A Review of Nonbiodegradable and Biodegradable Composites for Food Packaging Application

. The dependency on nonbiodegradable-based food packaging, increase in population growth, and persistent environmental problems are some of the driving forces in considering the development of biodegradable food packaging. This eﬀort of green packaging has the potential to solve issues on plastic wastes through the combination of biodegradable composite-based food packaging with plant extracts, nanomaterials, or other types of polymer. Modiﬁed biodegradable materials have provided numerous alternatives for producing green packaging with mechanical strength, thermal stability, and barrier performance that are comparable to the conventional food packaging. To the best of our knowledge, the performance of nonbiodegradable and biodegradable composites as food packaging in terms of the above properties has not yet been reviewed. In this context, the capability of biodegradable polymers to substitute the nonbiodegradable polymers was emphasized to enhance the packaging biodegradation while retaining the mechanical strength, thermal stability, barrier properties, and antioxidant and antimicrobial or antibacterial activity. These are the ultimate goal in the food industry. This review will impart useful information on the properties of food packaging developed from diﬀerent polymers and future outlook


Introduction
In line with country development and population growth, plastic pollution is an inevitable global issue caused by plastic usage in various daily activities.Plastic represents a material that is low cost, lightweight, and bio-inert with high mechanical properties [1,2].However, the production of numerous types of plastic has led to the overaccumulation of waste after use [3].Malaysia has recorded the highest annual per capita plastic packaging consumption with 16.80 kg per person on top of other countries, such as ailand, Vietnam, China, Indonesia, and the Philippines [4].Consequently, the accumulation of mismanaged plastic wastes in the environment will directly affect human health, soil pollution, water contamination, animal life, and economic losses [5][6][7].For instance, the accumulation of ∼2 tons of plastic per day in one of the Indonesian coastal areas is shown in Figure 1 [8].
e globally generated pandemic-associated plastic wastes from different sources (medical waste, personal protection equipment, and online packaging) have surpassed 8 million tons, resulting in the discharge of more than 25,000 tons to the ocean [9,10].
To date, there are three common routes for removing plastic wastes, which are mechanical recycling, energy recovery, and landfill.Most consumers might think that recycling is the most environmentally friendly approach to manage plastic wastes.However, the multilayers of different polymers result in some complications, whereby they should be separated according to the same kind, resulting in only less than 14% of the plastic wastes that are actually accepted for recycling [11,12].e usage of single-use plastics such as straws, coffee stirrers, and water bottles also affects the environment [13].e release of toxic gases during incineration and reduction in plastic waste of up to 95% could affect the environment, human health, and energy recovery [14,15].Rujnic-Sokele and Pilipovi also revealed that waste disposal areas may exhibit a particular issue in the release of methane gas because a gas collection system is lacking, leading to several thousands of illegal dumps [11].In 2016, from a total of 25.80 metric tons of plastic wastes in Europe only 29% were recycled, whereas more than 30.80% of the wastes were landfilled [16].
e food industry is a primary sector, which contributes to the accumulation of plastic packaging.
e international plastic industry has escalated to 322 million tons [18].In 2015, a total of 49 million tons of plastic were utilized as food packaging and the disposal of used packages had caused a great impact on the environment.It is generally noted that the primary aspects of packaging are to secure food from exterior environmental damage (physical, chemical, and biological), maintain quality, and increase the service life in addition to food safety.Besides, packaging also facilitates the storage and transportation of products [19,20].
erefore, packaging materials were examined not only with respect to their performances in terms of mechanical strength, thermal stability, barrier properties, and freshness of packed food, but also with respect to their biodegradable and sustainable resources to replace nonbiodegradable materials [21,22].
Studies on nonbiodegradable and biodegradable composites for food packaging application are reported here.e polymers covered in this review were polyethylene, polypropylene, polyvinyl chloride, polystyrene, and polyethylene terephthalate for nonbiodegradable-based composites.Meanwhile, cellulose, gelatin, polylactic acid, polyhydroxybutyrate, polycaprolactone, and polybutylene succinate were reviewed for biodegradable-based composites.e properties for both composites were highlighted based on its biodegradation, mechanical strength, thermal stability, barrier performance, and antioxidant and antimicrobial or antibacterial activity.Figure 2 shows the workflow overview of this study.
Superior mechanical and thermal properties, high barrier performance, good antimicrobial and antioxidant activity, and improved biodegradation (Figure 3) [23][24][25][26][27] are the key features that attract the demand for commercial packaging materials [28].Mechanical properties determine the film stability to prevent premature failure or cracking during handling, storage, and transport [29].Tensile strength (TS) can be defined as the maximum amount of tensile stress resisted by a material before breaking.e strain to break a material represents the elongation at break (EB), while modulus refers to the slope of linear elastic deformation of a stress-strain curve created during the tests conducted on a sample [30].To obtain composites with excellent mechanical properties, it is of utmost importance to study their morphology [31].Besides, the thermogravimetric analysis measures the weight change in a sample during heating.is technique enables a good insight into the specific thermal behavior of polymeric materials, which is related to their composition and structure of material due to chemical reactions or physical changes [29,32].Barrier properties determine the capacity of film to minimize moisture transfer and water permeability from internal or external environment through the food packaging [33].It is necessary to keep the moisture levels as low as possible to prolong the shelf life of food [28].Low barrier oxygen permeability presents a key factor for oxidation reaction, which contributes to food quality degradation, whereas the presence of carbon dioxide gas may prevent bacterial and fungal growth on food products [34].Oxidation is one of the primary reasons for food spoilage and nutritional loss, which occur during food processing and storage.e incorporation of antioxidant or antimicrobial agents into or as coating for the food packaging materials is an innovation to substitute the traditional food packaging as compared to the use of agents in the food itself [35,36].Packaged fresh food with high moisture content will lead to the growth of microorganisms, and thus, antimicrobial food packaging has received great attention in developing food packaging to overcome this problem [37].
e most widely used antimicrobial nanoparticles are nanoclays, silver nanoparticles, zinc oxide, and functional biopolymers such as chitosan [38].Lastly, the biodegradable property of a material is defined as its ability to be decomposed due to the action of microorganisms [39].e use of biodegradable polymeric materials over nonbiodegradable materials is a good solution in preserving the fossil resources and reducing environmental pollution [40].During the biodegradation process (Figure 4), polymers are broken down into smaller  Journal of Chemistry molecular fragments (oligomers, dimers, and monomers) in the presence of specific enzymes secreted by microorganisms, which are ultimately converted into biodecomposed products, such as water and carbon dioxide (aerobic conditions) and biomass, methane, and hydrocarbons (anaerobic conditions) [17,39].Biodegradation can be carried out by various techniques such as aerobic biodegradation (soil and composting environment) and anaerobic biodegradation (enzymatic hydrolysis) [41][42][43][44].e environmental conditions, test conditions, and type of polymer affect the rate of decomposition.A comprehensive review of these techniques has been done previously [45][46][47].
Biodegradable polymers can be classified into three groups: I) polymers derived from biomass, proteins, and polysaccharides; II) synthetic polymers derived from biomass-derived or oil-based monomers, polybutylene succinate (PBS), and polycaprolactone (PCL); and III) polymers originated from microorganisms, polyhydroxyalkanoates (PHAs), or polyhydroxybutyrate (PHB) [48].e comparison between nonbiodegradable and biodegradable materials in terms of degradation rate is listed in Table 1 .It was pointed out that the degradation rate of nonbiodegradable polymer was lower than that of biodegradable polymer.In fact, the compact and long carbon chains of synthetic plastics were difficult to degrade by microorganisms [14].Generally, the biodegradability of a polymer could help the biodegradation process of the base material [77].
e incorporation of biomass filler could enhance the degradation rate of both polymers due to the hydrophilic nature of the filler, which facilitated the microorganism attack on the surface of composite.It is known that microorganisms will consume the filler and cause a fracture in the polymer chain, which results in a higher degradation rate of modified composite with respect to the neat [78].In a soil degradation test, it was found that the decomposition of lowdensity polyethylene (LDPE) composites was in line with the degradation of natural polymer, accelerating the degradation rate of plastic due to the presence of starch in blend composites [79].Horvath et al. reported that Kenya, a country in East Africa, took a bold step in banning plastic carrier bags as a result of 100 million plastic bags being supplied by the supermarkets in 2017 [80].Biodegradable food packaging is one of the best efforts to solve the problems of nonbiodegradable-based counterpart as the latter tend to remain in the environment for hundreds of years [81].Most authors have reported that the modification of biodegradable polymers displayed improvement in the mechanical, thermal, barrier, and antimicrobial properties while maintaining the stability and extending the shelf life of packaged foods such as fish, cheese, and fruits [82][83][84][85].e utilization of biodegradable polymer seems to be a promising material for food packaging.
is review article emphasizes the properties of biodegradable composite to substitute the utilization of nonbiodegradable composite in terms of biodegradation, mechanical strength, thermal stability, barrier properties, and antioxidant and antimicrobial or antibacterial activity to meet the basic requirements of food packaging.

