Chitosan’s ability to form complex compounds with transition metals is an important discovery. Research has shown that it can ionically bind with Cu²⁺, Hg²⁺, Zn²⁺, Cd²⁺, Ni²⁺, and other metal ions [30]. This unique property is of utmost importance for active food packaging, as it can bind metal nanoparticles and regulate antimicrobial activity for extended periods, underlining the broad potential for its application in food safety. The ionic strength of the solvent, ion interactions in the solvent, and solution pH are important parameters that determine the solubility properties of chitosan in water [4]. Chitosan has a unique property of being soluble in acidic conditions but insoluble in basic conditions. However, chitosan with a medium molecular weight and a degree of acetylation (DA) of around 0.5 can be soluble at a pH of around 7. Differences in solubility values will significantly affect the biological properties of chitosan due to changes in enzyme interactions [31].

Chitosan is a natural polysaccharide with antimicrobial properties against bacteria, fungi, and yeast. This antimicrobial activity depends on its cationic nature, degree of acetylation, concentration, and the test organism [4]. The mechanism of chitosan’s antimicrobial activities is still being discussed. Chitosan can form a protective layer like cellophane on the food surface, which keeps microbes from physically attacking it [32]. The chitosan layer can limit gas exchange from food to the external environment, thus inhibiting oxygen transport for microbes to grow and develop [33]. According to its structure, the cationic groups of chitosan can easily interact with the anionic peptidoglycan in bacterial cell walls, causing the cell wall to disintegrate and damage to the cell wall results in the leakage of intracellular parts, leading to bacterial death [34]. Chitosan also forms a watertight layer around bacterial cells, preventing the exchange of solutes and thus disrupting bacterial metabolism [35]. Meanwhile, low molecular weight chitosan can go through the cell nucleus directly and inhibit the translation of DNA into RNA by binding to DNA molecules [36]. By incorporating various additives, including metal and metal oxide nanoparticles, essential oils, and plant extracts, the antibacterial properties of chitosan films can be significantly improved [37].

Besides that, one of the most essential properties that need more concern is antioxidant activity. Antioxidants are substances that prevent damage to biological processes caused by free radicals. They work by giving electrons to free radicals, rendering them harmless [38]. Free radicals are often associated with oxidative stress, which occurs when oxygen combines with certain chemicals. These harmful radicals can damage essential cell components like DNA, proteins, and membranes. Antioxidants neutralize free radicals before they can cause harm. Plants produce a variety of antioxidants as secondary metabolites. Chitosan has been shown to exhibit antioxidant activity [39], but further improvements are needed.

Several studies have tested the performance of chitosan as food packaging combined with other biopolymers, showing an improvement in the properties and characteristics of chitosan-based composites [6]. Some biopolymers previously studied are starch, cellulose, alginate, gelatin, and pectin. Various types of biopolymers that can be combined with the chitosan matrix are shown in Table 1.

Starch-based biodegradable films share similar physical properties with synthetic polymers, such as being tasteless, transparent, odorless, and resistant to gases like oxygen and carbon dioxide [49]. However, starch’s strong intermolecular bonds make it difficult to melt, limiting its direct use in film production. Additionally, the high water content and low melting temperature of starch make film processing complex. Incorporating active agents into starch films can also be challenging, as these agents may degrade or lose efficacy during processing or storage [50]. Blending chitosan with starch produces food packaging films with enhanced antimicrobial and antioxidant properties due to improved water barrier properties. When added with thyme leaf extract, the chitosan-starch matrix also demonstrates improved mechanical properties [41].

Cellulose, another abundant natural biopolymer, is commonly derived from plant stems. Films formed from the chitosan-cellulose combination exhibit excellent mechanical properties due to electrostatic interactions between the two polymers [42]. The cationic nature of chitosan and the anionic nature of cellulose facilitate strong interactions, resulting in food packaging that has been shown to extend the shelf life of products like cheese [42]. Other forms of cellulose, including methylcellulose, hydroxypropyl methylcellulose, quaternized hemicellulose, carboxymethyl cellulose, and microfibrillated cellulose, can also be combined with chitosan to create biocomposite-based films. Research on cellulose derivatives, such as carboxymethyl cellulose, has demonstrated their potential as additives for chitosan to improve mechanical properties and enhance antibacterial activity. The chitosan-carboxymethyl cellulose matrix effectively inhibits the growth of Staphylococcus pneumonia, Bacillus subtilis, and Escherichia coli [43]. A study also revealed that avocados coated with moringa, chitosan, and carboxymethyl cellulose experienced slower respiration rates and maintained higher firmness than uncoated avocados throughout the storage period. These factors reduced moisture loss and improved overall fruit quality and shelf life [44]. Another form of cellulose, hydroxypropyl methylcellulose, exhibited excellent UV barrier properties when combined with chitosan [45].

