinaudo M Schue F 2012 Terminology for biorelated polymers and applications IUPAC Recommendations 2012 Pure and Applied Chemistry 84 2 377 410 doi 10 1351 PAC REC 10 12 04 S2CID 98107080 Focht DD Biodegradation AccessScience doi 10 1036 1097 8542 422025 a b c d e Lucas N Bienaime C Belloy C Queneudec M Silvestre F Nava Saucedo JE September 2008 Polymer biodegradation mechanisms and estimation techniques Chemosphere 73 4 429 42 Bibcode 2008Chmsp 73 429L doi 10 1016 j chemosphere 2008 06 064 PMID 18723204 a b Muller R 2005 Biodegradability of Polymers Regulations and Methods for Testing PDF In Steinbuchel A ed Biopolymers Wiley VCH doi 10 1002 3527600035 bpola012 ISBN 978 3 527 30290 1 Archived from the original PDF on 2018 09 19 Retrieved 2018 09 19 Hueck Hans January 1966 The biodeterioration of materials as part of hylobiology Material und Organismen 1 5 34 via ISSN 00255270 a b Allsopp Dennis 2004 Introduction to Biodeterioration Cambridge Cambridge University Press ISBN 9780511617065 a b Aerobic and Anaerobic Biodegradation PDF Fundamentals of Aerobic amp Anaerobic Biodegradation Process Polimernet Plastik San Tic Ltd Sti Archived PDF from the original on 2011 04 19 Van der Zee M 2011 Analytical Methods for Monitoring Biodegradation Processes of Environmentally Degradable Polymers Klinkner BA 2014 Anaerobic Digestion as a Renewable Energy Source and Waste Management Technology What Must be Done for this Technology to Realize Success in the United States University of Massachusetts Law Review 9 68 96 Haider T Volker C Kramm J Landfester K Wurm FR July 2018 Plastics of the future The impact of biodegradable polymers on the environment and on society Angewandte Chemie International Edition in English 58 1 50 62 doi 10 1002 anie 201805766 PMID 29972726 Definition of BIOAVAILABILITY www merriam webster com Retrieved 2018 09 19 Jessop A 2015 09 16 How is biodegradability measured Commercial Waste Retrieved 2018 09 19 Adamcova D Radziemska M Fronczyk J Zloch J Vaverkova MD 2017 Research of the biodegradability of degradable biodegradable plastic material in various types of environments Przeglad Naukowy Inzynieria i Ksztaltowanie Srodowiska 26 3 14 doi 10 22630 PNIKS 2017 26 1 01 a b Measuring biodegradability Science Learning Hub Retrieved 2018 09 19 Scott G Gilead D eds 1995 Degradable Polymers Netherlands Dordrecht Springer doi 10 1007 978 94 011 0571 2 ISBN 978 94 010 4253 6 Witt U Yamamoto M Seeliger U Muller RJ Warzelhan V May 1999 Biodegradable Polymeric Materials Not the Origin but the Chemical Structure Determines Biodegradability Angewandte Chemie 38 10 1438 1442 doi 10 1002 sici 1521 3773 19990517 38 10 lt 1438 aid anie1438 gt 3 0 co 2 u PMID 29711570 Marine Debris Biodegradation Time Line Archived 2011 11 05 at the Wayback Machine C MORE citing Mote Marine Laboratory 1993 a b Ikada Y Tsuji H February 2000 Biodegradable polyesters for medical and ecological applications PDF Macromolecular Rapid Communications 21 3 117 132 doi 10 1002 sici 1521 3927 20000201 21 3 lt 117 aid marc117 gt 3 0 co 2 x Flieger M Kantorova M Prell A Rezanka T Votruba J January 2003 Biodegradable plastics from renewable sources Folia Microbiologica 48 1 27 44 doi 10 1007 bf02931273 PMID 12744074 S2CID 32800851 Kyrikou I Briassoulis D 12 Apr 2007 Biodegradation of Agricultural Plastic Films A Critical Review Journal of Polymers and the Environment 15 2 125 150 doi 10 1007 s10924 007 0053 8 S2CID 195331133 Section 6 Biodegradability of Packaging Waste PDF Www3 imperial ac uk Archived PDF from the original on 2013 06 02 Retrieved 2014 03 02 Wu C January 2003 Physical properties and biodegradability of maleated polycaprolactone starch composite PDF Polymer Degradation and Stability 80 1 127 134 CiteSeerX 10 1 1 453 4220 doi 10 1016 S0141 3910 02 00393 2 Carrington Damian 28 September 2020 New super enzyme eats plastic bottles six times faster The Guardian Retrieved 12 October 2020 Plastic eating enzyme cocktail heralds new hope for plastic waste phys org Retrieved 12 October 2020 Knott Brandon C Erickson Erika Allen Mark D Gado Japheth E Graham Rosie Kearns Fiona L Pardo Isabel Topuzlu Ece Anderson Jared J Austin Harry P Dominick Graham Johnson Christopher W Rorrer Nicholas A Szostkiewicz Caralyn J Copie Valerie Payne Christina M Woodcock H Lee Donohoe Bryon S Beckham Gregg T McGeehan John E 24 September 2020 Characterization and