Nonbiodegradable Composite
Ho et al. reported that the worldwide production of synthetic polymers has reached 322 million tons per year, in which 20%-30% of municipal solid waste volume in disposal areas were represented by plastics [86].Most synthetic plastics were designed to be of lightweight, with good mechanical properties, high thermal stability and durability, and high resistance to environmental degradation [87].A literature survey conducted among Malaysian food hawkers in Kuala Selangor indicated that almost 33% of respondents used plastic bags to pack their food [88].Generally, this "white pollution" has generated great concern due to its hydrophobic properties, leading to their long lifetime of hundred years in natural environment [89].
e combination of nanomaterial or other polymers with the film base could improve the barrier performance and mechanical and thermal properties as compared to the use of a single polymer [90].erefore, several recently published articles on the modification of nonbiodegradable composite-based food packaging are discussed thoroughly in the following sections.

Polyethylene (PE).
Polyethylene (PE) is the first polyolefin material with an enviable and continuous growth in the food industry since the 1940s [91].ere are two main types of PE (Figure 5), which are low-density polyethylene, LDPE (many short-and long-chain branching), and highdensity polyethylene, HDPE (low amount of branching), in which LDPE exhibits a lower degree of crystallinity than  Journal of Chemistry HDPE [92].Among the other PEs, LDPE is suitable for food packaging owing to its favorable moisture barrier and high thermal stability along with excellent resistance to abrasion and chemicals [93].Although the merging of low cost, nontoxicity, superior sealing performance, excellent mechanical strength, and thermal and chemical resistance makes this PE to be widely used, its low barrier properties could limit its use for food packaging application [94,95].e chemical structure of PE is shown in Figure 6.He et al. aimed to evaluate the quality and stability of garlic cloves packed in PET, PE, aluminized kraft paper (AKP), single kraft paper (SKP), and mesh bag (MB) after 180 days of storage at −2 °C [95].It was clearly seen that the PET, PE, and AKP that contained the garlic cloves did not show any germination during storage.Conversely, about 100% germination rate was achieved for the cloves packed in SKP and MB after 90 days of storage due to the low ability to prevent water and gas from passing and thus accelerated the germination rate of garlic.Garlic cloves packed with PE recorded the lowest respiratory intensity with 12.25%, while the highest respiratory intensity of garlic cloves stored in AKP by 149.30% was observed after 120 days of storage in contrast to 0 day of storage (34.85 mg•kg −1 h −1 ).After 90 days, there was no significant change in the water content of garlic cloves packed in PE and SKP.erefore, PE can be regarded as the most effective packaging material, which effectively reduces the deterioration of garlic clove cell membrane.
Eyssa et al. investigated the capability of irradiated HDPE with different nanoparticles: ZnO or Ag to preserve the stored grains of wheat [96].e prominent increment in tensile strength (TS) incorporated with higher nanoparticle concentrations and irradiation doses was demonstrated due to the effect of radiation-induced crosslinks.As a result, the TS was boosted up to 177% and 158% by incorporating both 2 wt.%ZnO and Ag, respectively, with the optimum dose at 75 kGy than the unirradiated HDPE (12.86 MPa). is  6 Journal of Chemistry behavior was related to the reaction between zinc ion in ZnO and lone pair of electron on oxygen atom in vinyl triethoxysilane (VTES) coupling agent, giving a homogenous dispersion of ZnO into the HDPE film.Notably, inverse data were obtained for both nanocomposites with the reduction in elongation at break (EB) by increasing nanoparticle concentrations and radiation dose (75 kGy).Even though the HDPE film was more thermally stable than that of nanocomposites, the irradiation was helpful in improving its thermal stability.Interestingly, HDPE/2 wt.% Ag nanocomposite film with a dose of 75 kGy presented the best formulation along with 100% mortality rate toward Sitophilus granaries after five days of storage.e impact of PE/PP film assisted with alkali-treated wheat straw (WS) was explored by Dixit and Yadav [97].e response surface methodology (RSM) showed that the optimum variables of 1.80 g PE, 1.20 g PP, and 1.20 g treated WS yielded 45.02 MPa TS (tensile strength), 120% EB (elongation at break), and 51.74 g•m −2 day −1 WVTR (water vapor transmission rate).A notable decrease in TS and EB was observed in both composites with values of 26.88%; 5.85% (native WS) and 3.20%; 2.07% (treated WS), respectively, than the neat PE/PP matrix (46.50 MPa TS; 122.05% EB). e poor interfacial adhesion between polymer and native WS was the reason behind the significant reduction in mechanical property for PE/PP/native WS.Apart from that, the WVTR increased for both composites, as evident by 178.11% (native WS) and 9.24% (treated WS) with respect to the PE/PP matrix (47.50 g•m −2 day −1 ).e surface roughness and good compatibility of treated composite film represented much better barrier properties.However, both polymeric composite films still maintained their hydrophobic properties.
is suggested that the inclusion of treated biomass in polymer matrix could widen its usage for green packaging.e fabrication of active packaging, which is composed of LPDE-based film and polyisoprene natural rubber, was evaluated by Gaikward et al. [98].roughout the study, 20 wt.% polyisoprene possessed optimum mechanical strength with 12.72% (TS) and 10.62% (EB), whereas 5 wt.% polyisoprene showed much better barrier properties with the lowest increment values for oxygen transmission rate, OTR (41.59%), and water vapor permeability, WVP (10.34%), with respect to the neat LDPE (6.13 MPa; 121.39%EB; 353 cm 3 •m −2 day −1 OTR; 5.80 is might refer to the interaction between LDPE and polyisoprene leading to higher strength, while the hydrophilic characteristic of polyisoprene was the reason for higher WVP.For thermal stability, the addition of polyisoprene does not significantly influence the thermal degradation of LDPE composite film.Overall, about 14% bacterial reduction seems to be related to the absence of oxygen for beef jerky packed with LDPE/20 wt.% polyisoprene film after 90 days of storage as compared to the LDPE film.