Alginate, a biopolymer sourced from seaweed, is gaining significant attention as a sustainable alternative to traditional petroleum-based polymers. Seaweed, a plentiful marine resource, doesn’t require land for cultivation, making it an environmentally friendly choice [51]. Alginate can also interact electrostatically with cationic chitosan. This interaction significantly influences contact angle, microstructure, and thermal performance. Adding alginate to the chitosan matrix enhances water and gas barrier properties [46].

Pectin, another plant-based biopolymer, is rich in structural polysaccharides. Pectin is a complex carbohydrate extracted from plants, primarily composed of galacturonic acid units. These units can be chemically modified, with some carboxyl groups esterified with methyl groups or neutralized with bases [52]. Pectin possesses an anionic layer, facilitating stable intermolecular interactions with chitosan [53]. Chitosan-pectin composites exhibit improved properties and characteristics while preserving fruits’ physicochemical and sensory properties [47].

Carrageenan, a seaweed-based biopolymer, can work effectively with chitosan to improve food preservation. Carrageenan is a linear polysaccharide composed of galactose and ester sulfates, distinguished by the presence of sulfur groups. Lambda (λ), kappa (κ), and iota (ι) carrageenan are the three primary types, each characterized by a unique arrangement of sulfate groups in their repeating units [54]. According to Nguyen et al. (2021), with a specific combination of 1% chitosan and 0.2% κ-carrageenan could reduce weight loss in dragon fruit stored at 10°C and successfully delayed the yellowing of the fruit’s skin. A natural aging process like yellowing is a major visual sign that influences consumer choices [48].

Gelatin can also be added to chitosan matrices as a co-agent to enhance the quality of food packaging. Gelatin is a naturally occurring water-soluble protein obtained from the partial hydrolysis of collagen. A study applied a carboxymethyl chitosan matrix with added gelatin to cherries. The results indicated that this combination of biopolymers could improve food packaging quality. This study also demonstrated that the biopolymer blend supplemented with ascorbic acid could enhance the antioxidant properties of the packaging [55]. A specific study investigated food packaging from a chitosan matrix combined with gelatin from tuna fish skin as a preservative for papaya fruit. This matrix combination improved antioxidant properties and reduced mass loss, thereby successfully extending the shelf life of peeled papaya [19].

Despite having antimicrobial and antioxidant properties, chitosan’s potential can be further maximized through improvements in these areas. One method to enhance the antioxidant and antimicrobial properties of chitosan-based food packaging is by adding extracts from plant parts such as leaves, fruit peels, stems, and seeds [6]. In addition to being non-toxic, plant extracts are widely available in nature. Adding extracts rich in polyphenols, like banana peel and mango peel extracts, can improve the antioxidant properties of chitosan-based films and coatings. Various plant extracts that have been studied as antioxidant agents are shown in Table 2.

Antioxidant properties are often tested using the 2,2-diphenyl-1-picrylhydrazyl (DPPH) reagent. The DPPH method for testing antioxidants is one of the most widely used methods for testing plant extracts. This method is based on measuring electron paramagnetic resonance spectroscopy of DPPH depletion during its reaction with antioxidants. Antioxidant activity is usually expressed as a percentage of free radical inhibition. Although widely used, the DPPH method needs to be standardized [68]. The kinetic properties of each sample greatly influence antioxidant activity. Plant extracts can react rapidly with DPPH, while essential oils undergo a slower reaction [71]. In addition to antioxidant properties, plant extracts also potentially have antimicrobial properties.

Banana peels, often considered waste, have shown potential as an additive in chitosan-based packaging. Research has indicated that banana peels can alter chitosan films’ physical and mechanical properties. Banana peels contain phenolic compounds such as carotenoids, ascorbic acid, and biogenic amines that function as antioxidants [62]. The addition of banana peel extracts significantly enhanced the antioxidant capacity of the films compared to pure chitosan films. As the banana peel extract concentration increased, so did the antioxidant activity. It shows a similar trend observed in the total phenolic content [62]. Meanwhile, this research also demonstrated that increasing the concentration of banana peel extract led to a decrease in mechanical properties, specifically tensile strength [62].

