key: cord-0691398-pfdacm60
authors: Abhilash,; Inamdar, Isiri
title: Recycling of plastic wastes generated from COVID-19: A comprehensive illustration of type and properties of plastics with remedial options
date: 2022-05-12
journal: Sci Total Environ
DOI: 10.1016/j.scitotenv.2022.155895
sha: 609049b86db27958a6acef7ed38945937aa1ed81
doc_id: 691398
cord_uid: pfdacm60

Plastic has contributed enormously to the healthcare sector and towards public health safety during the COVID-19 pandemic. With the frequent usage of plastic-based personal protective equipment (PPEs) (including face masks, gloves, protective body suits, aprons, gowns, face shields, surgical masks, and goggles), by frontline health workers, there has been a tremendous increase in their manufacture and distribution. Different types of plastic polymers are used in the manufacture of this equipment, depending upon their usage. However, since a majority of these plastics are still single-use plastics (SUP), they are not at all eco-friendly and end up generating large quantities of plastic waste. The overview presents the various available and practiced methods in vogue for disposal cum treatment of these highly contaminated plastic wastes. Among the current methods of plastic waste disposal, incineration and land filling are the most common ones, but both these methods have their negative impacts on the environment. Alongside, numerous methods that can be used to sterilize them before any treatment have been discussed. There are several new sorting technologies, to help produce purer polymers that can be made to undergo thermal or chemical treatments. Microbial degradation is one such novel method that is under the spotlight currently and being studied extensively, because of its ecological advantages, cost-effectiveness, ease of use, and maintenance. In addition to the deliberations on the methods, strategies have been enumerated for combination of different methods, vis-à-vis studying the life cycle assessment towards a more circular economy in handling this menace to protect mankind.

. Further, when it comes to quantifications during such a pandemic, medical plastic residues from COVID-19 tests have no relationship with the population size or the country's gross domestic product (Celis et al., 2021 ).

An estimation of plastic waste generated by RT-PCR diagnostic test, by continent has been described in detail in Fig. 4 . Similarly, a statistical study from 2020, of the top ten countries with the highest amounts of plastic waste generation has also been depicted in Fig. 5 . Further, these statistics are only based on one method of testing, which is RT-PCR. Other methods such as an antigen or antibody testing are difficult to quantify as we do not have official data on the regions that are using these methods or the number of such tests being performed. These statistics however will also vary when we take the second wave and third wave, which has hit many countries, into consideration (Celis et al., 2021) .

There are several different polymers utilized in making different varieties of plastics depending on their utilization (Table-1) . A majority of plastic polymers are inert/nonreactive . However, some polymers are weakened or even dissolved using nonpolar organic solvents. These differences in the properties of polymers are a result of many different factors such as:

 Functional groups  The number of monomers present  Degree of cross-linking/saturation Plastic polymers can be broadly classified into 2 main categories-thermoplastic and thermoset. Thermoplastics do not have any cross-links and are, therefore, capable of withstanding more heat. This allows them to go into a molten state or soften when heated and once they cool down, they maintain their shape. They can thus, be remolded into shapes and materials to our convenience. They are formed by additional polymerization and contain linear long-chain polymers. They are weak, soft, less brittle, and have a lower molecular weight and are thus easier to be J o u r n a l P r e -p r o o f degraded especially by microbes, eg., polyethylene, polypropylene, polystyrene, polyvinyl chloride (Ouellette and Rawn, 2015) .

Thermoset plastics on the other hand are highly cross-linked with covalent bonds, which does not allow them to soften at high temperatures. This makes it hard for them to be re-molded. They are formed by condensation polymerization. They are strong, hard, and brittle and have a higher molecular weight, eg., polyester, polycarbonate, polyamide, polyurethane (Ouellette and Rawn, 2015) .

Apart from the above-mentioned polymers that are already highly toxic to the environment, many of these plastics has additives, as mentioned in Table- 2. that help in improving their properties like flexibility strength or elasticity, anti-fog, antiscratch, anti-glare, anti-static. All of these additives add to the toxicity of plastics causing a lot of damage to their surroundings when they undergo degradation (Hahladakis et al., 2018; Wiesinger et al., 2021) .

The significance of leachable chemicals from microplastics depends on parameters such as the chemical concentration in the parent plastic, their partitioning coefficient, the age and degree of degradation of the microplastic being studied (Halden, 2010; Okunola et al., 2019) . For instance, the degree of crystallinity in aged microplastics will be higher, and thus they may have reduced leaching (Lambert et al., 2017) .

The appropriate, as well as eco-friendly methods of management of waste generated from the pandemic, is very important. In an attempt to safeguard our health, we must not ignore the future environmental implications of plastic waste generated.

For example, even if 1% of the facial masks are disposed of inappropriately, then it would still lead to around 10 million masks polluting the environment every month (Shiferie, 2021) . Each face mask approximately weighs 4g and this would thus be equivalent to around 40,000kg of plastic into the environment as pollution (Silva et J o u r n a l P r e -p r o o f al., 2021) . Further, we do not have information about how these masks are disposed of either, because many common people who do not have enough awareness will end up mixing these masks with the rest of their garbage (Xu and Ren, 2021; Yacob et al., 2022) . This makes it very difficult to, segregate the waste and treat it appropriately. The pandemic has completely turned this system upside down with the massive addition of waste which will impact normal operations to a large extent (Parashar and Hait, 2021) .

According to a recent study in Magdalena River, Columbia by Prata et al., (2020) , the degradation of non-woven synthetic cloths (PPE), was a major source of the microplastic microfibers found in both, the water and sediment samples. . This eventually has harmful effects on the terrestrial as well as aquatic biota (Silva et al., 2021) .

Three major waste disposal systems in place for the treatment of medical wastes depending on their hazard level are mechanical recycling, incineration, and landfilling. According to an estimation by the Ellen McArthur Foundation at the global level, the percentage of plastic waste undergoing mechanical waste recycling is only 16%; whereas the rest are either incinerated (25%), dumped into sanitary/unsanitary landfills (40%), or they leak into the environment as a result of mismanagement (19%) (Vanapalli et al., 2021) . It has been observed that, at a global level, almost 14,900 tons of plastic residues have been incinerated, and 494 tons of plastic end up in landfills. More than 10 tons of plastic waste is incinerated in most countries (Celis et al., 2021) . The COVID-19 pandemic is highly contagious and is present as a contaminant in all the medical as well as municipal solid waste (MSW) being generated. Therefore, incineration and landfilling are potential disposal methods being preferred over recycling (Fig.6 ). Both these methods, however, have deteriorating effects on the air, soil, and water quality in the long run. For example, in the United Kingdom, the carbon footprint of MSW incineration is 0.179 t CO 2 eq./t and from landfills, it is 0.395 t CO 2 eq./t (Jeswani et al., 2013) .

Landfilling is one of the most common methods widely used to dispose of many types of mixed wastes in the hope that they will degrade (Abdel-Shafy and Mansour, 2018) . Increased levels of greenhouse gases such as CO 2 and CH 4 are released in significant amounts during the plastic degradation process in these landfills (Royer et al., 2018) . Since this degradation process is highly time-consuming, the gases released thereafter also remain in the air for a longer time (Prata et al., 2020; Okunola A et al., 2019) .

The process of incineration has a greater advantage over landfilling when it comes to energy recovery. Yet, landfilling is comparatively more preferred only from the waste management perspective. A study performed on non-recyclable plastic (Hopewell et al., 2009) showed that the CO 2 emissions from landfilling (253g per kg) are much lesser compared to incineration (673-4605g per kg). However, a majority of developing and underdeveloped countries still follow the unsanitary dumping of wastes without prior treatment. This method leads to massive space constraints, leaching of toxic chemicals, and can also cause open fires to occur in dumps (Eriksson and Finnveden, 2009 ). It will have the same effect as incineration, releasing large amounts of air pollutants such as dioxins and furans. (Vanapalli et al., 2021) .

Thermal treatment is yet another method used to treat large medical plastic residues.

Thermal treatment is also given more importance because the high temperatures used in thermal treatments ensure the complete disruption of any type of microbial contamination (Błaszczyk and Iciek, 2021) . Some of the thermal treatment methods commonly used are incineration, steam treatment (autoclaving), microwave treatment, and plasma treatment. Different types of treatment can be used depending on the type of plastic waste, technical, economic, environmental, and J o u r n a l P r e -p r o o f social acceptability of the region. Incineration is done at very high temperatures of 800-1000 o C, along with the recovery of waste heat energy is a very realistic and sensible choice to make in terms of waste disposal (McDonnell, 2009) . This method as mentioned will ensure complete removal of contaminants and also release heat energy that can be utilized for other purposes (Klemeš et al., 2020) . The incineration method continues to be the best choice for the amount of medical plastic waste (>10t/day), mainly because of its safety reasons. If the volumes of medical waste are lesser (<10t/day), then other methods such as chemical disinfection or physical disinfection (microwaves or high-temperature steam) are better options (Silva et al., 2021) . The bigger challenge during this pandemic, however, is surpassing the incineration capacity by a huge margin. For instance, during the starting phase of the pandemic in 2020 the highest amount of waste generated in Wuhan, China was 240 tpd (tons per day) which was almost 5 times above the normal incineration capacity of just 49 tpd (Klemeš et al., 2020) . This will surely have a severe impact on the air quality, leaving no room for the environment to recover (Parashar and Hait, 2021) .