Polypropylene (PP).
ere is an ever-growing interest in the development of polypropylene-based packaging as it can be utilized in food contact applications, especially for microwavable food container [99].PP (Figure 6) has a linear hydrocarbon chain, which only consists of carbon atoms in its structure with hydrophobic properties [8].Scanning the literature review, PP undeniably has been one of the outstanding polymers due to its low cost, low water vapor transportation, gas permeability, excellent resistance to chemicals, and abrasion along with high-temperature durability [100].Despite their remarkable characteristics, the difficulty in degradation and poor oxygen barrier of PP restrict this material from being widely used in the food industry [101].e performance of PP composites, which comprised of organically modified montmorillonite (OMMT) with iron nanoparticles, was reported by Khalaj et al. [101].e introduction of 2 wt.%OMMT boosted the mobility distance of the gas molecules, leading to a reduction in OTR and WVTR by 22.22% and 33.33%, respectively, in contrast to the neat PP (1.80 cm 3 •m −2 day −1 OTR; 0.60 g•m −2 day −1 WVTR).Meanwhile, the insertion of 0.2 wt.% nanoparticles resulted in the decrement in permeability of neat PP by both 55.56% (OTR) and 76.67% (WVTR).is might be due to the nanoparticles, which increased the intercepting and scavenging of oxygen through a chemical reaction.Moreover, a slight improvement in thermal stability (melting temperature, T m ) of about 0.98% was also noted with 2 wt.%OMMT/0.2wt.% nanoparticles as compared to PP/1 wt.% OMMT (T m : 163.90 °C).For mechanical strength, the highest increment was recorded at 2 wt.%OMMT/0.05wt.% nanoparticles with ∼17.86% (TS) and ∼81.82% (modulus) as compared to the neat PP (28 MPa TS; 495 MPa modulus).Overall, the incorporation of 0.05 wt.% iron nanoparticles and 2 wt.%OMMT into neat PP was recommended because the resulting composite exhibited superior barrier and mechanical properties.
Returnable seafood packaging that contained antimicrobial additive in PP-based film was discussed by Singh et al. to reduce the waste and carbon footprint [102].In contrast to the PP film (40.80 MPa TS; 5.05% EB), reduction of 13.94% TS with a slight increment of 0.67% elongation was noted in the case of PP/3 wt.% silver-zinc (AgZn) composite film, owing to the plasticization effect of additive in the matrix.e improvement in thermal stability was also associated with the presence of active material in the composite film.Further, the additive had reduced up to 99% bacteria for both Staphylococcus aureus (S. aureus) and Escherichia coli (E.coli) after 24 h with an optimum concentration of 10 wt.%.Meanwhile, about 50% of antimicrobial properties was observed after the fifth wash cycle, presenting superior action against Gram-negative microorganisms.e study declared that the silver ions played a key factor in the formation of reactive oxygen molecules and thus inhibited the bacterial respiration and subsequently reduced the deterioration and food-borne disease toward purchasers.
Prabhu and Devaraju described the influence of silver zinc, which contained zeolite coating on biaxial-oriented polypropylene (BOPP/SZZ) films for meat packaging [103].From this investigation, the BOPP/SZZ packaging film demonstrated significantly better barrier properties with regard to the OTR and WVTR with 16.17% and 69.03%, respectively, in contrast to BOPP film (4.76 cm 3 •m −2 day −1 OTR; 22.60 mg•dm −2 WVTR).e increase in coated SZZ-BOPP might be due to the silver ion, which improved the molecular bonding of aluminium on the film.Additionally, the antimicrobial activity was also successfully reduced up to 92.67% after 4 h and highly reduced to 98.50% for the next 24 h by inhibiting the following microbes: Listeria monocytogenes (L.monocytogenes), Clostridium perfringens (C.perfringens), Salmonella enteritidis (S. enteritidis), E. coli, and Campylobacter and thus proved the efficacy of SZZ as an antimicrobial agent in BOPP film.All in all, improved properties of the packaging film helped to extend the shelf life of meat for 10 days in a refrigerated storage.
e combination of sodium chloride (NaCl) treatment with PP packaging was figured out by Zhang et al. [104].According to the study, freshly cut ginger dipped in 0.05 mol•L −1 NaCl solution and packed with PP resulted in a minimum weight loss of ∼0.70% with retained firmness of up to ∼21.54% as compared to pure water combined with PP packaging (0.83% weight loss: 13 N firmness) after 20 days of storage.e inhibition of surface browning due to the NaCl treatment was proposed to be the reason for this behavior.It was found that in the case of the O 2 level the values of ∼3% (water + PP) and ∼2% (aq.NaCl + PP) were presented, but in the case of CO 2 level, the values of ∼7% (water + PP) and ∼8.30% (aq.NaCl + PP) were described.After 20 days, the antibacterial and antifungal reduction during the storage of fresh ginger was reported to be at 41.30% and 31.39%,respectively, in contrast to the water + PP packaging (4.14 log CFU•g −1 ; 4.11 log CFU•g −1 ).Overall, the ginger treated with NaCl combined with PP packaging had the best appearance quality.

Polyvinyl Chloride (PVC).
e utilization of around 39.3 million metric tons in 2013 ranked polyvinyl chloride (PVC) (Figure 6) as the third most applied thermoplastic-based food packaging after PE and PP [105,106].Meanwhile, consumer demands with regard to low cost, lightweight, superior chemical resistance, and barrier toward burning, as well as great desire for fresh products, are also driving this escalation [107].e major disadvantages of PVC as food packaging are high stiffness with poor flexibility, low thermal properties, and difficulties in melt processing.In fact, the high chlorine content and stability of PVC have influenced the disposal and treatment of PVC waste as the incineration process could contribute to the emission of hydrogen chloride and organic halogen compounds [108,109].
In recent years, Braga et al. synthesized an active antimicrobial film of PVC, which contained silver (Ag) nanoparticles as an excellent alternative to modified atmosphere packaging (MAP) [110].e incorporation of 8 wt.% Ag into PVC film recorded an optimum thermal stability over other loadings.Surprisingly, the nanocomposite film of PVC/1 wt.% Ag and PVC/2 wt.% Ag demonstrated good antimicrobial activity against Fusarium solani (F.solani) and Bacillus subtilis (B.subtilis), respectively, as compared to the no inhibitory action of 4 wt.% and 8 wt.% Ag and neat films.
e lack of antimicrobial action was believed to be because of poor diffusion through the PVC matrix, which subsequently slowed the migration of Ag through the culture medium.e study also found that PVC/1 wt.% Ag was the best nanocomposite film in expanding the shelf life of bread for 15 days of storage than the PVC film (five days of storage).
Yadav et al. focused on the aptitude of graphene oxide dispersion in polyvinyl chloride/waterborne castor alkyd (PVC/WCA/GO) nanocomposite film [108] e GO was declared to be responsible for improving the mechanical strength of nanocomposite film as a consequence of homogenous distribution, polar-polar interaction, and hydrogen bonding formation of the GO with PVC/WCA matrix.
e PVC/ WCA/0.5 wt.% GO nanocomposite was more thermally stable than PVC/WCA film (T d : 315 °C), as evident by the increment of about 26.98%, relating to the strong hydrogen bonds and van der Waals forces that occurred among WCA, GO sheets, and PVC molecules.
is indicated that the prepared nanocomposite films were beneficial material for food packaging at an industrial scale.
e comparison between meat-packed conditions and atmosphere of normal air (PVC wrap) and MAP were evaluated by Chmiel et al. [111].Based on MAP, the lower O 2 and higher CO 2 levels were recorded by 68.80% and 24.90% than the initial levels with 75.70% and 20.20% (display case), respectively, after nine days of storage.e consumption of gas by bacteria, meat-specific enzymes, and gases exchange would be the cause of O 2 level reduction, whereas the use of oxygen for bacterial respiration led to the higher CO 2 concentration as their products.Moreover, meat in PVC wrap and in MAP stored in a cooling room could extend the shelf life until eight and more than nine days, respectively.is can be seen from the growth of Pseudomonas spp.around 64.80% (PVC foil) and 52.42% (MAP) after eight days.For the display case, the unacceptable quality was observed on day 7 for PVC wrap, while the acceptable quality was presented by MAP after nine days of storage.In short, MAP had the tendency to expand the meat shelf life by at least one and two days in the cooling room and the display case storage, respectively.e preparation of duo-functional PVC films with additive mixture (MA) as pure and encapsulated potassium metabisulfite for minimally processed apples was analyzed by Foralosso et al. [112].In terms of thermal stability, no thermal degradation difference was observed between the control film and the films incorporated with additives when the concentration of MA was increased.e insertion of 0.1 wt.% MA resulted in the lowest decrease in EB (machine direction) of about 32% than the neat PVC (187.60%).Meanwhile, 2 wt.%MA presented the best film among others, in which the bacterial reduction was achieved up to ∼25%, ∼29.09%, and 21.82% at 4 °C, 8 °C, and 20 °C, respectively, after 20 days as compared to the control film (4.80 log CFU•g −1 ; 5.50 log CFU•g −1 ; 5.50 log CFU•g −1 at 4 °C, 8 °C, and 20 °C).ese reductions might be due to the generation of antimicrobial effect via KM dissociation at the beginning of storage.Meanwhile, EKM within silica matrix may require a longer time to generate SO 2 antimicrobial, keeping the reducing effect for a longer period.Notably, the duofunctional PVC/2 wt.% MA film has higher ability to extend the life span of cut apples up to eight days of storage at 8 °C as compared to the PVC film (four days).