Green tea leaves (Camellia sinensis) are a rich source of phenolic compounds like catechin, theaflavin, and thearubigin [63]. These three compounds have been shown to inhibit microbial growth and possess good antioxidant properties. Studies have shown that adding green tea extract to chitosan films can enhance their antioxidant properties. Results indicate that the higher the concentration of the extract, the better the antioxidant properties [63]. The study also indicated that adding green tea extract to chitosan films improved their mechanical and barrier properties. The interactions between chitosan and the polyphenolic compounds present in green tea extracts likely contributed to these modifications in film properties [63].

Research on developing chitosan-based food packaging has also been conducted using extracts from red grape seeds combined with Zataria multiflora Boiss essential oil. Grape seeds have a high content of flavonoids. Research has proven that chitosan films with these natural compounds can improve their antioxidant and antimicrobial properties [64]. A comparative analysis revealed that chitosan films fortified with grape seed extract possessed a greater capacity to scavenge DPPH radicals than those fortified with Zataria multiflora Boiss essential oil [64].

Jujube leaves, also known as ziziphus leaves, have been shown to improve the antioxidant properties of chitosan films [65]. Jujube leaves exhibited the highest DPPH scavenging activity compared to pine nutshell and peanut, similarly, demonstrating the total phenolic content. The variation in antioxidant activity among the composite films could be attributed to the intricate interplay of the three plant extracts. The incorporation of the three plant extracts into chitosan films led to a significant decrease in the water swelling capacity and mechanical strength of the films. Conversely, it increased the permeability of the films to water vapor, oxygen, and carbon dioxide. These modified properties hold potential for the development of active modified atmosphere packaging systems for fruits and vegetables [65].

Propolis, a substance bees produce, can also be used as an antioxidant and antimicrobial agent. Propolis contains many beneficial compounds, such as flavonoids, phenolic acids, phenyl aldehydes, and other amino acids. The addition of propolis extract to chitosan films led to an increase in total phenolic content and DPPH scavenging activity. Furthermore, as the concentration of propolis extract increased, so did the antioxidant activity and total phenolic content [66]. Another study explored the use of propolis extract from three types of Malaysian stingless bees: T. apicalis, H. fimbriata, and T. binghami. These propolis samples were found to contain flavonoids and phenolic compounds, known for their potential in creating biologically active substances and exhibiting strong antioxidant properties. The results indicated that all three types of propolis demonstrated significant antioxidant activity, with H. fimbriata propolis exhibiting the highest performance [67]. Propolis has been studied as a compound that can inhibit bacterial growth such as Bacillus cereus, Listeria monocytogenes, and Staphylococcus aureus [66].

Mango leaf extract has been investigated as an additive in producing chitosan-based films implemented on cashew nuts. Research has shown an increase in antioxidant activity after adding mango leaf extract at a concentration of 5%, resulting in a maximum inhibition percentage in the DPPH test of 87.16% [68]. The increase in inhibition is due to the thickening of the chitosan composite film with the extract. The increase in antioxidant activity also suggests the involvement of other phenolic compounds present in mango leaf extract. In addition, the parameter of oxidation resistance was also shown to increase significantly after the film was supplemented with mango leaf extract at concentrations of 3% and 5%. The morphological results showed an interaction between the phenolic polymer of mango leaf extract and chitosan, resulting in a smooth film structure [68].

Purple sweet potato is a source of anthocyanins. Anthocyanins are phenolic compounds that play a role in antioxidant activity. Plants rich in anthocyanins exhibit various colours such as orange, red, purple, and blue, depending on the type of plant [72]. Research has reported that the addition of purple sweet potato extract can improve the antioxidant properties of chitosan. This antioxidant mechanism is related to the chelating efficiency that can inhibit lipid peroxidation. Due to these advantages, chitosan films supplemented with purple sweet potato extract can protect food from oxidative damage [69].

Olive leaves (Olea europaea L.) are recognized as a valuable source of various bioactive compounds, particularly a diverse range of phenolic compounds. Olive leaf extract exhibits potent antioxidant and antimicrobial properties, making it effective in combating diseases such as coronary heart disease, diabetes, and certain bacterial infections [73]. It was confirmed by a study demonstrating that a chitosan-olive leaf extract blend exhibited approximately 75% DPPH radical scavenging activity [70].

The addition of turmeric extract to chitosan films significantly enhanced their antimicrobial properties. Compared to pure chitosan films, turmeric extract-incorporated films demonstrated a significant reduction in Staphylococcus aureus and Salmonella counts [74]. This improved antimicrobial activity can be attributed to the presence of curcuminoids and terpenoids within the turmeric extract. The addition of turmeric extract to chitosan-based food packaging also increases the value of the tensile strength parameter and significantly improves the barrier properties against visible ultraviolet light [74]. Another study shows that the turmeric extract could inhibit fungal growth, especially for Botrytis cinerea [75].