engineering of a two enzyme system for plastics depolymerization Proceedings of the National Academy of Sciences 117 41 25476 25485 Bibcode 2020PNAS 11725476K doi 10 1073 pnas 2006753117 ISSN 0027 8424 PMC 7568301 PMID 32989159 Spary Sara Cows stomachs can break down plastic study finds CNN Retrieved 14 August 2021 Quartinello Felice Kremser Klemens Schoen Herta Tesei Donatella Ploszczanski Leon Nagler Magdalena Podmirseg Sabine M Insam Heribert Pinar Guadalupe Sterflingler Katja Ribitsch Doris Guebitz Georg M 2021 Together Is Better The Rumen Microbial Community as Biological Toolbox for Degradation of Synthetic Polyesters Frontiers in Bioengineering and Biotechnology 9 doi 10 3389 fbioe 2021 684459 ISSN 2296 4185 Compostable Compostable info Retrieved 2014 03 02 Requirements of the EN 13432 standard PDF European Bioplastics Brussels Belgium April 2015 Archived PDF from the original on 2018 09 24 Retrieved July 22 2017 Breulmann M Kunkel A Philipp S Reimer V Siegenthaler KO Skupin G Yamamoto M 2012 Polymers Biodegradable Ullmann s Encyclopedia of Industrial Chemistry Weinheim Wiley VCH doi 10 1002 14356007 n21 n01 ISBN 978 3527306732 Gross RA Kalra B August 2002 Biodegradable polymers for the environment Science 297 5582 803 7 Bibcode 2002Sci 297 803G doi 10 1126 science 297 5582 803 PMID 12161646 Agamuthu P Faizura PN April 2005 Biodegradability of degradable plastic waste Waste Management amp Research 23 2 95 100 doi 10 1177 0734242X05051045 PMID 15864950 S2CID 2552973 The University of Nottingham September 13 2007 Using Green Chemistry to Deliver Cutting Edge Drugs Science Daily Lendlein A Langer R May 2002 Biodegradable elastic shape memory polymers for potential biomedical applications Science 296 5573 1673 6 Bibcode 2002Sci 296 1673L doi 10 1126 science 1066102 PMID 11976407 S2CID 21801034 Gomez EF Michel FC December 2013 Biodegradability of conventional and bio based plastics and natural fiber composites during composting anaerobic digestion and long term soil incubation Polymer Degradation and Stability 98 12 2583 2591 doi 10 1016 j polymdegradstab 2013 09 018 Biodegradable Products Institute Composting bpiworld org Retrieved 2018 09 24 a b Magdoff F November 1993 Building Soils for Better Crops Soil Science 156 5 371 Bibcode 1993SoilS 156 371M doi 10 1097 00010694 199311000 00014 Morris S Martin JP Humus AccessScience doi 10 1036 1097 8542 325510 S2CID 242577363 Retrieved 2018 09 24 Kranert M Behnsen A Schultheis A Steinbach D 2002 Composting in the Framework of the EU Landfill Directive Microbiology of Composting Springer Berlin Heidelberg pp 473 486 doi 10 1007 978 3 662 08724 4 39 ISBN 9783642087059 Martinez Blanco J Colon J Gabarrell X Font X Sanchez A Artola A Rieradevall J June 2010 The use of life cycle assessment for the comparison of biowaste composting at home and full scale Waste Management Submitted manuscript 30 6 983 94 doi 10 1016 j wasman 2010 02 023 PMID 20211555 Starnecker A Menner M 1996 01 01 Assessment of biodegradability of plastics under simulated composting conditions in a laboratory test system International Biodeterioration amp Biodegradation 37 1 2 85 92 doi 10 1016 0964 8305 95 00089 5 Zenkiewicz M Malinowski R Rytlewski P Richert A Sikorska W Krasowska K 2012 02 01 Some composting and biodegradation effects of physically or chemically crosslinked poly lactic acid Polymer Testing 31 1 83 92 doi 10 1016 j polymertesting 2011 09 012 Avella M Bonadies E Martuscelli E Rimedio R 2001 01 01 European current standardization for plastic packaging recoverable through composting and biodegradation Polymer Testing 20 5 517 521 doi 10 1016 S0142 9418 00 00068 4 Akullian A Karp C Austin K Durbin D 2006 Plastic Bag Externalities and Policy in Rhode Island PDF Brown Policy Review Song JH Murphy RJ Narayan R Davies GB July 2009 Biodegradable and compostable alternatives to conventional plastics Philosophical Transactions of the Royal Society of London Series B Biological Sciences 364 1526 2127 39 doi 10 1098 rstb 2008 0289 PMC 2873018 PMID 19528060 Webb H Arnott J Crawford R Ivanova E Webb HK Arnott J Crawford RJ Ivanova EP 2012 12 28 Plastic Degradation and Its Environmental Implications with Special Reference to Poly ethylene terephthalate Polymers 5 1 1 18 doi 10 3390 polym5010001 Kelly BC Ikonomou MG Blair JD Morin AE Gobas FA July 2007 Food web specific biomagnification of persistent