Polystyrene (PS).
Polystyrene-based food packaging occupies fourth place in the food industry, which is after PE, PVC, and PP [113].PS (Figure 6) is an aromatic polymer that is formed through the polymerization process of styrene monomers [114].Its unique characteristics, such as excellent mechanical properties, high thermal stability, low moisture penetration, ease of processing, and low cost, make PS as a high potential material for food packaging [115].However, the nondegradability behavior and high recycling cost of PS are the primary problems since it is highly stable and has a high molecular weight.Besides, the toxicity and recalcitrant compounds of PS also lead to environmental pollution, human health problems, and disruption of ecosystems [86,116].
Ibrahim et al. explored the efficiency of zinc oxide nanoparticles (5 wt.% ZnO) incorporated in PS-based food packaging [117].e thermal analysis demonstrated that the degradation temperature (T d ) of nanocomposites had increased by about 35.81% as compared to the neat PS (T d : 296 °C). is means that the presence of ZnO was responsible for delaying the decomposition rate of nanocomposites.It was worth to note that the prepared nanocomposites revealed a much better antimicrobial impact toward Staphylococcus aureus (S. aureus), Pseudomonas aeruginosa (P.aeruginosa), Candida albicans (C.albicans), and Aspergillus niger (A.niger) relative to non-inhibition properties of neat PS.In a similar study, Fakhri et al. mentioned that the combination of less than 1.5 wt.% ZnO with 3.5 wt.% nanoclay (C15A) in neat PS presented the optimum TS [115].Meanwhile, the range of 0.65 wt.% ˂ZnO˂ 1.5 wt.% and C15A > 3.5 wt.% resulted in maximum modulus.ese could be explained by the higher interfacial adhesion between both nanoparticles, contributing to the homogenous distribution inside the matrix.Overall, the composition of nanoparticles played a key role in the fabrication of nanocomposites as they tend to agglomerate and thus cause the reduction in mechanical strength.
e achievements of 99.90% bacterial reduction against E. coli for PS/ HPQM-neu and PS/HPQM-water (more suitable) specimens after 4 h with the ideal dosage of 1250 ppm HPQM were noted.
e interaction between the phenyl group and the silanol group (Si-OH) of Neusilin played a main factor in the reduction in bacteria.e minimal antibacterial usage did not alter the mechanical strength of PS doped composites.It was found that the significant reduction in antibacterial performance at different rates was revealed by all specimens for the immersion in water (80 °C), detergent solution (room temperature and 80 °C), and accelerated UV aging.It is recommended that the PS-based food container material is suitable for application at room temperature as thermal and UV aging factors could lead to polymer degradation.
Hegazy et al. studied the performance of low-density polyethylene/polystyrene/maleic anhydride/magnesium hydroxide (70 wt.% LDPE/30 wt.% PS/10 wt.% MA/5 wt.% Mg(OH) 2 ) blend nanocomposite toward gamma irradiation [119].e higher irradiation dose increased the TS of LDPE film and nanocomposite film, but a prominent decrease was observed at 40 kGy for LDPE.About 8.89% increment in TS was exhibited for irradiated nanocomposite due to the effect of crosslinking, with ∼55% decrement in EB as compared to the irradiated LDPE (9 MPa TS; 65% EB) at 30 kGy.Moreover, the incorporated Mg(OH) 2 nanoparticles as additive did not influence the mechanical properties of nanocomposite.As compared to the neat LDPE (T d : 397.30°C at 25 kGy; 386.20 °C at 0 kGy), the optimum thermal stability of nanocomposite increased by around 9.21% at 25 kGy as compared to 3.26% at 0 kGy.In conclusion, the irradiation method was beneficial to enhance the properties of prepared nanocomposite, especially in the food packaging sectors.

Polyethylene Terephthalate (PET).
Polyethylene terephthalate (PET), which belongs to the class of aromatic polyester, is the most well-known material used for beverage container [120].e condensation polymerization of PET (Figure 6) involves the esterification reaction of monoethylene glycol and terephthalic acid or dimethyl terephthalate [121].As compared to the other types, PET possesses superior mechanical strength, gas retention properties, thermal and chemical stability, and cheap material [122].Even though PET can be recycled, the presence of aromatic moieties makes PVC impervious toward hydrolytic degradation and microbial attack [122].
Ding et al. monitored the performance of black garlic using different types of packaging materials: polyethylene terephthalate bottles (PETBs), kraft paper bags (KPBs), and aluminium-laminated polyethylene bags (ALPBs) at 4 °C and 20 °C after 90 days of storage [123].According to data, the moisture content values of garlic stored in each packaging were reported to be in the order of ALPB (30.07%)>PETB (25.66%)>KPB (24.05%) at 4 °C.Meanwhile, the order of PETB (25.17%)>ALPB (25.10%)>KPB (22.73%) was noted at 20 °C.In terms of thermal stability, PETB presented the second highest with the stability of 3.03% (4 °C) and lowest stability of about 3.74% (20 °C) among others, as compared to the unpacked black garlic (T m : 56.1 °C).In similar types of study, Giuffre et al. clarified that the highest moisture content was presented by PET-packed raspberries (90.58%), whereas fruits without any film exhibited the lowest moisture content (87.73%) after nine months of storage in the freezer [124].
Antonis evaluated the storage conditions of PET bottles incorporated in olive oil for 12 months of storage [125].
eir findings indicated that the prominent differences in OTR at 15 °C were statistically significant for the total storage period as compared to bottles that contained oil kept at 30 °C and 40 °C.About 25% increment was revealed by the oil-containing bottles at 15 °C during illuminated environment relative to the unfilled PET bottle (8.00 cm 3 •m −2 day −1 ) after 12 months.e presence of humidity and oil penetration had increased the OTR.Meanwhile, the binding of water at polar sites of PET polymer could hinder the flow of oxygen to pass through, which resulted in a lower OTR for unfilled PET bottle.e thermal analysis indicated that significant changes in thermal properties were obtained within the first four months, among the filled PET and control bottle.In other types of PET modification, Essabti et al. achieved an OTR reduction of up to 94.87% with two coated layers of 1 wt.% chitosan:40 wt.% vermiculite nanoclay on 130 µm PET film (0.31 cm 3 •m −2 day −1 ) [126].
erefore, these improved barrier behaviors support its usage in food packaging application.
Ishtiaque et al. assessed the gas permeation on PET film coated with natural polyphenolic-gelatin mixture (PGM) [127].It was worth to note that the OTR and WVTR of PET-PGM film decreased by 22.56% and 23.08%, respectively, with regard to the PET film (82 cm 3 •m −2 day −1 OTR; 1.30 g•m −2 day −1 WVTR). is was reasonable because the coated PET film polymer structure became more powerful and resistant toward oxygen strong protective coating, owing to the reduction spaces in the coating with regard to the uncoated PET.Noh et al. also investigated similar characteristics with the incorporation of nanoparticles in PET-based food packaging film [128].e introduction of 2 wt.% graphene nanoplatelets (GNPs) demonstrated up to 99% reduction in OTR with the highest strength of ∼23.93% TS and ∼191.15%modulus as compared to the neat PET (28 MPa TS; 190 MPa modulus; 12.30 cm 3 •m −2 day −1 ).
Nayak and Khuntia evaluated the efficiency of PET-based film in conjunction with treated Moringa oleifera fruit fibers [129].Based on the fiber loadings, 20 wt.% fiber reinforcement had the optimum set of mechanical properties, which increased by 5.16%; 21.01%; and 4.60% (untreated) and 19.29%; 47.08%; and 13.70% (treated) for TS, modulus, and EB, respectively, in contrast to the neat PET (55.26 MPa TS; 2570 MPa modulus; 19.10% EB). e improved mechanical strength was undoubtedly related to the good adhesion between hydrophilic fiber and hydrophobic matrix.e need of chemical treatment of fiber should be considered as the presence of lignin could deteriorate the strength of prepared composites.From the viewpoint of thermal stability, the composite (T d : 540 °C) exhibited excellent stability than the neat PET (T d : 480 °C). is suggested that the utilization of fiber could convert the waste to wealth as it exhibited higher mechanical and thermal properties of final composite.
To sum up, the single-use nonbiodegradable composite exhibited excellent properties and performance as compared to the single-use biodegradable composite.
e constantly growing production of commercial food packaging has gained considerable attention due to their attractive properties.e degradation of nonbiodegradable-based composites is a great challenge as the composite is increasingly used and the demand is high.Efforts were made to overcome these problems through reuse and recycling, but most of the plastics are nonrecyclable.Consequently, the uncontrolled growth of nonbiodegradable plastic wastes has led to critical environmental pollution.Table 2 presents the additional uses of nonbiodegradable composites for food packaging application.