A study has demonstrated synergistic performance between chitosan films and apple peel polyphenols. The high polyphenol content of apple peel extract enables it to inhibit the activity of Staphylococcus aureus, Salmonella typhimurium, Escherichia coli, and Bacillus cereus [76]. This was evidenced by the formation of inhibition zones on the agar medium. It was observed that as the concentration of apple extract increased, the size of the inhibition zone also increased. The addition of polyphenols led to a decrease in the mechanical properties of the chitosan film. This reduction in mechanical strength may be attributed to a disruption in the crystalline structure of the chitosan matrix. The incorporation of polyphenols could interfere with the formation of ordered crystalline structures, weakening the intermolecular hydrogen bonding within the matrix [76].

In a study, pork coated with a tomato extract and chitosan-based edible coating was able to reduce the population of aerobic mesophilic bacteria for up to 21 days [77]. In this study, bacterial analysis was calculated based on the growth of bacterial colonies, represented by log/CFU. The number of mesophilic and coliform bacteria analyzed over several days indicated that the combination of chitosan and tomato extract was able to inhibit bacterial growth [77].

Pomegranate peel can scavenge free radicals and has antimicrobial properties. Pomegranate peel extract has been tested to inhibit the exchange of oxygen and carbon dioxide and increase the antioxidant activity of chitosan-based food packaging. This extract can inhibit the growth of Staphylococcus aureus [78]. The addition of 10 g/L of pomegranate peel extract of film material resulted in a notable ability to kill Staphylococcus aureus bacteria. However, the same treatment did not affect Escherichia coli. This aligns with the general understanding that Gram-positive bacteria, are more susceptible to antimicrobial agents compared to Gram-negative bacteria [78].

Clove extract can also be used as an antibacterial agent, especially against Salmonella typhimurium, Staphylococcus aureus, and Escherichia coli. This study showed that the addition of clove extract to the chitosan matrix can inhibit bacterial activity. This is indicated by the bacterial test results observed from the zone of inhibition formed. The largest zone of inhibition against bacteria was observed from the test using a chitosan matrix supplemented with clove extract [7].

Similar to clove extract, the combination between chitosan and peppermint (Mentha piperita L.) extract could be effective against bacteria (79). The chitosan demonstrated effectiveness against both gram-positive and gram-negative bacteria. It was particularly strong against Salmonella typhimurium, Staphylococcus aureus, and Escherichia coli. When combined with peppermint extract, the mixture exhibited a synergistic effect, especially against Staphylococcus aureus, with a larger zone of bacterial growth inhibition compared to the other bacteria [79].

In addition to plant extracts, the properties of chitosan-based food packaging can be enhanced using essential oils. Numerous studies have investigated using essential oils as additives in chitosan, which can also influence its mechanical properties. The effect of essential oils depends on their composition. Generally, some research has shown an incompatibility between hydrophobic essential oils and chitosan, affecting the polymer’s microstructure. The interaction between essential oils and chitosan can lead to a more porous structure, reducing the tensile strength of the resulting film [6]. It could also happen due to the volatility of the essential oil [84]. Despite the limitations, chitosan and essential oil have a synergistic relationship. Chitosan can effectively slow down the evaporation rate of essential oils. Polymeric-based materials are effective in encapsulating and preserving essential oils. Various types of polymeric platforms, including hydrogels [85], nanoparticles, and nanoemulsions [86,87], have been studied to analyze the performance of essential oils.

Besides affecting the mechanical properties of chitosan, essential oils can improve their antimicrobial and antioxidant properties. Similar to plant extracts, the antioxidant properties of essential oils are often evaluated using the DPPH method. Compared to plant extracts, essential oils react more slowly with DPPH. The differences in reaction kinetics have been classified into three categories: rapid, intermediate, and slow [71]. Various types of essential oils that have been studied as antioxidants and antimicrobial agents are shown in Table 3, respectively.

Zataria multiflora Boiss, a fragrant medicinal plant, is part of the Lamiaceae. It grows in warm, mountainous regions of Iran, Pakistan, and Afghanistan [93]. The essential oil from this plant contains many oxygenated monoterpene phenols, enabling it to inhibit the activity of bacteria, fungi, and radicals [64]. Zataria multiflora Boiss essential oil-fortified chitosan exhibited improved antioxidant activity. The study revealed a synergistic effect when grape seed extract was combined with this formulation, leading to a higher overall antioxidant capacity [64]. Meanwhile, another study reveals that Zataria multiflora Boiss essential oil could more effectively inhibit Listeria monocytogenes growth than grape seed extracts [94].