The process of incineration, unlike landfilling, has energy recovery. Many developed countries like, Sweden, Denmark and Poland have all been using various modern and advanced technologies such as the "waste to energy" system that works by treating waste and also acts as an air pollution control method. One of the best examples of a country utilizing this method is Sweden, where up to 23% of energy output is recovered from both municipal and industrial waste incineration (Holmgren, 2006) .

Since most plastics are non-biodegradable, the focus should be on reducing the production itself. It is also important to note that, the plastic waste residues from the pandemic must be sterilized before being recycled (Parashar and Hait, 2021) .

The process of plastic recycling depends majorly on the purity of the plastic that is being considered. Therefore, many impurities in the form of dust, dirt, additives, J o u r n a l P r e -p r o o f inorganic materials, and mixed polymers act as barriers in the pathway of recycling (Klemeš et al., 2020) . Single stream plastic like PET with the least number of mixed polymers and impurities is easier to recycle (Hopewell et al., 2009 ). On the contrary, mixed plastic streams, SUPs and multilayer plastics are quite expensive to be recycled and have almost no economic value even after recycling. ome of the common problems faced during mechanical recycling of waste products are polymer crosscontamination, inorganic impurities, additives in the polymer, inappropriate segregation at the source or during the collection of waste, and semi-degraded plastics when they are collected from open dumps Lange, 2021) . All of these factors need to be assessed and some methods must be strictly implemented to ensure the proper recycling .

The recycling process can be categorized into 4 main types:

 Primary ( recycling of plastic residues, using mechanical methods, into products that have the same properties as that of parent plastic).

 Secondary (the recycling of plastic residues via, mechanical processing into products with lower properties than the parent plastic polymer).

 Tertiary (use of chemical processes to reduce the polymers to monomers/oligomers so that they can be either re-polymerized to produce fresh plastic products or used for the production of other types of materials).

 Quaternary (energy recovery in any form from the processing of these plastics).

The final products after plastic recycling, may not be as economically valuable as some other recycled materials such as metals or even glass (Hopewell et al., 2009 ). This is mainly because of the low value of plastics in comparison to metals or glass.

Apart from this, technical issues like melting also need to be taken care of during plastic recycling processes. Thee recycling by melting results in the structural weakness in the final products. . For instance, two commonly blended polymers, polyethylene, and polypropylene have very limited use after recycling (Lithner et al., 2009 ).

In the processing of plastic residues through incineration methods, 1 ton of plastic releases around 5 -10 tons of CO 2 (Vollmer et al., 2020) . When plastic waste is landfilled, less than 2wt% carbon molecules in the polymers are hardly released even after long intervals Webb et al., 2013) ). This reduces the lifecycle of CO 2 to one-third the value obtained by incineration for the same amounts of plastic, that too with no energy recovery (Windfeld and Brooks, 2015) .

In addition to the environmental impact of the large amounts of pollutants released, the amount of energy recovered from the incineration of plastics is less than the amount of energy conserved from mechanical recycling. The heating value of plastics by thermal treatment processes is approximately 36,000kJ/kg (Panda et al., 2010) . On the other hand, mechanical processing helps in recovering almost 60,000-90,000kJ/kg (Panda et al., 2010) . Hence, recycling plastic waste residue will conserve almost double the amount of energy as incineration and it also has a very little environmental impact (Rahimi and García, 2017) . We must start looking at discarded plastic waste as a source of energy. Primary recycling methods cannot be applied to PPE or medical equipments used for COVID-19 because we require pure polymers for these methods. The secondary recycling methods are used to produce products that have functions different from those of the parent plastics (Fig.7) . This method can be adopted for COVID-19 plastic waste residue, but it requires very thorough sterilization of the waste products (Rahimi and García, 2017) .

When we talk about the plastic waste generated from the COVID-19 pandemic, we are dealing with "contaminated waste" materials. It is very important to disinfect all these materials before they are recycled or repurposed to prevent the mass spread of the contaminant microbes (Abdel Shafy and Mansour, 2018). Further after disinfection, some of these materials may still retains its original strength and all the other properties. Thus, they can be reused until the safety standards are met post disinfection.

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Chemical disinfection combined with mechanical shredding done before the disinfection has been widely used to pre-treat COVID-19 waste residues. During the mechanical shredding process, the air is passed through high-efficiency particulate air (HEPA) filters to remove any aerosol formation that might be infectious in the successive steps (Liu et al., 2022) . The shredded mixture is then mixed with chemical disinfectants and processed in either a closed system or under negative pressure for a stipulated amount of time. This helps the organic substances to be decomposed and inactivates or kills all the infectious microorganisms.

There are several advantages of using chemical disinfection methods -broadspectrum sterilization, fast action, stable performance, and requirement of low effective concentrations (Rutala et al., 2015) . There is also no residual hazardous toxins leftover after the process is completed, and this method not only kills all types of microorganisms effectively but also inactivates any spores present (Wang et al., 2020) . The contamination of medical equipments and PPE are different depending upon the surroundings in which they have been utilized. Therefore, a sterility assurance level (SAL) must be established to ensure complete sterilization (Shalaby et al., 2013) . Depending on the initial viral activity, the reduction of the microbial load to reach SAL can be as low as 5 logs, or as high as 12 logs (Lee et al., 2014) . However, for any initial load of microorganisms, higher the reduction in concentration posttreatment, the process will be more advantageous and preferred (Jinia et al., 2020) .

Tchemicals used in the disinfection of COVID-wastes are classified as chlorine-based and a non-chlorine-based system. A chlorine-based treatment system involves the use of chemicals like NaOCl or ClO 2 that are used as disinfectants. Since chlorine has a high electronegativity, it can easily oxidize peptide links and denatures the J o u r n a l P r e -p r o o f proteins, by penetrating the cell layers even at neutral pH (Singh et al., 2012) . One of the first chemical disinfectant used was NaOCl which acts by releasing halo acetic acid, chlorinated aromatic compounds, and dioxins. Similarly, ClO 2 , a strong biocide being unstable is easily decomposed into salt and mild toxic products . A nonchlorine-based disinfectant like H 2 O 2 , oxidizes and denatures proteins as well as lipids (Ilyas et al., 2020) . Hydrogen peroxide is also a strong oxidizing agent and thus by producing hydroxyl radicals that attack and damage the DNA and other essential cell components (Jinia et al., 2020) . High levels of reactivity and no toxic releases associated with these methods make it an advantageous choice.

However, H 2 O 2 is not found to be appropriate for linen or cellulose as it degrades the properties of the material (Ilyas et al., 2020; Jinia et al., 2020) . To overcome this drawback, vaporized hydrogen peroxide (vH 2 O 2 ) used as a disinfectant showed promising results via degradation of of bacteria, and viruses. One of the main advantages of using vH 2 O 2 at low temperatures is its compatibility with polymeric materials (McEvoy and Rowan, 2019). This has an additional benefit of reduction in processing time to nearly half (e.g., from 10-15 h with ethylene to just 6 h with vH 2 O 2 ). It can also be performed at atmospheric pressure or under vacuum conditions. There is no improvement in its compatibility with cellulose-based materials. .

Some other chemicals used are povidone-iodine (0.23%), isopropanol (>70%), ethyl alcohol (>75%), and formaldehyde (>0.7%), known to inactivate the coronavirus (Ilyas et al., 2020; Singh et al., 2020) . Formaldehyde alkylates the amino and sulfhydryl groups of proteins and nitrogen atoms of purine bases; whereas glutaraldehyde alkylates the sulfhydryl, hydroxyl, carboxyl, and amino groups (Jinia et al., 2020) .

Heat is also an excellent disinfecting technique. With an increase in usage and the need for disinfection of N95 masks, few other methods such as heat and radiations J o u r n a l P r e -p r o o f have also been successful in destroying the virus. For example, an investigation using dry heat/hot air at 75 o C for 30mins or using ultraviolet radiation at 254nm and 8watts for 30 mins, have been known to destroy the virus (Chin et al., 2020; Ilyas et al., 2020) . However, the level of decontamination and how well it works by penetrating the layers of material and removing the trapped virus is still an unknown phenomenon. There are a few recent studies by Chin, et al.(2020) , where the stability of the SARS-CoV2 virus was observed at various temperatures. Using a total of 106.8 TCID50 (fifty-per cent Tissue Culture Infective Dose) viruses per ml of viral titer. The SARS-CoV-2 virus was highly stable at 4 o C, as they observed a reduction to 106.1 TCID50 per mL of viral load, even after 14 days. However, the viruses were inactivated 100% within 5 mins at 70 o C. Thus, there exists a lot of scope to heat as a disinfection method for the sterilization of PPE (Chin et al., 2020; Jinia et al., 2020) .