10
Journal of Chemistry

Biodegradable Composite
European Bioplastics Association has predicted that the worldwide production of biodegradable materials could escalate up to 108 6000 tons by 2022 as compared to the production in 2017 with 880 000 tons, a growth of 24% within five years [133].Biodegradable materials have a tendency to degrade completely by the action of microorganisms through the secretion of enzyme in natural environment.e degradation can also occur through mechanical, thermal, chemical, radiation, or biological processes [134].Kumar et al. declared that the utilization of modified biodegradable-based composite film has a higher potential to be applied in food packaging owing to its excellent mechanical strength [135].Even though biodegradable materials could preserve fossil resources and reduce environmental pollution, the higher price and poor barrier performance are the major limitation faced by biodegradable materials at an industrial scale [136].
erefore, some modifications on biodegradable composite-based food packaging are clearly described in the next section.7) is a polysaccharide chain, which consists of D-glucopyranose units connected by ß-1,4 glycoside linkages, with highly packed structure due to the inter-and intramolecular hydrogen bonds [137,138].Among biodegradable materials, cellulose is one of the world's most abundant renewable matter and an attractive natural polymer in the fabrication of green food packaging.Cellulose offers several advantages, including low cost, environmentally friendly, high mechanical strength, nontoxic,  12 Journal of Chemistry and the abundant functional groups in the structure, and has led to numerous interesting modifications [139,140].Although cellulose has a great potential as food packaging material, its high polarity results in much lower barrier properties [141].e comparison between nanocellulose (NC) film and recycled nanocellulose (RNC) film through the spray coating method was carried out by Shanmugam et al. [136].In contrast to the virgin film (0.003 µm•s −1 Pa −1 ), the increment of ∼50% of air permeability for RNC film was still accounted as a better air resistance for packaging application.Unlike air permeability, the WVP for RNF film increased up to 97.77% relative to the virgin film (1.79 × 10 −7 g•m −1 h −1 Pa −1 ).e low barrier properties of RNC film were related to the agglomeration during recycle process, and the utilization of homogenizer was suggested to completely break the formation of agglomerates within a cellulose nanofiber suspension.Interestingly, the RNC film had a tendency to maintain ∼70% of the strength of the NC film.In conclusion, this recyclable material was seen to be comparable with those of commercial packaging materials, such as PE, PVC, and PS.

Cellulose. Cellulose (Figure
Achaby et al. evaluated the performance of polyvinyl alcohol (PVA)/carboxymethyl cellulose (CMC) blend film with cellulose nanocrystals (CNCs) derived from sugarcane bagasse fibers [142].It was found that the strength of bionanocomposite with 5 wt.%CNC obtained an optimum increment of 82.96% and 141.23% for TS and modulus, respectively, than the PVA/CMC film (64.85 MPa TS; 1138.70 MPa modulus).ese indicated that the high aspect ratio of CNC and the interaction between matrix and CNC played a key role in the formation of hydrogen bonds, thereby improving the strength of bionanocomposites.However, the exceeded reinforcement of 10 wt.% CNC was not recommended as it tends to agglomerate in the matrix.Meanwhile, the added 5 wt.%CNC also showed a slight increase by 2.78% for thermal stability, while the WVP was reduced by 81.90% in contrast to the PVA/CMC blend film (T d : 288 °C; 1.16 × 10 −7 g•m −1 h −1 Pa −1 ).e higher barrier properties might be the cause of homogenous dispersion of CNC within the matrix and subsequently reduced the free volumes of the bionanocomposite films.Overall, these green bionanocomposite films with remarkable properties provide very interesting alternatives to nonbiodegradable-based food packaging.
e feasibility of biocomposite film of methylcellulose (MC) and crosslinker glutaraldehyde (GA) with extracted murta fruit (MU) was evaluated by Dicastillo et al. [143].Based on the results, the addition of 20 wt.% GA into MC/ MU film demonstrated about 55.57% reduction in swelling index, which was caused by the hydrophilicity reduction in crosslinked films as compared to the MC/MU/10 wt.% GA film (105.60).e reduction in EB and modulus by ∼35% and ∼64.91%, respectively, with ∼160% increment in TS for MC/MU/20 wt.% GA film was noted in contrast to the MC film (50% EB; 855 MPa modulus; 5 MPa TS).ese might be attributed to the strong interaction between matrix and crosslinker, which lowered the MC chain mobility, resulting in the enhancement of polymer strength, but reduced the flexibility of film.It was also emphasized that films that contained MU extract had reduced up to 99.90% of Listeria innocua (L.innocua) in regard to the no antimicrobial activity of MC film.
e decreased swelling index and improved mechanical strength with antimicrobial properties were achieved as the concentration of GA increased.
e evaluation on bacterial cellulose/guar gum (BC/ GG)-based polyvinyl pyrrolidone/carboxymethyl cellulose (PVP/CMC) hydrogel film was made by Bandyopadhyay et al. [77].It was noted that the combination of BC/GG and PVP/CMC film showed the least reduction in EB by 2% with the second-best increment in TS of 6.15% and 5.62% modulus in contrast to the neat film (23% EB; 24.40 MPa TS; 890 MPa modulus).Among all films, about 24.43% reduction in contact angle proved that the lower side of PVP/ CMC/BC/GG film was suited as packaging exterior as a result of its better hydrophobicity to prevent water permeability than the PVP/CMC film (61.40 °).Again, PVP/ CMC/BC/GG film presented the lowest WVP and OTR values in contrast to the control (8.28 × 10 −13 g•m −1 h −1 Pa −1 WVP; 75 cm 3 •m −2 day -1 0.1 MPa −1 OTR) by ∼76.09% and ∼66.80%, respectively.is might be attributed to the interactions between each component in the film, thereby improving the barrier properties.Interestingly, the introduction of BC/GG improved its biodegradation rate by about 7% relative to the neat film (88%) after 28 days of burial.erefore, PVP/CMC/BC/GG film was found to be a potential competitor for packaging application as it can prolong the shelf life of fresh berries up to 15 days of storage.7) is one of the most published water-soluble proteinaceous materials, whereby it is obtained from animal collagen through the process of hydrolysis [144].e production of gelatin as a raw material continues to grow due to the high consumer demand, particularly in food and beverage sector (28.10%), nutraceuticals (25.80%), pharmaceuticals (21.00%), cosmeceuticals (5.50%), photography (13.50%), and others (6.10%) [145].Gelatin has gained great attention due to its unique characteristics, including low price, excellent film-forming ability, high binding potential with water and emulsifying properties, biodegradable, and also edible [146].Unfortunately, the poor strength, durability, and low barrier effects are the main drawbacks for gelatin [147].