Eucalyptus globulus essential oil has been shown to enhance the antioxidant properties of chitosan-based food packaging by 43% [88]. This study also demonstrated an increased inhibition rate against Escherichia coli, Staphylococcus aureus, Pseudomonas aeruginosa, Candida parapsilosis, and Candida albicans. As the concentration of Eucalyptus globulus essential oil increases, the zone of inhibition on the agar plate becomes larger. These findings demonstrate that Eucalyptus globulus essential oil can be effective against a broad range of microorganisms [88].

Chitosan-based food packaging has also been tested with apricot kernel essential oil as an additive. The results showed that this combination resulted in good antioxidant, antimicrobial, and water barrier properties [89]. The primary components of apricot kernel oil were oleic acid and linoleic acid. The antioxidant properties of chitosan films fortified with apricot kernel oil are likely attributed to the presence of N-methyl-2-pyrrolidone within the apricot kernel oil. Moreover, the incorporation of apricot kernel oil into chitosan films demonstrated inhibitory effects on bacterial growth, particularly against Bacillus subtilis and Escherichia coli [89].

Caraway can also be used as an antioxidant agent. A study showed that adding caraway to chitosan films increased the antioxidant properties of chitosan as measured by the DPPH method [90]. The addition of caraway essential oil to chitosan films significantly enhanced their antioxidant activity. The primary constituents of caraway essential oil, carvone and limonene, exhibit strong antioxidant properties [90].

Carum copticum essential oil has also been tested in combination with chitosan to assess its potential as a food packaging material. Carum copticum essential oil exhibits stronger antioxidant properties in its pure form compared to its encapsulated form within chitosan nanoparticles. This difference may be attributed to the limited release of Carum copticum essential oil of the nanoparticles in ethanol. The nanoparticles remain intact, preventing the full release of the encapsulated Carum copticum essential oil [91]. This essential oil encapsulated in chitosan nanoparticles demonstrated the strongest antibacterial activity against a range of bacteria, including Staphylococcus aureus, Staphylococcus epidermidis, Bacillus cereus, Escherichia coli, Salmonella typhimurium, and Proteus vulgaris [91].

Another essential oil that can be used as an additive is Eryngium campestre. Eryngium campestre L., a perennial plant from the Umbrella family, is known for its medicinal properties. Its essential oil is valued for its potential to cure nerve pain, rheumatic conditions, inflammation, and heartburn [95]. Chitosan combined with Eryngium campestre essential oil can enhance antioxidant activity, particularly in neutralizing DPPH radicals. The antioxidant effect can be primarily attributed to the presence of phenolic compounds [92]. This study prepared chitosan as nano-chitosan and combined it with essential oil through encapsulation. Subsequently, this matrix was applied to cherries for 21 days of storage. The study demonstrated that Eryngium campestre essential oil could reduce aerobic bacterial counts, mass loss percentage, and titratable acidity [92].

Basil essential oil has also been investigated as an antimicrobial agent in chitosan films. Basil essential oil is often used as a food additive to prevent oxidation, as an antimicrobial agent, or as a flavoring agent in various products [96]. Testing chitosan films with basil oil has shown a good inhibitory effect on Staphylococcus saprophyticus and Escherichia coli [97]. Consequently, basil essential oil demonstrated potent antimicrobial activity against tested microorganisms, encompassing both gram-positive and gram-negative bacteria [97].

Tea tree oil (Melaleuca alternifolia) is well-known for its various benefits. Notably, it offers a promising alternative to conventional antifungal drugs [98]. Tea tree oil can also be used as an antimicrobial agent and is effective against Penicillium italicum. Tea tree oil composite films inhibited the growth of Penicillium italicum, with the rate of inhibition depending on the oil concentration. Lower tea tree oil concentrations had no observable antimicrobial effect. Research has shown that the addition of tea tree oil can also reduce the activity of Listeria monocytogenes even at a storage temperature of 10°C for 12 days [99].

Cinnamon is a natural material with excellent antioxidant properties. The primary active compound is cinnamaldehyde [100]. Incorporating cinnamon essential oil into chitosan films can enhance radical scavenging activity. Cinnamon essential oil combined with ginger essential oil is particularly suitable for chitosan films used to preserve meat. A common method for evaluating the antimicrobial efficacy of agents is to measure the total viable count of microorganisms on a sample, such as meat. In this case, a higher concentration of essential oils in chitosan-based films led to stronger antimicrobial activity against pork slices. This suggests that specific antimicrobial compounds present in ginger and cinnamon essential oil, including cinnamaldehyde, eugenol, limonene, and zingiberene, are responsible for this enhanced activity [100].