A very simple and cost-effective sterilization technique, using steam as a disinfection method for FFP2 masks, was demonstrated by a group of researchers at the Delft University of Technology in the Netherlands with dry sterilization and regular steam (van Straten et al., 2021) ,. In the case of steam, the masks were exposed to conditions similar to that in an autoclave(121 o C for 15 min). The results indicated that even as the steam treatment deactivated the virus, the filtration capacity of the mask remained undisturbed (Jinia et al., 2020) .

This method of utilizing steam or autoclaving is being seriously considered as a major alternative to incineration. The temperatures are sufficiently high to destroy all microorganisms including spores and there is no release of toxic chemicals or harmful gases. These systems generally operate at temperatures (121 and 163 o C) under pressure. This treated waste can then be taken to MSW treatment centers where they can be recycled or re-purposed, in the same way as non-infectious waste (Windfeld and Brooks, 2015) .

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Microwave technique can be used as an alternative to autoclaving (Lee and Huffman, 1996) . =The only disadvantage while using microwaves is that no metals must be present in the waste being sterilized (Windfeld and Brooks, 2015) . Microwave sterilization can be done in a temperature range of 177 -540 o C indicating a possibility of reverse polymerization when the microwaves are applied with high energy in an inert atmosphere. When the electromagnetic waves with a wavelength of 1mm to 1m, in the frequency of 100-3000MHz is applied to any material, then the molecules tend to vibrate and rub against one another causing an increase in the internal energy (Dogan Halkman et al., 2014) and thus maintaining the high temperatures required for disinfection. Some of the advantages of the microwave sterilization technique include limited heat loss, no toxic residues, and the requirement of relatively lower energy and temperatures. According to the "Technical specifications for microwave disinfection, centralized treatment engineering on medical waste" (on trial) published by the Ministry of Ecology and Environment (MEE) of China, microwave disinfection technology was successfully able to achieve the logarithmic value of killing viruses, bacteria parasites, and fungi of ≥ 6 (Wang et al., 2020) . This method is also found to be far more helpful when applied to on-site COVID-waste. This type of on-site decontamination not only saves a lot of time but also reduces the risk of transmission during COVID-waste transportation. For the disinfection of COVID-waste, a combination of autoclaving and microwave techniques can be used when the steam used is in a temperature range of 93-177 o C (Ilyas et al., 2020) .

UV radiations inhibits the formation of purine dimers that cause single-stranded as well as double-stranded breaks. Single strand breaks are repairable, but doublestranded breaks result in the loss of genetic material. Depending on the particular J o u r n a l P r e -p r o o f wavelength of UV radiations used, the effectiveness of sterilization is determined (Rastogi et al., 2010) . The maximum absorption of UV radiations for DNA and RNA occurs at 260 nm and thus the exposure of sterilizing material to UV light at around 260 nm is desired for effective sterilization (Jinia et al., 2020) .

X-rays/gamma radiations are high-energy radiations that damage the DNA of cell by direct energy deposition or by secondary interactions with the surrounding atoms or molecules. In secondary interactions, the radiations interact with the surrounding water molecules producing many hydroxyl free radical groups. The OHgroups, owing to their high electro-negativity react with DNA molecules causing up to 90% damage in their chemical and physical structure (Reisz et al., 2014) . Both, direct and indirect interaction of the radiations with cells, cause major damage to the double staranded DNA, eventually leading to cell death due to shorter wavelengths and higher energy. The radiation penetrates from the outer surface to the interior resulting in complete decontamination of the contaminated items. While using ionizing radiation for sterilization, the impact of the radiation on the material of the equipment must also be taken into consideration.

The plastic solid waste (PSW) generated from COVID-19, although classified as medical hazardous waste, still has a lot of contaminants, like wood, rubber, and metal particles. These contaminants need to be separated from the plastic polymers. In the case of mixed polymers, the individual polymers need to be separated as much as possible before reprocessing them because each of the polymers responds differently to different processing techniques (Scalenghe, 2018) . Manual separation of plastics from the contaminants and other polymers is time-consuming and ineffective. Thus, many automatic separation techniques have been studied and put into practice to fasten the process. These sorting techniques rely on differences in the properties of materials,that can be measured such as density, electrostatics, J o u r n a l P r e -p r o o f spectral signatures, and wettability (Luciani et al., 2015) . For instance, there are many differences in the densities of commercial polymers: PVC (~1.07-1.18g/cm 3 ) and PET (~1.38-1.49g/cm 3 ) being denser than polyamide (~1.07-1.18g/cm 3 ), polystyrene (~1.04-1.11 g/cm 3 ) and polyethylene (~0.91-0.97 g/cm 3 ) (Vadivelu et al., 2016) . Since polymer recycling is a complex procedure, there are many advancements in mechanical and optical separation technologies to allow for the correct identification and separation of different material types. Many new modern technologies that have been discovered in recent times have shown promising results in the separation of waste particles as small as 2 mm (Schmaltz et al., 2020) . The physical properties of the materials are targeted when mechanical separation systems are used, and for further differentiation of the materials, optical techniques are widely used in combination. To convert the random mixture of different plastics into a highly purified stock, the sorting processes used in recycling plants need to have more effective, accurate, affordable, and efficient irrespective of the type of input waste, originor the nonplastic contaminants. (Rahimi and García, 2017) .

Some of the most tested technologies used for plastic sorting/separation are as follows :

 Magnetic Density Separation (MDS) -In this method, plastics are separated based on the densities of the constitutent polymers. Even with an overlapping or narrow density difference between two plastic polymers, they can be distinguished accurately. This method uses a magnetic mixture of nanometre-sized iron oxdie particles suspended in waterand separated vertically in a magnetic field. MDS method is a rapid, accurate, and single-step process that effectively sorts HDPE, LDPE and PP. It also segregates other materials such as rubber and metal contaminants (Bakker et al., 2009) .  Speed acceleration (delamination of the polymer from other materials, at a very high speed centrifugal/centripital force).

 Solvent-based recovery -based on the solubility of the polymer in organic solvents. This is most effective for polyvinyl chloride, which is dissolvable and thus can be separated from materials insoluble in organic solvents.  Laser-induced breakdown spectroscopy ( for the evaluation of compositional elements of materials by comparing the in real-time atomic emission spectral data to referenced sources) (Zeng et al., 2021) .

Ultrasound technology ( monitor the separation of plastic waste and also to assess the process quality information) (Maio et al., 2010) . There is an imperativeneed to shift to a more automated waste segregation system with a combination of artificial intelligence technologies, to increase the safety of labourers working with such wastes. This type of system which makes use of artificial intelligence-powered automated systems to improve the efficiency and the speed of recycling. Since such systems have fewer chances of making errors when compared to manual segregation, the quality and value of the resultant recycled product are always higher (Vanapalli et al., 2021) .

There is a lot of research being done on different methodologies that can directly process co-mingled plastic waste. Most plastics are immiscible with one another, thus for plastic waste streams, there is lower phase separation of mixtures and thus the products have very reduced properties. The smallest amounts of contamination, of J o u r n a l P r e -p r o o f even one plastic-type with another, can change the properties of the resultant recycled product thereby reducing their potential usage (Klotz et al., 2022) . Polymer compatibilizers used are multicomponent polymers, similar to surfactants, and induce specific thermodynamic interaction with immiscible polymers (Ha et al., 1996) .

They are designed differently based on their functionality, as block polymers, random copolymers, and graft polymers.

Thermal processing, using the principle of waste-2-energy", is one of the most sustainable solutions at present, to deal with the excessively large amounts of plastic wastes being generated. Thermal processing with energy recovery not only reduces the volumes by 80-95% but also helps in converting the heat energy into some form of useful energy that can be utilized by many other industries (Prata et al., 2020) .

Pyrolysis is one such method which not only reduces the continuous waste being generated, but also derives profitable energy from the same. Pyrolysis has the upper hand over all thermal treatment methods mainly due to reduced carbon footprint (Thompson et al., 2009; .

Pyrolysis is one of the ideal methods, especially for those plastic waste feeds that cannot be de-polymerized. Such waste mainly comprises mixed PE/PP/PS possessmultilayer packaging, and are fiber-reinforced composites that cannot be mechanically recycled (Ragaert et al., 2017) . In the pyrolysis process, the chemical bonds in plastic polymers are broken using thermal energy in an oxygen-free environment to obtain resultant product /(mix of hydrocarbons) and depending on whether a catalyst is used in the process, it is also called catalytic cracking or thermal cracking, however, the process operated under pressure is called liquefaction (Vollmer et al., 2020) .