Gelatin. Gelatin (Figure
e development of gelatin-based film incorporated with papaya peel microparticles was evaluated by Crizel et al. to preserve lard [148].e outcomes showed that the incorporation of 7.5 wt.% microparticles in gelation film significantly improved the mechanical properties by 124.93% (TS) and 125.85% (modulus) with the decrement of 171.63%EB versus the neat film (3.41 MPa TS; 1088.21MPa modulus; 338.30%EB). e increased TS was undoubtedly referred to the protein-protein interaction in film with microparticles and higher dispersion of the particles inside the matrix, giving a good tension transfer.Notably, the microencapsulation of papaya peel (7.5 wt.%) did not affect the WVP as it only increased to about 3.97% than the gelatin film (1.26 × 10 −6 g•m −1 h −1 Pa −1 ).Overall, the film with 7.5 wt.% papaya peel microparticle powder was recommended as it demonstrated the optimum antioxidant activity with 31.51% among other loadings, over the gelatin film (6.71%).e prepared film was found to be a good candidate for packaging application as the mentioned excellent properties were close to those of LDPE-based food packaging.
In addition, Soradech et al. investigated the edible surface coating, comprising 60 wt.% shellac and 40 wt.% gelatin [149].A difference of 2.50% in weight loss was recorded between uncoated banana (8.30%) and coated banana after 30 days of storage.Since the weight loss was closely associated with the firmness of banana, the firmness of coated banana (46 N) decreased around 52.17% in contrast to the 86.52% for uncoated banana (45.41 N) after 30 days of storage.e occurrence of depolymerization and deesterification of protopectin in the middle lamella of the cell walls were the main mechanisms, which contributed to the softening of the cell walls.As compared to the uncoated ones (6.54 log CFU•g −1 ), the banana coated with the composite film presented the best properties in which the reduction in molds and yeasts was achieved up to ∼38.84% at 25 °C after 30 days of storage.In conclusion, the utilization of edible coating film was proven to be successful in extending the life span of banana.
Oliveira et al. discussed the integration of cashew gum (CG) and gelatin (G) films in the making of detergent pockets, dissolvable films, and fertilizer encapsulants [150].Enhanced barrier properties were noted with higher content of gelatin, but 5 wt.%G/5 wt.% CG exhibited superior water vapor barrier than the control film (1.35 × 10 −6 g•m −1 h −1 Pa −1 ), which was reduced by 14.07% owing to the film compaction without pore formation.Conversely, the synergistic effect of 2.5 wt.% G/5 wt.% CG presented the highest flexibility of material with up to 114.03% EB among others, in contrast to the neat film (0.87%).
ermal stability indicated a slight decrease of around 5.28% for the G/CG film than the gelatin film (T d : 341.20 °C).As expected, the highest CO 2 production of the G/ CG film (311.11%)after 22 days of biodegradable test indicated higher biodegradation rate as compared to the gelatin film (9 mL CO 2 production).ese clarified that the use of G/CG film was discovered to be helpful as it showed higher ability in improving the biodegradation of final products.
Huang et al. evaluated the influence of electron beam irradiation on the antioxidants of bamboo leaves (AOB) and fish gelatin (FG)-based films [151].As compared to the unirradiated FG/AOB film (8.30MPa TS; 64% EB), 7 kGy of FG/AOB film had maximum TS and minimum EB, as measured by 54.22% increment and 14% decrement, respectively.ese behaviors were related to the intermolecular interaction and the formation of crosslinks that prevent the mobility of polymeric chains as a consequence of a denser structure formation after irradiation.Meanwhile, the FG/AOB film at 7 kGy resulted in higher increment in WVP with 81.82% in accordance with 33.60% reduction in contact angle relative to the unirradiated film (1.10 × 10 −6 g•m −1 h −1 Pa −1 125 °). e higher humidity conditions (∼100%) were the reason for these results, whereas the formation of a new bond after irradiation and increasing polarity on the film surface contributed to the lowered contact angle.Notably, the highest thermal stability for FG/ AOB film (7 kGy) was referred to the intermolecular or intramolecular interactions between FG and AOB with the aid of irradiation.

Polylactic Acid (PLA).
Polylactic acid (PLA), which is also known as polylactide, represents the most promising biopolymer not only in the academic sector, but also in the plastic industry, whereby it is already commercialized in the form of pure or blended polymers (i.e., food packaging) to meet the need for sustainable green composites [152][153][154].Apart from breaking down into smaller molecular weight by the presence of microorganism in the soil, the lactic acid monomers of PLA can also be produced via the fermentation 14 Journal of Chemistry process of renewable sources, which are obtained from corn, sugar, potatoes, and beet [152,155].e properties of PLA (Figure 7) such as good mechanical strength, biocompatibility, abundance, and environmentally friendly make it worthy of a massive study in PLA.However, brittleness, low thermal stability, and low barrier properties restrict its direct utilization in food packaging applications [156][157][158].e synergistic effect of 1 wt.%ZnO nanoparticles and 0.5 wt.% Ag nanoparticles in pure PLA film was explored by Chu et al. [159].It was pointed out that the PLA/Ag/ZnO nanocomposite increased by 6.87% EB and decreased by about 41.06% and 29.32% for TS and modulus, respectively, than pure PLA (5.35% EB; 47.48 MPa TS; 3118.79MPa modulus).ese behaviors might relate to the incorporation of antimicrobial agents, which decreased the interactions between PLA chains and improved the mobility of PLA chains.
e WVP of the PLA/Ag/ZnO nanocomposite (6.84 × 10 −8 g•m −1 h −1 Pa −1 ) was better than those of pure PLA (6.08 × 10 −8 g•m −1 h −1 Pa −1 ), owing to the hydrophilic properties of ZnO nanoparticles.Notably, the PLA nanocomposite showed good antimicrobial activity against E. coli in contrast to the no antimicrobial properties of control film.As presented by Altan et al., the incorporation of carvacrol in PLA fibers (T d : 346 °C) had increased thermal stability by about 8.96% due to the formation of hydrogen bonding between PLA chains and carvacrol molecules [160].Meanwhile, the addition of carvacrol did not influence the thermal stability of zein fibers.e study also highlighted that carvacrol-loaded electrospun zein and PLA fibers were promising alternatives in extending the shelf life of bread as it could inhibit 99.60% and 91.30% of the growth of mold and yeast, respectively, at 20 wt.% carvacrol content.
e preparation of PLA films incorporated with microcrystalline cellulose (MCC) derived from the wood pulp was carried out by Kale et al. [161].
e WVTR was 35.20 g•m −2 day −1 for the neat PLA film and increased slightly by 36.50 g•m −2 day −1 for the composite containing 2 wt.%MCC.Meanwhile, the film with 0.1 wt.% MCC had the lowest WVTR value (35.50 g•m −2 day −1 ). is might be due to the agglomeration of MCC particles in the PLA matrix, which provides a few void spaces, allowing more rapid permeation.As compared to the MCC loadings, 2 wt.%MCC obtained an optimum increment of 1.92% and 23.61% for TS and modulus, respectively, with 1.94% decrement in EB than the PLA film (26.04 MPa TS; 288 MPa modulus; 9.53% EB). e increased TS and stiffness of composite were related to the lowered EB.Interestingly, the degradation rate of composite films increased in line with MCC loadings.PLA demonstrated four main stages of degradation (water absorption, ester cleavage forming oligomers, oligomer fractions of solubilization, and diffusion of soluble oligomers by bacteria).e presence of 2 wt.%MCC was found to promote the biodegradation rate of PLA composite up to 448.00% in contrast to the PLA film after 90 days of burial.erefore, this study seems encouraging for the application of PLA/MCC composite films for sustainable food packaging.
Villegas et al. investigated the effect of thymol and cinnamaldehyde on PLA film and PLA loaded with 5 wt.% organoclay Cloisite 30B (C30B) via supercritical impregnation using carbon dioxide (scCO 2 ) [162].As a result, PLA scCO2 /C30B composite that contained thymol showed the lowest modulus and TS, which was reduced by 77.78% and 50%, respectively, in contrast to the neat PLA (2250 MPa modulus; 12 MPa TS). is can be explained by the plasticization effect of thymol, which reflected the decrease in both testings.However, the highest modulus of PLA/C30B composite confirms that organoclay can act as a reinforcing effect other than the good affinity between the C30B and the PLA matrix.It seems that all composites were applicable for food packaging purposes as the contact angle values were higher than 65 °, which indicated the hydrophobic properties.Surprisingly, the impregnated films with both active compounds showed superior antimicrobial activity against E. coli and S. aureus with the concentration of 17 wt.%thymol and 12 wt.%cinnamaldehyde.It was found that all the composites were fully composted, evident by 90% of disintegration in less than 14 days.
In another study, Rezaeigolestani et al. improved the properties of PLA composites by introducing Zataria multiflora Bioss essential oil (ZME), propolis ethanolic extract (PEE), and cellulose nanofiber (CNF) to preserve vacuum-packed cooked sausages [163].It was found that the PLA composite with only CNF demonstrated an increment of 32.92% and 20% for TS and modulus, respectively, with 9.70% decrement in EB in regard to the neat PLA (16.10 MPa TS; 1000 MPa modulus; 49.30% EB). e ability of CNF to produce tighter and more brittle composite simultaneously was the reason for these obtained results.In fact, the addition of ZME and PEE made stiff polymers (like PLA) more flexible due to the plasticization effect of additive in the matrix.As a result, the reduction of 27.95% TS and 28% modulus with an increment of 13.90% EB was noted in the case of PLA/1 v/v.%ZME/CNF/PEE composite film.e incorporation of 0.5 v/v.%ZME and 2 v/v.%PEE to the neat PLA (6.44 × 10 −14 g•m −1 h −1 Pa −1 ) had reduced the WVP by 11.17% due to the hydrophobic properties of essential oils.Interestingly, PLA/1 v/v.%ZME/PEE composite could prolong the shelf life of sausages to more than 40 days, relating to the best antibacterial activity of the composite.erefore, the superior reinforcing function of natural antimicrobial substances will expand the application of PLAbased composites as replacements for traditional petrochemical plastics, especially for food packaging applications.