organic pollutants Science 317 5835 236 9 Bibcode 2007Sci 317 236K doi 10 1126 science 1138275 PMID 17626882 S2CID 52835862 Passos CJ Mergler D 2008 Human mercury exposure and adverse health effects in the Amazon a review Cadernos de Saude Publica 24 Suppl 4 s503 20 doi 10 1590 s0102 311x2008001600004 PMID 18797727 Rana SV July 2014 Perspectives in endocrine toxicity of heavy metals a review Biological Trace Element Research 160 1 1 14 doi 10 1007 s12011 014 0023 7 PMID 24898714 S2CID 18562345 Newman S Watkins E Farmer A Brink Pt Schweitzer J 2015 The Economics of Marine Litter Marine Anthropogenic Litter Springer International Publishing pp 367 394 doi 10 1007 978 3 319 16510 3 14 ISBN 978 3 319 16509 7 a b Matsangou E 2 July 2018 Counting the cost of plastic pollution World Finance Retrieved 17 September 2018 Rochman CM Cook AM Koelmans AA July 2016 Plastic debris and policy Using current scientific understanding to invoke positive change Environmental Toxicology and Chemistry 35 7 1617 26 doi 10 1002 etc 3408 PMID 27331654 Montanari S 2017 07 25 Plastic Garbage Patch Bigger Than Mexico Found in Pacific National Geographic Retrieved 2018 09 17 Gregory MR July 2009 Environmental implications of plastic debris in marine settings entanglement ingestion smothering hangers on hitch hiking and alien invasions Philosophical Transactions of the Royal Society of London Series B Biological Sciences 364 1526 2013 25 doi 10 1098 rstb 2008 0265 PMC 2873013 PMID 19528053 Villarrubia Gomez P Cornell SE Fabres J 2018 10 01 Marine plastic pollution as a planetary boundary threat The drifting piece in the sustainability puzzle Marine Policy 96 213 220 doi 10 1016 j marpol 2017 11 035 Hajat A Hsia C O Neill MS December 2015 Socioeconomic Disparities and Air Pollution Exposure a Global Review Current Environmental Health Reports 2 4 440 50 doi 10 1007 s40572 015 0069 5 PMC 4626327 PMID 26381684 Definition of BIODEGRADABLE www merriam webster com Retrieved 2018 09 24 Standards by ASTM International Edit D5210 Standard Test Method for Determining the Anaerobic Biodegradation of Plastic Materials in the Presence of Municipal Sewage Sludge D5526 Standard Test Method for Determining Anaerobic Biodegradation of Plastic Materials Under Accelerated Landfill Conditions D5338 Standard Test Method for Determining Aerobic Biodegradation of Plastic Materials Under Controlled Composting Conditions Incorporating Thermophilic Temperatures D5511 Standard Test Method for Determining Anaerobic Biodegradation of Plastic Materials Under High Solids Anaerobic Digestion Conditions D5864 Standard Test Method for Determining Aerobic Aquatic Biodegradation of Lubricants or Their Components D5988 Standard Test Method for Determining Aerobic Biodegradation of Plastic Materials in Soil D6139 Standard Test Method for Determining the Aerobic Aquatic Biodegradation of Lubricants or Their Components Using the Gledhill Shake Flask D6006 Standard Guide for Assessing Biodegradability of Hydraulic Fluids D6340 Standard Test Methods for Determining Aerobic Biodegradation of Radiolabeled Plastic Materials in an Aqueous or Compost Environment D6691 Standard Test Method for Determining Aerobic Biodegradation of Plastic Materials in the Marine Environment by a Defined Microbial Consortium or Natural Sea Water Inoculum D6731 Standard Test Method for Determining the Aerobic Aquatic Biodegradability of Lubricants or Lubricant Components in a Closed Respirometer D6954 Standard Guide for Exposing and Testing Plastics that Degrade in the Environment by a Combination of Oxidation and Biodegradation D7044 Standard Specification for Biodegradable Fire Resistant Hydraulic Fluids D7373 Standard Test Method for Predicting Biodegradability of Lubricants Using a Bio kinetic Model D7475 Standard Test Method for Determining the Aerobic Degradation and Anaerobic Biodegradation of Plastic Materials under Accelerated Bioreactor Landfill Conditions D7665 Standard Guide for Evaluation of Biodegradable Heat Transfer FluidsExternal links EditEuropean Bioplastics Association The Science of Biodegradable Plastics The Reality Behind Biodegradable Plastic Packaging Material Biodegradable Plastic Definition Retrieved from https en wikipedia org w index php title Biodegradation amp oldid 1149494554, wikipedia, wiki, book, books, library,

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