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The biggest advantage of this method is that it does not require the separation of the different types of waste plastic before processing and convert them into liquid fuel that can be used by various industries to generate energy for different purposes . Applying the process of pyrolysis to plastic wastes at temperatures of around 500 o C can generate large quantities of liquid oil, which can be used in gas turbines, boiler systems, generators, and sterling engines. This method consumes upto ~80 wt% of plastic waste. With the increase in industrialization worldwide, the demand for alternative fuel and energy resources are always high. Since pyrolysis is performed in the absence of oxygen and the fuel contains large amounts of carbon and hydrogen, it does not require further upgradation. Liquid fuelsare non-corrosive, non-acidic and have very high calorific values (Jain et al., 2020) According to various reports, the pyrolysis of plastic wastes at temperatures of 500- 

The use of catalysts during pyrolysis is called catalytic cracking. This method is differentiated into 2 types: liquid and vapor phase (Ragaert et al., 2017) . When the catalyst used comes in direct contact with the molten phase of the polymer, it is called the liquid-phase process, and causesconversion to partially degraded oligomers. When the catalyst comes in close contact with vapors that are formed J o u r n a l P r e -p r o o f during cracking, it is called the vapor phase process. In this method, solid catalysts used are silica-alumina, zeolites, ZSM-5, and mesoporous materials (Garcia et al., 2005) . Similarly, when polymers undergo catalytic cracking, the temperature required for the pyrolysis is lowered to a great extent, when compared to normal solid plastic waste pyrolysis. The temperatures generally required for an effective pyrolysis process must be higher than 450 o C, but with the use of catalyst, the temperature is reduced to 300-350 o C (Garcia et al., 2005) .

A recent study by Swansea University (Ref), converted PPE to hydrogen fuel (Uekert et al., 2008) , using sunlight. The studyshowed the catalytic thermal treatment of plastic polymers (PS, PE, PP, and PET), in the pure or mixed form, produces liquid oil with a higher percentage and range of aromatic compounds, than fuel products produced from petroleum. The liquid oil has a high heating value (HHV) of 41.7-44.2 MJ/kg, which is very close to conventional diesel (Miandad et al., 2019) .

The resultant aromatic compounds from some polymers can be used as a raw material for polymerization in various chemical industries (Chanda, 2021) . The liquid oil can also be mixed with diesel in different ratios, for use as fuel in transport vehicles apart from the solid residues (char). Th e chairmainly comprises condensed organic residues and inorganic phases which have an average heating value of 28.5-29MJ/kg and is used for the synthesis of activated carbon. ).

There are also many toxic by-products resulting from pyrolysis whose release can also be controlled by altering the operational parameters like the heating rate, temperature, duration of heatingd. The inert environment maintained during the pyrolysis of plastic polymers in thermal reactors also helps in controlling the resultant toxic by-products formed by carbon re-arrangement (Jung et al., 2021) . The carbonaceous materials used to make PPE can be converted into three phases of pyrogenic products (Siwal et al., 2021) , viz.., syngas (comprises of H 2 , CH 4 , and CO); condensable gaseous/liquid hydrocarbons; and char. J o u r n a l P r e -p r o o f

Hydro-cracking refers to the thermal breakdown of polymers in the presence of H 2 atmosphereand lower reaction temperature thereby decreasing the amount of coke formation by using radicals that block the coke precursors. Both these factors prolong the life of the catalyst during the reaction, thus reducing the amount of catalyst required, and also encourages the production of more saturated products like alkanes in the place of alkenes. These alkanes can be easily broken down into monomers using established steam-cracker technologies, which can be further used to synthesize PP and PE plastic polymers (Frączak et al., 2021) . The use of gasesother than hydrogen and nitrogen, are helium, argon, ethylene, propylene, and CO 2 . For example, in a CO 2 -rich environment, pyrolysis of PVC reduces tar formation and in pyrolysis of PET, the acidity of liquid oil is reduced (Vollmer et al., 2020) .

However, we must keep in mind the cost of hydrogen stream, operation set up and thus, the overall investment costs are all quite high (Ragaert et al., 2017) .

The thermochemical conversion of carbonaceous compounds like organic waste and even plastic waste, at temperatures of 750-850 o C into a mixture of gases is called gasification (Sikarwar et al., 2016) . Some of the commonly produced gas mixtures, also known as syngas, consist of carbon monoxide (CO), hydrogen (H 2 ), carbon dioxide (CO 2 ), methane (CH 4 ), nitrogen (N 2 ), smaller liquids like tar and solid fractions (Bhatia et al., 2021) . In gasification, almost any type of solid material can be converted into a gaseous mixture even without any pre-treatment. The chemical process involved in conversion is partial oxidation, which uses oxidizing agents like a mixture of steam and pure oxygen or only oxygen. Air can also be used, instead of pure oxygen, but that will result in lower outputs and is tougher to separate. There is also an increase in gas flow rate, all of which negatively impacts the overall cost of the process. Even from the environmental point of view, this produces a higher amount of noxious gas, which must be carefully controlled. The entire gasification J o u r n a l P r e -p r o o f process has many endothermic as well as exothermic processes, but the overall reaction is endothermic. Gasifiers are also used in this process to ensure higher thermal efficiency for further power generation as well as to reduce the harmful emission of gases into the atmosphere. A few impurities like NH 3 , H 2 S, NO x , alkali metals, and tars are also produced along with syngas (Ragaert et al., 2017) .

Solvolysis is achemical process, involving depolymerization and many other interchange reactions that result in the production of oligomers and monomers.

Solvolysis converts the thermoplastics and thermosets such as polyesters, polyamides, and polyurethanes (Xanthos and Patel, 1998) . Unlike pyrolysis, this method uses lower temperatures to selectively recover monomers from polyesters and polyamides. The different solvolysis methods like hydrolysis alcoholysis, phospholipids, ammonolysis, and aminolysis to cleave ether, ester, and acid amide bonds. allows for re-polymerization and production of plastic with the same quality as original purely made plastics. The products produced from solvolysis are mostly monomers that can be further purified, by removing colorants and additives. It also results in addition of conventionally obtained monomers and use them for polymer synthesis (Xanthos and Patel, 1998; . (Fatima, 2014) 

Mechanical stress on polymers results in homolytic cleavage to form radicals. This method is usually applied to restore plastic properties by crosslinking and cross polymerization. However, this method can also be applied to stimulate depolymerization, without the need for any external heat (Miao et al., 2021) 

The process of dissolution is widely used to separate one single polymer from a mixture of polymers usually when they are present as multilayer films (Pappa, 2001) .

The process can thus be used to recover plastic polymers from mixed plastic wastes without any additives. This dissolution method makes use of either a single solvent or a mixture of solvents and an anti-solvent. In this method, the solvent is chosen in such a way that it selectively dissolves only the plastic polymer intended to be J o u r n a l P r e -p r o o f recovered. An anti-polymer is then added to this solution, thus precipitating the desired polymer out, for recovery and purification. After the dissolution in a solvent and before precipitation with the antisolvent, all the undissolved materials such as pigments and undesired polymer, gets separated from the polymer mixture. After precipitation, the solvent and antisolvent mixture is separated for another batch. This separation, however, becomes expensive in terms of energy and time if the solvent has a very high boiling point. Thus, we must keep in mind to choose the most economically feasible solvent for this method (Vollmer et al., 2020) .

Another important aspect is that any residual solvent leftover in the precipitate will affect the polymer properties. Thus, complete removal of the solvent is necessary, and this becomes easier when the solvent is a supercritical fluid because it easily evaporates with decreased pressure. The extraction of the polymer as a precipitate by dissolution results in the production of crystallized polymer, which must be upgraded to produce virgin grade polymers. Also, the precipitated polymer must undergo the process of extrusion to produce polymer granulates that can be used to manufacture new plastic itemsby re-stabilization, rebuilding the macromolecular structure, addition of elastomers or fillers, and using compatibilizers on mixed recycled blends (Vollmer et al., 2020).

Using ionic liquids is yet another recent approach as a strong solvation agent for polymers. This method has been used commercially, but it does have the disadvantage of high toxicity. The process is mertorius due to the use of right type of counter ions, to separate the depolymerized products using liquid-liquid extraction.

Further, the ionic liquids used for the depolymerization processes are not volatile and therefore, the distillation method cannot be used for separation (Vollmer et al., 2020) .

Some non-neutral ILs, such as 1-butyl-3-methylimidazolium acetate [Bmim] [Ac], also act as catalysts that can completely glycolyze PET (Al-Sabagh et al., 2014) . Studies also showed that using ILs, even at temperatures lower than 250 o C, PE can be J o u r n a l P r e -p r o o f degraded to produce alkanes. This process also although comparatively slower, can produce alkanes yields of up to 95%. Most ILs are commonly used in place of organic solvents as they have almost negligible vapor pressure and are also advantageous as they can also behave as catalysts for the reaction (Greer et al.,2020) . To overcome these ill effects, eutectic solvents are better due to the low melting points and behave as acid or base depending on functionality (Smith et al., 2014) .