Polyhydroxybutyrate (PHB).
Polyhydroxybutyrate (PHB) is a thermoplastic biopolyester derived from renewable resources by bacterial synthesis and one of the members of polyhydroxyalkanoate (PHA) family [164].Currently, the use of PHB incorporated with antioxidant and antifungal agents could be a means to extend the shelf life of refrigerated food [165].PHB (Figure 7) is gaining increasing attention due to its excellent moisture barrier, mechanical performance, crystallinity, and biocompatibility and is naturally compostable under both aerobic and anaerobic conditions [164,166].ese particular characteristics exhibit similar end-use properties with nonbiodegradable-based food packaging, thereby are potentially suitable to replace Journal of Chemistry the conventional plastics.However, it is still expensive and quite brittle for further uses [166,167].
Manikandan et al. described the fabrication of PHBbased film with graphene nanoplatelets (GNPs) [168].ey stated that the insertion of 0.7 wt.% GNP in PHB film demonstrated the best barrier properties, evident by the reduction of about 56.92% for WVP than the pristine film (1.50 × 10 −10 g•m −1 h −1 Pa −1 WVP).e insertion of impermeable GNP could form a tortuous structure inside the matrix and thus reduced the permeability.ese results were closely related to the extended shelf life of potato chips and milk until 245 days and 26 days, versus 60 days and 6 days for the control, respectively.Comparing the neat PHB (4.50 MPa TS; 15% EB), the TS was increased by 98%, whereas EB was decreased by 2.80% with 0.7 wt.% insertion of graphene.
ese could be explained by the uniform dispersion of graphene, which resulted in higher TS, while the high brittleness of nanofillers contributed to the lowered EB.Importantly, the 20% reduction in biodegradation was revealed by the nanocomposites after 30 days of burial as compared to the PHB film (100%) due to the antimicrobial effect of graphene in nanocomposite.
e modification of PHB film with thermoplastic starch (TPS), organically modified montmorillonite (OMMT), and eugenol (Eug) was evaluated by Garrido-Miranda et al. [165].e thermal stability study indicated that the presence of additives did not significantly influence the degradation temperature of PHB film (T d : 299.20 °C).Moreover, the modulus was decreased by 24.68% for the PHB/TPS film, while it was increased by 12.82% with the addition of OMMT as compared to pure PHB (1560 MPa).e existence of OMMT as reinforcing agent was responsible for improving the TS of bionanocomposite.e decline in TS by 45.45% for the PHB/TPS film and 38.84% for the bionanocomposites film was observed in contrast to the PHB film (24.20 MPa), relating to the incompatibility and lower interfacial adhesion between the added polymers.
e incorporation of Eug (2.5 wt.% and 3 wt.%) in bionanocomposites presented the optimum antioxidant activity with more than 90% in contrast to 5.07% PHB/TPS film and 2.35% bionanocomposites (without Eug).As compared to the other films, the bionanocomposites with eugenol successfully inhibited the growth of Botrytis cinerea, corresponding to the highest antioxidant activity.
Ma et al. compared the performance of plasticizers, namely mono-caprylin glycerate (GMC) and glycerol monolaurate (GML), in PLA/PHB blend film [169].e introduction of GMC and GML (both 0.5 wt.%) had increased the TS by 39.29% and 43.83%, but in the case of EB, both films showed a reduction with 6.71% and 7.90%, respectively, than the neat film (30.80 MPa TS; 13.60% EB).
ese might be attributed to the diffusion of plasticizer and cinnamaldehyde (CIN) into the amorphous region of PLA/ PHB polymeric chain, which resulted in higher TS, whereas the simultaneous action of increasing intermolecular force and reducing slippage led to a lowered EB.In contrast to the control (22.30g•m −2 day −1 WVTR; 3.78 × 10 −13 cm 3 cm•cm −2 s −1 Pa −1 OP), a statistical increase in WVTR and OP for both films was presented, evident by 211.66%; 17.20% (GMC) and 248.43%; 33.07%(GML), respectively, owing to the presence of the aldehyde group in CIN for each film.Interestingly, the shelf life of salmon dices packed with the PLA/PHB/GML film was prolonged up to 17 days in contrast to the deterioration of salmon dices packed with the PLA/PHB/GMC film after 15 days of storage.
e study stated that the reduction in TS at higher rubber loading might be due to the softening effect of rubber.Conversely, the higher TS in line with higher coagent loading was responsible for improving peroxide crosslinking efficiency, which led to an increased polymer strength.Meanwhile, the occurrence of polymeric chain scission and poor crosslinking efficiency were the reasons that TS was not affected by the added peroxide.e WVTR of the blend (38.90 g•m −2 day −1 ) was also comparable to the use of PPbased food packaging (23-31 g•m −2 day −1 ).As expected, the blend biodegradation rate was decreased by 9.90% than neat PHBV (24.70%), owing to the higher molecular weight of NR.
erefore, the development of PHBV/NR blend was considered as an efficient production to replace and compete with synthetic polymer packaging.

Polycaprolactone (PCL).
Polycaprolactone (PCL) is a synthetic biopolymer of aliphatic polyester synthesized by the ring-opening polymerization of ε-caprolactone [171].It has been widely used as a suitable biomaterial thanks to its great biocompatible, biodegradable, low-set processing temperature (60 °C), superior strength, and good barrier properties [172].Due to these reasons, PCL (Figure 7) is the most commonly used polymer based on food packaging, which was reported by Khalid et al. [173].Nonetheless, its low barrier properties and lack of mechanical strength are the weakness of PCL [174].
e fabrication of acetylated hemicellulose (AH)nanocellulose (ACNC) films coated with PCL film was evaluated by Mugwagwa and Chimphango [175].As compared to the PCL film (13.61MPa TS; 43.90% EB; 280.30MPa modulus), the TS and EB were decreased by 50.62% and 27.89%, respectively, whereas the increase in modulus by 19.63% was recorded for PCL-coated AH-ACNC film.Interestingly, the modulus of coated PCL film (335.33MPa) was close to that of the LDPE film (244.46MPa).However, there was no significant difference in terms of wettability properties between uncoated and coated PCL films.It was worth to know that the introduction of polyphenol in AH-ACNC/PCL film was helpful in increasing the antioxidant activity.As a result, the fatty food simulant (40 °C) recorded the highest antioxidant activity, which was caused by the highest discharge of polyphenols from the films over the other simulants.
erefore, the integrity of AH-ACNC/PCL film as active packaging has huge potential to substitute LDPE-based food packaging.
Ahmed et al. found that the combination of ZnO nanoparticles and clove essential oil (CEO) inside polylactide/polyethylene glycol/polycaprolactone (PLA/PEG/PCL) blend film could maintain the TS value (13.96MPa) with a significant improvement of about 136.10% EB in contrast to the blend film (13.97 MPa TS; 25.48% EB) [176].e finer nanoparticle distribution and lower interfacial energy between matrix and nanoparticles resulted in higher TS.Meanwhile, the plasticization effect of CEO improved the EB of nanocomposite film.e synergistic effect of ZnO and CEO had reduced the WVP of the base film by around 78.41% than the control film (5.65 × 10 −9 g•m −1 h −1 Pa −1 ).About 5.53% reduction in degradation temperature was noted, which indicated that the control film (148.40 °C) was more thermally stable than PLA/PEG/PCL/ZnO/CEO film.
e enhanced flexibility of polymeric chains as a consequence of plasticizing effect was the main factor that reduced the thermal stability of nanocomposite film.After seven days of incubation, the combination of 3 wt.%ZnO and 25 wt.%CEO was found to give the highest inhibition of S. aureus and complete inhibition of E. coli associated by the effect of active compound eugenol from CEO with the ZnO in contrast to no antimicrobial properties of control film.Overall, the prepared nanocomposite film was the best candidate for scrambled egg packaging.
Figueroa-Lopez et al. assessed the performance of multilayer systems, which consisted of gelatin (GEL) and electrospun PCL incorporated with black pepper oleoresin (OR) [177].As compared to PCL film (T d : 350 °C), the PCL/ GEL/PCL film experienced an increase in thermal stability by 5.71% when incorporated with active coating (oleoresin).
ese low barrier properties might be attributed to the hydrophilic character of GEL and the formation of a less continuous-film structure after adding OR, which led to higher permeation.However, the incorporated OR decreased the mechanical strength by 4.81% TS and 15.63% modulus with 1.90% increment of EB, in contrast to the PCL/GEL/PCL film (31.20 MPa TS; 15.50% EB; 883 MPa modulus).
e multilayer system that contained GEL, PCL, and OR provided a strong antimicrobial behavior toward S. aureus after 10 days of storage.
e decline in mechanical properties was undoubtedly related to the poor interfacial adhesion between matrix and GFSE and thus weakened the TS and EB, but in the case of modulus, the plasticization effect of glycerol in GFSE led to lower stiffness of polysaccharide film base.Among all the films, GFSE with 13 wt.% was suggested for further use, as it presented the optimum antimicrobial activity.e complete inhibition of E. coli and no mold growth were presented by salmon and bread samples, respectively, which were packed in PCL/chitosan/GFSE film as compared to the PCL/chitosan film after seven days of storage.As a conclusion, the synergistic effect of polymers was found to have a higher potential to enhance film properties in regard to the use of each polymer alone.