Extracted essential oil from lemongrass could also improve the antimicrobial activity of chitosan-based composite films and coatings. The essential oil contains various monoterpenoid groups of secondary metabolites such as geranial, neral, and citral, which essentially promote a good effect on bacteria growth inhibition [101,102]. Furthermore, a combination of chitosan and lemongrass essential oil can also improve the anticancer properties [103], antioxidant activity [104], antifungal properties [105], and mechanical properties [106]. Lemongrass essential oil combined with chitosan was reported to effectively inhibit the growth of Staphylococcus aureus, Staphylococcus epidermidis [107], Rhizopus stolonifera [105], Bacillus cereus, Escherichia coli, Listeria monocytogenes, and Salmonella typhi [101].

Metal nanoparticles such as silver and copper are effective antimicrobial nanomaterials against gram-positive and gram-negative bacteria, fungi, protozoa, and viruses. Antimicrobial agents in nanomaterials can electrostatically bind to the microbial cell wall, altering the membrane potential and leading to various metabolic disruptions, including impaired cellular respiration, cell membrane damage, and transport imbalances, ultimately causing cell death [6]. Another mechanism specific to metal nanoparticles involves the production of reactive oxygen species (ROS). Certain nanomaterials can stimulate inflammation, chemically converting toxic oxidants such as hydrogen peroxide into more reactive free radicals. Semiconductor nanomaterials can generate ROS through reactions between excited electrons and water molecules, producing substances toxic to microorganisms. ROS can cause damage to DNA and RNA, lipid peroxidation, and inhibit enzymes in microbes. The size and shape of nanoparticles can influence ROS production and antimicrobial activity. Small nanoparticles can penetrate cell membranes and other biological layers [6].

The green synthesis of metal nanoparticles has found widespread application in the food industry. Silver nanoparticles (AgNPs) are one example of metal nanoparticles used in chitosan-based food packaging. A study investigated the synthesis of chitosan-based films incorporated with AgNPs. The results indicated that adding AgNPs enhanced antimicrobial activity, particularly against Staphylococcus aureus, Escherichia coli, Salmonella, and Listeria monocytogenes [117]. Antimicrobial activity enhancement was demonstrated by the increased size of the inhibition zone observed during testing. The addition of AgNPs to the chitosan/polyvinyl alcohol film significantly improved its antioxidant properties, and this effect became more pronounced as the C-Ag concentration increased. The antioxidant mechanism of chitosan/polyvinyl alcohol films involves the pairing of oxygen atoms from C-Ag with nitrogen atoms in DPPH. This pairing leads to a decrease in absorbance at 517 nm and the disappearance of DPPH’s purple color [118].

Copper nanoparticles (CuNPs) combined with chitosan have also been studied and shown to exhibit excellent antifungal activity against tomato fruit [119]. CuNPs were effective in inhibiting the growth of Alternaria solani and Fusarium oxysporum. Cu ions are known to exhibit antifungal properties by generating highly reactive hydroxyl radicals that can damage biological molecules. In this study, the enhanced antifungal activity of Cu-chitosan nanoparticles arises from a synergistic effect between chitosan, which induces defense enzymes, and the toxic effects of released Cu ions [119].

Metal oxide nanoparticles, such as zinc oxide (ZnO), titanium dioxide (TiO₂), and copper oxide (CuO), have also been investigated as additive materials. These metal oxide nanoparticles are commonly used as additives in biopolymer matrices to improve the quality of food packaging. The ZnO nanoparticles have been found to extend the shelf life of meat by up to 14 days [120]. This study tested ZnO nanoparticles as an inhibitor of bacterial activity, specifically Staphylococcus aureus and Escherichia coli. Additionally, ZnO has been tested in chitosan matrices for banana application. In this study, ZnO nanoparticles were proven to inhibit the activity of Bacillus subtilis also. The best results were shown in the inhibition rate of Staphylococcus aureus [121]. In a study reveals that adding ZnO nanoparticles to chitosan films did not significantly improve their antioxidant properties [122].