Microorganisms have repeatedly proven to be excellent tool that are used to degrade various organic substances. Taking inspiration from this, a lot of research has been done over the years, to isolate and identify microorganisms that can be used for the digestion of plastic polymers (Mohanan et al., 2020) . Several studies by various researchers worldwide used microbes as well the degradative enzymes produced to deal with the rising levels of plastic wastes in the environment (Geyer et al., 2007) . Plastic polymers apart from having a strong backbone, show high levels of crystallinity and surface hydrophobicity, that prevent their natural breakdown and decomposition. (Carr et al., 2020; Jenkins et al., 2019; Ng et al., 2018) . Microorganisms utilizes plastics as the carbon source which are energetically less expensive, and ubiquitously present in the soil environment (Jenkins et al., 2019) . Further, even if the availability of plastic as raw material for microbes is abundant (for example, in the marine ecosystem), the high levels of salt in the water may prevent the microbes from acting on the plastic source (Carr et al., 2020) . Thus, to search for suitable microbes and extract the relevant enzymes from them we must isolate the different microbes from different species and study their degradation under different conditions of pH, temperature, salt, etc (Lear et al., 2021) .

Several studies in recent years have focused on the ability of different microorganisms and their enzymes to degrade synthetic plastics. Even though there are several reviews regarding this topic, almost all of them seem to focus on single J o u r n a l P r e -p r o o f streams of plastic polymers like PE/ PS/ PP /PET /PUR, etc (Ru et al., 2020) . Singh and Gupta (2014) (Ajith et al., 2020) . According to few studies, the heterotrophic bacteria may be stimulated to digest polymers by the release of dissolved organic carbon from plastic materials (Onda and Sharief, 2021) . In all the cases, the digestion of polymers by microorganisms is caused by enzymes, either externally or internally, that were able to break the carbon bonds in polymers (Ajith et al., 2020) . It has also been observed This database contains a list of many microorganisms and their relationship with different plastic polymers. The database also provides information about 79 specific genes that are supposedly related to bio-degradation. Recombinant DNA technologies and tools have been widely used to improve the expression of the specific genes involved in the plastic degradation process. However, these recombinant species must not be released into nature without carefully assessing the risks it poses, as it could become potentially overpowering (Carr et al., 2020) . Mixed Microbial Culture (MMC)inhabiting can efficiently utilize all the different available resources found in their surroundings (Jenkins et al., 2019) . Screening in nature for such consortia will help us find alternatives to genetically engineered microbes. Such mixed cultures are also beneficial since they are inexpensive and easy to prepare and J o u r n a l P r e -p r o o f maintain, have higher conversion efficiencies and are also the least susceptible to contaminations (Carr et al., 2020) .

The growth of all microorganisms is strongly influenced by various environmental parameters including temperature, pH, the salinity of the growth media, humidity in the air, amount of oxygen, atmospheric pressure, water activity, sunlight, and many more. In the same manner, these factors also influence the polymer degrading ability of the microorganisms. Since enzymes attack the chemical bond in the polymers, the chemical and physical properties decide the biodegradability of different polymers (Kale et al., 2015) . Some of these important factors are discussed below.  Presence of stabilizers, antioxidants, and additives further slowed down the rate of degradation as their toxicity affects microbial growth.

Apart from all these factors some structural parameters such as the presence of branching or linearity in polymers, the type of chemical bonds like amide/ester/glycosidic, etc., the physical form of the polymers (fibres, pellets films, powdered form), decide the surface area available for microbial growth, and further the biodegradability. Keeping all these factors in mind, while screening for suitable microbes, is very important (Kale et al., 2015) .

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Microorganisms belonging to the Pseudomonas genera are very well known for their ability to degrade most types of plastic polymers as well as their monomers.

Pseudomonas sp. has been mostly been studied for its ability to degrade hydrocarbons and other hydrophobic polymers, but most naturally found isolates are also known to degrade polyethylene, polypropylene, polyethylene glycol, polyurethane, polystyrene, polyethylene succinate, polyvinyl chloride, and polyvinyl alcohol to different extents. One study of a mixed microbial culture extracted from cow dung, comprising of thermophilic Pseudomonas sp., Bacillus sp., Paenibacillus sp. and Stenotrophomonas sp., was incubated with HDPE and LDPE plastic polymers for 120 days (Skariyachan et al., 2017) causing nearly 55% and 77% of their weight and with increased incubation period gave better results.. Along with this, many other factors also need to be altered for biodegradation to improve efficiency. Even though some polymers like polyurethane have very high durability, many Pseudomonas species like P.aeruginosa, P. flourescens, P. protegens, and P. chlororaphis have shown degrading ability (Carr et al., 2020) . months. The level of degradation was analyzed using CO 2 emission test, scanning electron microscopy (SEM), Fourier Transformation Infrared Spectroscopy (FTIR), and colonization studies (Kale et al., 2015) . A summary of some of the microorganisms, their source, and biodegradation of plastics have been mentioned in Table- 3 (Kale et al., 2015) J o u r n a l P r e -p r o o f According to a few reports two microorganisms namely, Brevibacillus borstelensis and Rhodococcus ruber can use polythene as the sole carbon source, since they can break down the carbon backbone of the polymer. A few fungal species like Penicillium simplicissimum YK, Aspergillus flavus and Mucor rouxii NRRL1835 have also been known for quite some time now for their polyethylene degrading ability. Using FTIR technology the polyethylene degradation of 61% by Microbacterium paraoxydans and 50.5% by Pseudomonas aeruginosa was recorded after an incubation period of two months. Whereas, in another study, 47.2% weight loss of the polythene polymer was recorded after incubation of 3 months using the microbe Aspergillus oryzae.

Polyethene discs were added into shaking tubes along with the broth and incubated for 8 months, at pH 4 and room temperature conditions, with the organism Phanerochaete chrysosporium recorded a 50% weight loss in the discs (Kale et al., 2015) .

In some studies, it was also noted that the pre-treated polymers could be degraded more easily than the original plastic waste. For example, a study using irradiated and non-irradiated LDPE films were treated with microorganisms like Aspergillus spp. and Lysinibacillus spp. were monitored for their biodegrading capabilities. In the case of irradiated films, there was a 29.5% biodegradation observed and in the case of nonirradiated films, only 15.8% biodegradation was observed (Esmaeili et al., 2013) .

Further, the decrease in percentage of carbonyl index (CI) of the LDPE polymer was higher in the case of UV-irradiated films, when it was allowed to degrade in the soil as compared to in vitro, with a specifically selected organism. In another study, 8 isolates out of the 25 isolates from landfills were selected and purified for their plastic degrading abilities. Of the eight, one of them even exhibited a 17% biodegradation, after one month of incubation in liquid culture with 130 rpm, kept at 37 o C (Kale et al., 2015) .

Sometimes, the microorganism can indirectly facilitate the process of plastic waste clean-up, even if they cannot directly digest the polymers (Urbanek et al., 2018 ). An J o u r n a l P r e -p r o o f interesting study using P.aeruginosa as bio-film was conducted to trap the microplastics and settle them at the bottom of the bioreactor. Once the microplastics are captured by the biofilms, they can be released from the biofilm matrix, with the help of the biofilm-dispersal gene (Kaplan., 2010) This gene allows excision of microplastics from the matrix. The microplastic collected in this manner can then be recovered and recycled at our convenience Liu et al., 2021) . 8.3.

Different molecular mechanisms such as chemical, thermal, photo, and biodegradation can result in plastic polymer degradation. Plastic polymers being hydrophobic, in nature reduces the accessibility to microbial species for breakdown and assimilation. This problem can be overcomed by treating plastics with enzymes that add functional groups to the polymer backbone and improve their hydrophilic nature, thereby resulting in the degradation of the main polymer chain via reduction in the molecular weight of the polymer (Aamer et al., 2009) . These shorter fragments are water-soluble and can easily be absorbed by the microbial cells for metabolism.

Aerobic organisms will release CO 2 and water as end products while, anaerobic organisms will release CO 2 , water as well as methane. These gases can be collected and used for various applications. These oligomers and monomers can also be used in many re-polymerization techniques, to produce recycled polymers or they can be converted to organic intermediates like acetones, acids, or ketones (Kale et al., 2015) .