Polybutylene Succinate (PBS).
Polybutylene succinate (PBS) can be synthesized from polycondensation reaction of 1,4-butanediol with succinic acid [179].PBS is a special candidate for the new development of bio-based food packaging due to the results of low cost, good processability, improved thermal stability, and chemical resistance [180].Interestingly, the ester bond in PBS structure (Figure 7) can be chemically degraded by water or in the landfill through the action of microorganisms, in addition to the mechanical properties similar to commercially used PE and PP materials [181].Despite those attractive properties, their high light penetration and expensive material along with insufficient water vapor barrier restrain its use in the food industry [182].
Ayu et al. examined the effectiveness of PBS blend with five modifications of tapioca starch (A, B, C, D, and E) [183].
e incorporation of starch D increased the TS by 21.03% owing to the high crystallinity of amylose content as compared to the starch E/PBS blend (14.98 MPa) at 40 wt.% starch loading.
e lowest TS can be explained by the presence of high chain branches of amylopectin found in starch E/PBS blend.Generally, increasing the starch loading could lead to the weakening structure of the blend because of more void formation in the blend.In contrast, the rigidity of all blends was improved with higher concentrations of starch.Overall, the optimum loading for all types of starch should be less than 50 wt.% to achieve good tensile strength.Based on the starch types, the reduction in thermal stability was noted, but the high crystallinity of starch A, B, C, and D/ PBS blends revealed excellent thermal stability.To conclude, starch A, B, C, and D/PBS blends were proposed for food wrap and food container applications, whereas PBS/starch D blend was suitable for grocery plastic bags.
Recently, Wattanawong et al. assessed the fabrication of PBS film with the introduction of silver-loaded zeolite [184].Based on the types, the silver Zeolite Socony Mobil-5 (ZSM-5) was the best filler as it demonstrated the superior antibacterial activities toward E. coli and S. aureus.e incorporation of 0.5 wt.% AgZSM-5 into PBS film was sufficient to inhibit about 99.90% bacteria after 24 h incubation, relating to the bactericidal effect by silver ion.In contrast, the neat PBS presented 25% reduction in S. aureus with no antibacterial activity toward E. coli.
e presence of outer membrane layer of bacteria should be considered as it can easily absorb the succinic acid, resulting in the bacterial cell damage.Overall, PBS/0.5 wt% ZSM-5 film was found to be the optimum as it showed the lowest reduction of around 14.15% TS and 10.61% modulus with the highest EB by 8.81% relative to the neat PBS (47.29     Journal of Chemistry [185]. e incorporation of 2 wt.% and 10 wt.% thymol recorded the lowest decrement of about 10.86% TS and the highest EB value of around 5.12%, respectively, as compared to the pristine PBS (39.98 MPa TS; 17.46% EB). e lowered TS can be explained by the plasticization effect originated from thymol, which made the PBS/thymol film less stiff than PBS film.Meanwhile, the reduction in intermolecular forces between thymol and matrix resulted in higher elongation at higher rate.As compared to the control (63.19 ml mil•m −2 day −1 atm −1 ), the least increment of OTR by 3.69% with 2 wt.% thymol made it more suitable for food packaging.In regard to the plasticization effect, the increase in amorphous segment in the PBS film resulted in higher oxygen permeability.It was interesting to note that 6 wt% and 10 wt.% of thymol were found to be optimum toward S. aureus and E. coli, respectively.
Negrin et al. studied the influence of irradiation toward PBS-based film and poly(butylene/thiodiethylene succinate) random copolymer (PBS-PTDGS) films [186].e decreased thermal stability for all films with higher absorbed dose was due to the reduction in molecular number (M n ) caused by the degradation of polymer chains into shorter segments.
e residual M n of PBS film at 200 kGy was statistically decreased by 50% in contrast to 20% residual M n for P(BS60TDGS40).e PBS film (100 kGy) in water showed a 16.67% reduction (contact angle) as compared to the unirradiated PBS film (90 °), thereby improving the wettability properties.Meanwhile, the wettability of PBS-based copolymers was in line with the absorbed doses, particularly in air.After 52 days of burial, the irradiated PBS film portrayed more resistance to degradation, which is equal to 77% (air) than 40% (water) at 100 kGy as compared to 62% residual weight of neat PBS (0 kGy).Meanwhile, a slight improvement in biodegradation was shown by irradiated P(BS70TDGS30) copolymer in water (100 kGy) as compared to the treatment in air at the same dose.is proved that the utilization of gamma irradiation was very helpful in improving the biodegradation of PBS polymer.
To summarize, biodegradable materials have aroused as a sustainable alternative to lessen the dependency on nonbiodegradable-based plastics along with the development of a greener economy in regard to its biodegradable, biocompatible, renewable, and excellent properties.Based on the detailed analysis, it can be clearly seen that the modification of biodegradable materials has produced numerous candidates for food packaging, whereby the properties are comparable to nonbiodegradable counterparts.Table 3 lists the additional uses of biodegradable composites for food packaging application.

Conclusion and Future Perspective
is review summarizes the comparison on the performance of nonbiodegradable (PE, PP, PVC, PS, and PET) and biodegradable (cellulose, gelatin, PLA, PHB, PCL, and PBS)based composites for food packaging application.In this review, the important properties of biodegradation, mechanical strength, thermal stability, barrier properties, and antioxidant and antimicrobial or antibacterial activity were highlighted to fulfill the specification of food packaging.e issues, challenges, and suggestions regarding the production of food packaging were also discussed.
e selection of polymers can sometimes be limited, but the improvement in the integrity of biodegradable-based food packaging with plant extracts, nanomaterials, or other types of polymers is suggested as these materials can complement each other, resulting in a far superior final product.In short, the utilization of biodegradable composites is highly beneficial for the food industry sector.
Despite the fact that many studies have shown that the nonbiodegradable composites can produce a much better food packaging, there is an urgent need for further studies on the use of biodegradable-based food packaging, which may be helpful to replace the use of conventional packaging.It cannot be denied that the lack of market demand might be due to the high cost of green packaging, but the fact that nonbiodegradable-based packaging takes up to thousand years to disintegrate and breakdown completely in natural environment requires in-depth case studies on how biodegradable materials can reduce the high treatment cost of plastic waste management and limited landfill sites.
erefore, the identification of biodegradable-based food packaging is essential to ensure that the final properties of prepared packaging exhibit similar end-use properties with those of commercial packaging.
A global public awareness on the development of green food packaging should also be implemented to initiate the environmentally friendly lifestyle.Even though the impacts on plastic waste accumulation were highlighted, information on the influence of these global issues toward humans and environment is still insufficient.In this context, the involvement of the government is suggested to restrict the use of commercial food packaging to increase the demand toward green packaging products at an industrial scale.

Figure 2 :
Figure 2: Workflow overview of this study.

Figure 5 :
Figure 5: Schematic representation of the structure of (a) LDPE and (b) HDPE.

Table 1 :
Comparison of degradation rate between nonbiodegradable and biodegradable composites by soil burial method.
. e insertion of 0.5 wt.% GO into PVC/WCA film statistically enhanced the TS and modulus of nanocomposite blend with values of 259.97% and 185.48% in contrast to PVC film (6.22 MPa TS; 255.94 MPa modulus), as well as about 26.14% and 141.07%relative to PVC/WCA film (17.75 MPa TS; 303.09MPa modulus), respectively.
MPa TS; 406.45 MPa modulus; 442.49%EB). e fabrication of antimicrobial packaging from PBS and thymol was investigated by Petchwattana and Naknaen