Other research has shown that using titanium dioxide nanoparticles can help chitosan inhibit microbes in food packaging. Antimicrobial testing was conducted on Staphylococcus aureus, Escherichia coli, Candida albicans, and Aspergillus niger [123]. The study proved that titanium dioxide nanoparticles could inhibit the activity of all these types of microbes. A study reveals that the antioxidant activity of the samples with added TiO₂ NPs show a decrease with increasing TiO₂ NPs concentration. Meanwhile, at certain concentrations, shows increased antioxidant activity. This is likely because the antioxidants were bound to the surface of TiO₂, limiting their ability to interact with and neutralize free radicals [124].

Copper oxide nanoparticles could inhibit the microbes Escherichia coli, Pseudomonas aeruginosa, and Listeria monocytogenes [125]. A research study has demonstrated that copper oxide nanoparticles (CuONPs) exhibit enhanced antimicrobial activity against gram-positive bacteria compared to gram-negative bacteria. This increased susceptibility of gram-positive bacteria, particularly Staphylococcus aureus, to CuONPs is linked to the higher concentration of amine and carboxyl groups on their cell surfaces. These functional groups have a stronger affinity for copper ions, leading to increased toxicity and disruption of cellular processes in gram-positive bacteria [126]. The incorporation of CuO NPs into the chitosan/hydroxypropyl cellulose matrix resulted in a substantial increase in antioxidant activity as the nanoparticle concentration was raised. This improved antioxidant performance of the nanocomposite films is likely attributed to the increased electron density of the CuO NPs, which enhances their ability to scavenge free radicals [127].

In addition to the various metal and metal oxide nanoparticles mentioned previously, there is another type with high potential for improving the antimicrobial properties of chitosan. This type of nanoparticle is cerium oxide (CeO₂) nanoparticles. Cerium oxide has a unique property derived from the cerium element, which can be reversibly converted from the Ce(III) to Ce(IV) form [128]. This property is particularly attractive because it plays an important role in inhibiting the activity of microorganisms. Meanwhile, cerium oxide nanoparticles could also inhibit ROS activity, which is good for improving the antioxidant activity of chitosan [129]. A study shown that the nanocomposite chitosan films containing 2% nanoceria effectively scavenged approximately 75% of ABTS and 50% of DPPH free radicals. This antioxidant activity is attributed to nanoceria’s unique ability to transition between different oxidation states (Ce³⁺ and Ce⁴⁺) due to oxygen vacancies within its crystal structure [130].

Mechanical properties are one of the criteria that need to be achieved for food packaging applications. The strength of the packaging can affect the durability and shelf life of food. Chitosan films offer a high degree of customization, allowing them to be tailored for specific applications, such as enhancing barrier properties or mechanical strength. A major focus of current research is developing chitosan-based edible films that can serve as primary food packaging, preventing moisture loss and oxygen access [131]. However, to increase its resistance to external disturbances, the mechanical properties of chitosan still need to be improved.

A study was shown that the addition of AgNPs enhances the hydrophobicity of the material, resulting in contact angle measurements for the chitosan/PVA layer that exceed 90 degrees [118]. Other studies have shown that the presence of AgNPs also enhances the mechanical properties of chitosan-PVA composites. For chitosan/PVA-Ag nanocomposite films, a significant increase in tensile strength, stress at break, and elongation at break was observed. This improvement can be attributed to the formation of an additional bonded network created by the incorporation of AgNPs within the polymer blend. This network is formed through hydrogen bonding and strong electrostatic interactions between the polymer blend and AgNPs [132].

The other study reveals that the tensile strength of chitosan and CuNPs films was higher than pure chitosan films. Both tensile strength and elongation at break showed an increasing trend with increasing CuNPs concentration up to a certain value. However, as the concentration of CuNPs increased, the tensile strength gradually decreased. The reduction in strength is likely caused by a weakening of the interaction between the nanoparticles and the chitosan matrix at higher concentration [133].

Typically, a higher elongation at break, coupled with a good tensile strength, indicates superior material quality. By incorporating ZnO nanoparticles into a blend of chitosan and xanthan gum, the mechanical properties of the resulting films were significantly enhanced. This improvement is attributed to the enhanced interaction between the biopolymers and the nanoparticles [134]. The ZnO nanoparticles could also significantly weaken the films’ mechanical properties. The nanoparticles interfere with the crystalline order of the chitosan, reducing the strength of the intermolecular bonds between the polymer chains [122].

The addition of TiO₂ nanoparticles to chitosan significantly improved the tensile strength and elongation at break of the resulting nanocomposites. The tensile strength and deformation at break were both higher in samples containing TiO₂ compared to those without [135]. As the concentration of TiO₂ nanoparticles increased, so did the mechanical properties [136]. This enhancement is likely due to the electrostatic interaction between the positively charged TiO₂ nanoparticles and the negatively charged carboxyl groups in the chitosan matrix. Additionally, the incorporation of nanoparticles into the chitosan chains may increase chain mobility, further contributing to the improved tensile strength and elongation. However, these molecular interactions can also strengthen the polymer network, potentially reducing its flexibility [136].