Some of the physical parameters such as temperature, pressure, and moisture are involved in the mechanical breakdown of the polymer, which is even essential for the enzymes and microbial metabolites. The extracellular enzymes, typically do not penetrate the polymer, thus making the bio-degradation of plastics, only a surface erosion process. In the process of plastic degradation, the pro-oxidants catalyze the formation of free radicals in polythene. These free radicals react with molecular oxygen and then attack the polythene matrix to break them down into monomers or oligomers. When the enzymatic degradation of plastic polymers happens via J o u r n a l P r e -p r o o f hydrolysis it follows two major steps: the enzyme first binds to the polymer and secondly, it catalyzes the bond cleavage using a water molecule (Kale et al., 2015) .

Lignin has a very complex polymer structure that can be compared with plastic polymers. Lignin-degrading microorganisms, like white-rot fungi were extensively screened to check for their plastic degrading capabilities. Polyethylene degradation with fungal species IZU-154, Phanerochaete chrysosporium, Trametes versicolor under different nutritional conditions was attempted and it was observed that manganese peroxidase (MnP) is the major enzyme involved in polyethylene degradation (Iiyoshi et al., 1998) . This discovery encouraged researchers to use manganese peroxidase (MnP) to treat polyethylene polymers in the presence of tween 80, Mn (II), and Mn (III) chelators. The enzyme laccase (La) is also a well-studied degrader of aromatic substrates, and thus it was used in the oxidation of the hydrocarbon backbone of polyethylene. Using cell-free laccase, 20% reduction in the average molecular weight of the polythene was observed (Kale et al., 2015) .

The fungi Chaetomium globosum secretes both, La and MnP enzymes that can be used effectively to treat polyethylene. The mushroom Pleurotus ostreatus is capable of degrading oxo-biodegradable plastics without any pre-treatment of plastic with UV or thermal radiation. After 45 days of incubation, small holes were observed on the surface of the plastic surface due to the formation of hydroxyl groups and carbon-oxygen bonds. The degradation of the dyes used in the bags was also observed in some cases (H.V et al., 2014) .

Owing to their simpler structure, aliphatic polyesters can easily be broken down by enzyme activity when compared to aromatic polyesters even at room temperatures. terephthalate digesting enzyme. The PET polymer is degraded back into its monomers, namely BHET and TPA, as a result of mutations occurring at the active sites of cutinase residue. Cutinases have been recorded for their ability to digest various other polyesters at a temperature range of 40-70 o C at a pH range of 4-7, without using any co-factors (Carr et al., 2020; Ru et al., 2020) . The MHETase enzyme hydrolyses the MHET monomers to TPA and further to ethylene glycol (EG), which can be used to reproduce PET polymers. Crystalline PET, due to its structure, cannot be hydrolyzed by enzymes at room temperature; however, the reactivity improves with, thus during enzymatic action, the temperatures in the range of 67-81 o C (Vollmer et al., 2020) .

Most of the studies discussed above are done in controlled laboratory conditions. However, the natural environment where the microorganism is isolated has a diverse set of conditions in terms of temperature, humidity, sunlight, oxygen, and other nondesirable microorganisms that compete for nutrients. These conditions are very harsh compared to the comfortable environment provided in laboratories where microbes grow to optimum levels. Such conditions generally do not allow the complete degradation of plastics. Therefore, for microorganisms to use plastic wastes and grow on them, combined action of heat, moisture, and microorganisms, assists in better degaradation (Garcia and Robertson, 2017) .

A comprehensive study and investigation of all the microbial species involved in biodegradation is necessary to intensify the research in plastic bio-degradation techniques. Further, we must consider combining bio-degradation with other methods and find the right combination, to ensure complete plastic degradation leaving minimal residues behind.

Life cycle assessment is an important concept that helps us understand the relationship of any product with the environment, especially when we are trying to J o u r n a l P r e -p r o o f improve its sustainability. It can be defined as the comparative study/ assessment of all the environmental impacts on a particular product, process, or activity at different stages of its lifetime. It is a complete study from cradle to grave, starting from the extraction, transportation, and processing of raw materials; manufacturing; transportation; use, re-use, and maintenance; recycling; material; energy and water consumption; emissions; to the final disposal. It is important to compare the LCA studies, to find the best product, and for that, the assumptions and methodologies used in each step of a product's lifetime must be well documented, clear and consistent. A few environmental impacts that are evaluated for almost all products are toxicity to humans and other living organisms; freshwater and marine ecotoxicity; terrestrial ecotoxicity; acidification (of soil and rains); eutrophication; global warming potential; ozone depletion; depletion of fossil fuels (coal, petroleum, and natural gases); abiotic depletion of mineral resources; visible pollution in terms of litter; photochemical oxidation; renewable and non-renewable energy use (Ojeda, 2013) .

Assessment of the CO 2 emissions during different stages of the plastic lifecycle yielded that more than half the emissions arise from plastic production, whereas incineration of the final waste gives rise to only one-third of the emissions, and less than 10wt% of emission is associated with final product assembly like multilayer packaging (Hopewell et al., 2009) . The emissions of CO 2 from the transport of these waste materials to treatment plants are minimal. Further, the pyrolysis products like liquid fuel which replaces conventional fuels and natural gases help in saving almost 30wt% of emissions (Geyer et al., 2007) . The CO 2 savings from dissolution/ precipitation methods are almost at 65-75wt%, which is the highest among all other methods, since these methods don't involve any bond breaking or reforming.

Solvolysis involves the efficient conversion into high-value recycled products saving almost the same amount of CO 2 as dissolution. Although, for many of the recycling methods, if renewable energy is used for electrification, then the overall recycling process can also become more sustainable. However, this cannot be included during the LCA as this energy source is not directly related to the recycling method and will J o u r n a l P r e -p r o o f therefore not be counted. Variation in the life cycle assessment is mainly caused due to the differences in the carbon content of the material and energy requirements of production. Differences may also be observed based on the plastic-type being assessed, because of melting point, tensile strength, viscosity, and energy content that affect the process parameters (Vollmer et al., 2020) .

Bearing in mind, the many ways in which plastics affect the environment through different stages of their life cycle, polymer production in the future can be looked at more sustainably. For example, using CO 2 -derived methanolwill further decrease the emissions. (Fig.8) . The LCA of products also clearly indicates that the technologies that causes the least structural breakage/ bond breakages produce a higher quality of recycled products and also less harm to the environment (Schwarz et al., 2021) .

Moreover, by including the cost of CO 2 emissions in the final product, polymers produced from fossil sources will become more expensive, encouraging more manufacturers to go for sustainable and recycled plastic polymers (Vollmer et al., 2020) .

The life cycle assessment is aimed towards a circular economy than a linear one ensuring minimum wastage. In the case of plastic products, working towards a circular economy would imply constantly trying to produce monomers and oligomers to be re-polymerized after purification for the same or different applications.

Increasing the use of some novel technologies discussed in the previous sections like dissolution/precipitation, chemical recycling technologies, and other up-cycling methods will help us pave the way to reach the goal of a circular economy for plastics (Glaser et al., 2022) . It will also help increase the current trend of recycling ( Fig.1) , and at the same time provide alternative solutions (Vollmer et al., 2020) .

The fact that plastic usage has significantly improved our lives is undeniable, but since their disposal and management have become an even bigger issue, we must find more sustainable alternatives to the same (Patrício Silva et al., 2021) . For such J o u r n a l P r e -p r o o f measures to be adopted into the mainstream, there must be a good collaboration among all the top stakeholders who are ready to invest in more sustainable methods and products. Along with them, the government also must make strict regulations, and standardize product quality. There must be taxes/penalties imposed on CO 2 emissions that take into consideration the environmental costs. This will greatly increase the cost of fuel-based plastic usage and encourage more sustainable options. It will also encourage the adoption of newer disposal methods (chemical recycling/bio-degradation) which are less harmful to the environment. Similarly, stricter regulations on the design of packaging materials, will ensure more recycling.

Further, we must focus on research and innovation that produces newer products from plastics having higher quality and value (Vollmer et al., 2020) .

The concept of circular economy is a wholesome approach towards the economy, by taking into consideration its impact on all fields of business, society, and the environment. It is a system that works towards constantly keeping a product in use, until it has been used up to its full potential, and generated the least or no amount of waste. Adopting such a system will have a progressive impact on our economy as well as the planet. These firm steps taken today can reduce the CO 2 emissions in the atmosphere by almost 50% in the next 10 years (Bucknall, 2020) .

Some of the novel methods being developed in recent times that might help us work towards this goal are discussed below:

Bio-based plastics (polymers that are partially or completely derived from biomass), have been emerging as a sustainable (although short-term) alternative to conventional plastics, by replacing fossil fuel with renewable resources . These biopolymers are synthesized from biological sources such as plants, microorganisms, animals, etc. Bio-polymers adopt the properties of synthetic polymers showing effective moisture resistance, long shelf-life, and high tensile strength (Bhatia et al., 2021) . In addition, bio-based plastics have the potential to J o u r n a l P r e -p r o o f decrease carbon footprint and increase recycling targets such as home composting and waste management efficiency. Due to their adjustable degradation rates and sustainable thermophysical properties, aliphatic polyesters (e.g., polylactic acid, PLA and polyhydroxyalkanoates, PHA) and furanic-aliphatic polyesters (e.g., Polythene2,5furandicarboxylate, PEF and Polythene2,5-furandicarboxylate-co-polylactic acid, PEFco-PLA) are of particular interest as building-blocks for PPE and other single-use plastics (Siracusa and Blanco, 2020) ).

One of the limiting factors for the industrial application of mass PHA production is the cost of raw materials like pure carbon and nitrogen. Widely available waste organic material can be used as an option for cost-effective PHA production. Waste generated from industries (dairy, food processing, biodiesel, etc.), household, and municipal waste are surplus and available throughout the year to be utilized as feedstock for microbial fermentation and PHA production. The availability of the feedstock in a particular geographical region must also be taken into consideration (Bhatia et al., 2021) .

Another important aspect of the PHA synthesis process is selecting the PHA accumulating microbe. Over 300 species of microorganisms have been identified (and several more under investigation) that can accumulate PHA granules in a cell.

Some well-explored microbes that can utilize a variety of carbon sources for producing different types of PHA are Ralstonia, Pseudomonas, Halomonas, Burkholderia, Rhodospirillum. The modifications in the metabolic pathway in the PHA synthesis is one of the crucial strategies to produce the desired type of PHA copolymer. There are several aspects of production contributing to the high costs of PHA, like the slow growth of microorganisms, high energy requirements for sterilization and aeration processes, low rates of conversion of raw materials to PHA and expensive downstream processing. Further research in this area should focus on the aforementioned issues about the high cost of PHA and address methods in which J o u r n a l P r e -p r o o f the same can be overcome allowing PHA to be synthesized on a much larger scale (Bhatia et al., 2021) .

To address the problem, we must dive into the root of it which, in this case, lies in the design of the plastic product itself. If the plastics are designed with the intent of recycling, then the recycling of plastic polymers could be done far more easily. We can produce 100% poly-olefinic plastics without using any additives and they can degrade during melting and re-extrusion processes. If such polymers could be designed, they degrade under predetermined conditions into their monomers or oligomers, which would be a key step forward in the recycling of plastics (Vollmer et al., 2020) .

Thermoset plastics have covalent cross-links with permanent networks that are difficult to reshape, reprocess or even recycle. Vitrimer type plastic, an innovative and novel discovery by Leibler and his co-workers (ref), are also cross-linked polymers but they have dynamic covalent networks. These dynamic networks can be rearranged by using higher temperatures or other stimuli, allowing them to be recycled without losing their strength and original properties. In the mechanochemical process of vitrimerisation, metal-carboxylate ligands are formed. These serve as junctions for the transesterification reactionThis practical design will help provide new insights into the possibility of eliminating "end-of-life" thermoset polymers (Yue et al., 2020) .

An early and critical lagging in the overall planning for efficient implementation of plastic waste management is the reason for the rise of another bigger environmental crisis during the ongoing pandemic. The statistical data on the extra plastic waste generated from PPE and medical waste, apart from the normal waste that was being J o u r n a l P r e -p r o o f produced before the pandemic, is truly very shocking. It is therefore important that we focus our attention on new and innovative methods of plastic production, such that it will help us easily handle the waste thus generated. There is a dire need for people worldwide to move beyond the linear economy and work towards a circular economy. The pandemic has pushed us to be more alert and prepared for such a situation, if and when it arises in the future. The scientific community, corporate society, and government institutions, all over the world must come together to help in the development of more sustainable methods and encourage them by providing the necessary economic and social support.

The COVID-19 pandemic has given us the necessary push that was needed to start taking the plastic management issue more seriously. Keeping in mind the different methods of repurposing and recycling plastics discussed earlier in this paper some recommendations to work towards a sustainable environment and circular economy are as follows:

 As the number of cases is rising rapidly, there is a dearth of PPE kits for frontline workers. To meet these demands, it is necessary to encourage, the new innovations and research working towards the production of eco-friendly and reusable PPE kits. This method makes plastic polymers almost immortal, thus encouraging continuous reuse of the polymers for different purposes.

 The usage of cloth masks must be encouraged among the general public, rather than single-use commercially available plastic masks. Since the general public is less prone to exposure to the virus compared to health care workers who are close to affected patients, the usage of cloth masks provides a good amount of protection.

 When it comes to plastic polymers in medical kits, it is rather difficult to replace them with these types of equipment. To reduce wastage in this area we can consider the thorough sterilization and reuse of materials such as J o u r n a l P r e -p r o o f pipetting tips and testing plates wherever feasible. The usage of eco-friendly swabs can also be considered in place of plastic swabs.

 Microbial degradation is one of the most recent and promising fields of research to degrade plastic polymers. These microbes have the unique ability to degrade and utilize carbon, hydrogen, nitrogen, etc. from plastic polymers for their growth. They release enzymes that are produced either as extra or intracellular enzymes that can degrade the polymers. The only disadvantage in most microbial degradations, however, is the time factor. Deep analysis and research in this field will surely help us in developing environments that increase degradation in a shorter amount of time.

 A combination of different sterilization and repurposing methods that have been discussed earlier in this paper must be studied well and developed in such a way that it allows maximum usage of the polymer and results in a minimum amount of wastage. The use of automation and robotics integrated with artificial intelligence (AI), machine learning (ML), and the internet of things (IoT) will play an important role in plastic waste segregation and recycling, especially during this pandemic.

 The government, corporate sectors, and scientific communities must all come together to develop and strictly implement laws regarding the proper disposal and treatment of plastic wastes. Further, setting up mobile treatment facilities temporarily at locations will help treat and get rid of the waste on-site.

Plastic usage in several forms during COVID-19 is continued to be imperative despite its harmful effects. The generation of plastic wastes in times of a pandemic, especially from test kits and PPEs for the frontline workers, is inevitable. We cannot completely ban the usage of plastic-based PPE or medical kits. Instead, we must find an ecofriendly alternative for them to lessen damage to the environment and landscape as against the current scenario. There must be an implementation of a few short-term and long-term activities that would decrease the deleterious effects of plastic residues released from PPE and COVID-19 test kits. Based on the discussion presented in the review, it is possible to get rid of these wastes using the methods highlighted. The majority of the methods discussed have their shortcomings in terms of cost, infrastructure requirement, or incubation time required to complete the process. To work towards a circular economy, a multifaceted/interdisciplinary approach is necessary to deal with the complexity of the problem. Among all the above methods, the microbial degradation approach (to degrade the polymers and to produce bio-based polymers from biowaste) seems to be advantageous.

Considering the number of different microorganisms and their specificity to the polymers, it would be apt to frame an ideal combination of microbes to deal with medical plastic problems. This method seems to have the least ecotoxicity and maximum advantage in terms of cost. There is a lot of scope for research on the degradation of plastic wastes. The collection and sorting infrastructure will also need to be improved, by implementing stricter regulation. Government policies must be put into place to make sure that such methods get maximum funding. This will help increase the demand for the same and in the long run slowly work towards reducing the cost of eco-friendly recycling and repurposing methods. Successful adoption of newer recycling methods will require the cooperation of researchers, the industrial community, and the government. Many new practices are already finding their way into real-world applications. Spreading knowledge and educating the youth about the same will only help newer innovations to come into the markets. Tables and Figures   Table-1 : Different Polymers, their Properties and Ecotoxicity. (Halden, 2010; Ouellette and Rawn, 2015; Okunola A et al., 2019; Gadhave, Vineeth and Gadekar, 2020; Jain et al., 2020; O'Dowd et al., 2020; Praharaj Bhatnagar, 2020; De-la-Torre and Aragaw, 2021; Haque, Sharif, et al., 2021; Haque, Uddin, et al., 2021) 

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A review on pyrolysis of plastic wastes', Energy Conversion and Management

Current plastics pollution threats due to COVID-19 and its possible mitigation techniques: a waste-to-energy conversion via Pyrolysis

Current plastics pollution threats due to COVID-19 and its possible mitigation techniques: a waste-to-energy conversion via Pyrolysis

Conserving Supply of Personal Protective Equipment-A Call for Ideas

Biowaste-to-bioplastic (polyhydroxyalkanoates): Conversion technologies, strategies, challenges, and perspective

Selection of heat treatment conditions and prevention of secondary microbial contamination of liquid sugar: practical remarks

Engineering Design Process of Face Masks Based on Circularity and Life Cycle Assessment in the Constraint of the COVID-19 Pandemic

Plastics as a materials system in a circular economy

Global shortage of personal protective equipment

Microbial Polyethylene Classification, quantification, fate, and impacts on human health

Degradation Rates of Plastics in the Environment

Degradation Rates of Plastics in the Environment

Chemical aspects of polymer recycling

Stability of SARS-CoV-2 in different environmental conditions

COVID-19 pandemic and healthcare solid waste management strategy -A mini-review

Polymer Mechanochemistry and the Emergence of the Mechanophore Concept

Plastic and its consequences during the COVID-19 pandemic

What we need to know about PPE associated with the COVID-19 pandemic in the marine environment

Non-Thermal Processing-Microwave, Editor(s): Carl A. Batt, Mary Lou Tortorello

Preventing masks from becoming the next plastic problem

Biodegradation of low-density polyethylene (LDPE) by mixed culture of Lysinibacillus xylanilyticus and Aspergillus niger in soil

Chemical Recycle of Plastics

Waste Material Recycling in the Circular Economy -Challenges and Developments

Polymers and Polymeric Materials in COVID-19 Pandemic: A Review

The future of plastics recycling

Catalytic cracking of HDPE over hybrid zeoliticmesoporous materials

Production, use, and fate of all plastics ever made

Kara Lavender Law, Production, use, and fate of all plastics ever made Sci

Study of microbes having potentiality for biodegradation of plastics

Are Reliable and Emerging Technologies Available for Plastic Recycling in a Circular Economy?