In the other study, the chitosan/hydroxypropyl cellulose film with CuO nanoparticles showed a significant increase in tensile strength and Young’s modulus compared to the control film without nanoparticles. This improvement is attributed to the nanoparticles reinforcing the polymer matrix, creating a denser network that restricts molecular movement [127]. Meanwhile, another study demonstrated that a combination of 1% CuO/NiO nanoparticles could enhance the tensile strength and elongation at break of polyvinyl alcohol/starch/chitosan films. However, further increasing the nanoparticles concentration to 2% led to a significant decrease in tensile strength and elongation at break. This decline suggests that the nanoparticles may have agglomerated, reducing the number of effective interactions with the polymer and potentially disrupting the hydrogen bonding network within the polymer matrix [137]. The optimal concentration of both nanoparticles and polymers must be carefully considered to ensure the quality of food packaging.

Chitosan-based nanocomposite with the gelatin and CeO₄Zr nanoparticles showed the improvement of structural, morphological, mechanical, and thermal properties [138]. Although there is not much research on cerium oxide nanoparticles, the development of this metal oxide has a high potential for improving the properties and characteristics of chitosan as food packaging.

The addition of metal or metal oxide nanoparticles improves the thermal stability of chitosan. For example, adding silver nanoparticles to chitosan films enhanced their thermal resistance, especially at higher temperatures. This improvement is attributed to the interaction between the metal nanoparticles and the polymer chains. The specific interactions, such as van der Waals forces, hydrogen bonding, and other chemical bonds, influenced the thermal properties of the composite films. While the thermal profiles of the composite films were similar to pure chitosan at lower temperatures, a significant increase in thermal stability was observed at higher temperatures [139].

The thermal stability of the chitosan/polyvynil alcohol films was enhanced by increasing the AgNPs content. This improvement was due to the stable nature of the AgNPs. Polyvynil alcohol-Ag and chitosan-Ag nanocomposites exhibited higher thermal stability compared to pure polymers. This suggests that the incorporation of AgNPs into the chitosan/polyvynil alcohol mixture improved heat resistance and delayed thermal degradation [118].

On other hand, the thermal stability of chitosan, ZnO nanoparticles, and their composite was investigated under high temperatures by Aouadi et al. (2024). Chitosan was less thermally stable than both ZnO nanoparticles and the chitosan-ZnO nanoparticle composite. This is due to the heat sensitivity of chitosan’s polysaccharide structure, which is prone to degradation at elevated temperatures. In contrast, ZnO nanoparticles and the composite exhibited higher thermal stability, suggesting that the addition of chitosan did not significantly compromise their thermal properties. Interestingly, coating ZnO nanoparticles with chitosan enhanced their thermal stability, indicating a synergistic effect between the two materials [140]. Meanwhile, adding a small amount of ZnO nanoparticles to the chitosan films did not significantly affect their thermal stability. This may be because the limited number of nanoparticles hindered the interaction between the chitosan chains, leading to a slight decrease in thermal stability [141].

TiO₂ nanoparticles to chitosan enhanced the thermal stability of the resulting composites. The addition of TiO₂ nanoparticles to chitosan films led to the formation of TiO₂ bonds, which strengthened the interactions between chitosan molecules. This enhanced interaction resulted in improved thermal properties of the composite film [142]. This improvement is attributed to the formation of hydrogen bonds between the functional groups of chitosan and the TiO₂ crystallites. The presence of TiO₂ nanoparticles altered the decomposition mechanism of the chitosan matrix. Interestingly, increasing the concentration of nanoparticles led to a further increase in thermal stability [136].

Another study reveals that incorporating NiO/CuONPs into the polyvinyl alcohol/starch/chitosan blend slightly enhanced the thermal stability of the resulting bio-nanocomposites. This improvement is attributed to the formation of stronger chemical bonds between the polymer chains, which slows down the degradation process. Given their enhanced thermal stability, these bio-nanocomposite films show potential for use in food packaging applications [137].

On the other hand, the incorporation of 1% nanoceria did not significantly affect the thermal stability of the chitosan film matrix. However, increasing the nanoceria concentration to 2% led to a notable decrease in thermal stability. This reduction is likely due to the lower concentration of nanoceria at this level, which may result in a more uniform distribution throughout the polymer matrix [130].