Industrial Applications of Ionic Liquids

Methods of Recycling

Methods of Recycling, Properties and Applications of Recycled Thermoplastic Polymers

The Next Generation of Sustainable Food Packaging to Preserve Our Environment in a

3 -Textile materials and structures for topical management of wounds

Polyethylene degradation by lignin-degrading fungi and manganese peroxidase

Disinfection technology and strategies for COVID-19 hospital and bio-medical waste management', Science of The Total Environment

Strategy for repurposing of disposed PPE kits by production of biofuel: Pressing priority amidst COVID-19 pandemic

Microbial Degradation of Plastics: New Plastic Degraders, Mixed Cultures and Engineering Strategies

Energy from waste: carbon footprint of incineration and landfill biogas in the UK

Review of Sterilization Techniques for Medical and Personal Protective Equipment Contaminated With SARS-CoV-2

Valorization of disposable COVID-19 mask through the thermo-chemical process

Microbial Degradation of Plastic: a review

Biofilm dispersal: mechanisms, clinical implications, and potential therapeutic uses

Limited utilization options for secondary plastics may restrict their circularity

Biodegradation of low density polyethylene (LDPE) by certain indigenous bacteria and fungi

Results from a preliminary study using social media and an online survey with Spanish consumers

Ecotoxicity testing of microplastics: Considering the heterogeneity of physicochemical properties

Managing Plastic Waste─Sorting, Recycling, Disposal, and Product Redesign

Plastics and the microbiome: impacts and solutions

Microbial reduction efficacy of various disinfection treatments on fresh-cut cabbage

Medical waste management/incineration

Leachates from plastic consumer products -Screening for toxicity with Daphnia magna

Portable HEPA Purifiers to Eliminate Airborne SARS-CoV-2: A Systematic Review. Otolaryngol Head Neck Surg

Engineering a microbial "trap and release" mechanism for microplastics removal

Upgrading of PVC rich wastes by magnetic density separation and hyperspectral imaging quality control

Tribo-Electrostatic Separation Analysis of a Beneficial Solution in the Recycling of Mixed Poly(Ethylene Terephthalate) and High-Density Polyethylene

The W2Plastics Project: Exploring the Limits of Polymer Separation. The Open Waste Management Journal

Plastic waste footprint in the context of COVID-19: Reduction challenges and policy recommendations towards sustainable development goals

Sterilization and Disinfection, Editor(s): Moselio Schaechter, Encyclopedia of Microbiology

Terminal sterilization of medical devices using vaporized hydrogen peroxide: a review of current methods and emerging opportunities

Terminal sterilization of medical devices using vaporized hydrogen peroxide: a review of current methods and emerging opportunities

Catalytic Pyrolysis of Plastic Waste: Moving Toward Pyrolysis Based Biorefineries

Current Technologies in Depolymerization Process and the Road Ahead

Microbial and Enzymatic Degradation of Synthetic Plastics

Microbial water quality and the detection of multidrug resistant E. coli and antibiotic resistance genes in aquaculture sites of Singapore

Polymers and the Environment

Public and Environmental Health Effects of Plastic Wastes Disposal: A Review

Plastic waste as a fuel -CO2-neutral or not?

Identification of Microorganisms Related to Microplastics

Putting on and Removing Personal Protective Equipment

(eds) Organic Chemistry Study Guide

Thermolysis of waste plastics to liquid fuel A suitable method for plastic waste management and manufacture of value added products-A world prospective

The selective dissolution/precipitation technique for polymer recycling: a pilot unit application, Resources, Conservation and Recycling

Plastics in the time of COVID-19 pandemic: Protector or polluter?', Science of The Total Environment

Increased plastic pollution due to COVID-19 pandemic: Challenges and recommendations

Plastic waste release caused by COVID-19 and its fate in the global ocean

Article on "Dealing with Medical Plastic Waste: An Aftermath of COVID -19

COVID-19 Pandemic Repercussions on the Use and Management of Plastics

Mechanical and chemical recycling of solid plastic waste', Waste Management

Chemical recycling of waste plastics for new materials production

Plastic pollutants: effective waste management for pollution control and abatement

Molecular mechanisms of ultraviolet radiation-induced DNA damage and repair

Effects of ionizing radiation on biological molecules--mechanisms of damage and emerging methods of detection

Increased personal protective equipment litter as a result of COVID-19 measures

Detailed Analysis of the Composition of Selected Plastic Packaging

Production of methane and ethylene from plastic in the environment

Microbial Degradation and Valorization of Plastic Wastes

Disinfection, Sterilization, and Control of Hospital Waste. Mandell, Douglas, and Bennett's Principles and Practice of Infectious Diseases

Redefining bio medical waste management during COVID-19 in india: A way forward

Resource or waste? A perspective of plastics degradation in soil with a focus on end-of-life options

Plastic pollution solutions: emerging technologies to prevent and collect marine plastic pollution

Plastic recycling in a circular economy; determining environmental performance through an LCA matrix model approach

6 -Sterilization techniques for biotextiles for medical applications

Plastic pollution during COVID-19: Plastic waste directives and its long-term impact on the environment

Challenges, opportunities, and innovations for effective solid waste management during and post COVID-19 pandemic', Resources, Conservation and Recycling

Improper disposal of face masks during COVID-19: unheeded public health threat

Shortage of personal protective equipment endangering health workers worldwide (no date)

Alcohol-based hand sanitisers as first line of defence against SARS-CoV-2: a review of biology, chemistry and formulations

Comparative efficacy evaluation of disinfectants routinely used in hospital practice: India

Screening and Identification of Low Density Polyethylene (ldpe) Degrading Soil Fungi Isolated from Polythene Polluted Sites Around Gwalior City (m

Bio-Polypropylene (Bio-PP) and Bio-Poly(ethylene terephthalate) (Bio-PET): Recent Developments in Bio-Based Polymers Analogous to Petroleum-Derived Ones for Packaging and Engineering Applications

Key ingredients and recycling strategy of personal protective equipment (PPE): Towards sustainable solution for the COVID-19 like pandemics

Enhanced biodegradation of low and high-density polyethylene by novel bacterial consortia formulated from plasticcontaminated cow dung under thermophilic conditions

Deep Eutectic Solvents (DESs) and Their Applications Chemical Reviews

Low density polyethylene degrading fungi isolated from local dumpsite of Shivamoga district

Plastics, the environment and human health: current consensus and future trends

Microbial degradation of aliphatic polyesters

Municipal solid waste management during COVID-19 pandemic: a comparison between the current activities and guidelines

Hazardous metal additives in plastics and their environmental impacts

Degradation of plastics and plasticdegrading bacteria in cold marine habitats

Polymer composites for thermal management: a review

Can sterilization of disposable face masks be an alternative for imported face masks? A nationwide field study including 19 sterilization departments and 471 imported brand types during COVID-19 shortages

Challenges and strategies for effective plastic waste management during and post COVID-19 pandemic

Microbial degradation of plastics: Sustainable approach to tackling environmental threats facing big cities of the future

Disinfection technology of hospital wastes and wastewater: Suggestions for disinfection strategy during coronavirus Disease 2019 (COVID-19) pandemic in China

Plastic Degradation and Its Environmental Implications with Special Reference to Poly(ethylene terephthalate)

Microbial enzymes for the recycling of recalcitrant petroleum-based plastics: how far are we?

Plastic waste as a novel substrate for industrial biotechnology

Deep Dive into Plastic Monomers, Additives, and Processing Aids

Medical waste management -A review

Solvolysis

Assessing face masks in the environment by means of the DPSIR framework

Plastics degradation by microbes: A sustainable approach

Laser induced breakdown spectroscopy for plastic analysis

The authors express gratitude to NASI-INSA-IAS for funding the study and supporting Ms. Isiri with the Summer Research Fellowship (SRFP 2020-21).

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