Advancements in Gellan Gum-Based Films and Coatings for Active and Intelligent Packaging
"> Figure 1
<p>Structure of gellan gum [<a href="#B15-polymers-16-02402" class="html-bibr">15</a>]. (<b>a</b>) High- and low-acyl gellan gum. (<b>b</b>) Coil-to-helix and sol-gel transition of gellan gum. Reprinted with permission from Elsevier.</p> "> Figure 2
<p>Appearance of gellan gum-based films. (<b>a</b>) Gellan gum film containing titanium dioxide nanoparticles [<a href="#B35-polymers-16-02402" class="html-bibr">35</a>]. (<b>b</b>) Gellan gum/cellulose/chitosan composite film [<a href="#B32-polymers-16-02402" class="html-bibr">32</a>]. (<b>c</b>) Gellan/gelatin film containing red radish anthocyanins [<a href="#B44-polymers-16-02402" class="html-bibr">44</a>]. (<b>d</b>) Gellan gum film incorporating red cabbage anthocyanins [<a href="#B43-polymers-16-02402" class="html-bibr">43</a>]. (<b>a</b>) was used under a CC-BY 4.0 license. (<b>b</b>,<b>c</b>) were reprinted with permission from the American Chemical Society. (<b>d</b>) was reprinted with permission from Elsevier.</p> "> Figure 3
<p>Bibliometric network map based on the co-occurrence of terms in recent studies (2015–2024) on gellan gum-based packaging materials.</p> "> Figure 4
<p>Methods to prepare gellan gum-based films and coatings. (<b>a</b>) Preparation of film-forming solution. (<b>b</b>) Casting method to prepare film. (<b>c</b>) Methods to deposit coating onto the food surface.</p> "> Figure 5
<p>Contact angle of gellan gum-based composites. (<b>a</b>) Gellan gum/soy protein composites with <span class="html-italic">Clitoria ternatea</span> flower extracts [<a href="#B73-polymers-16-02402" class="html-bibr">73</a>]. (<b>b</b>) Gellan gum/konjac glucomannan composites with gallic acids [<a href="#B37-polymers-16-02402" class="html-bibr">37</a>]. Both figures were reprinted with permission from Elsevier.</p> "> Figure 6
<p>Optical properties of gellan gum-based composites. (<b>a</b>) Opacity of gellan gum composites with roselle anthocyanin and nisin [<a href="#B67-polymers-16-02402" class="html-bibr">67</a>]. (<b>b</b>) Gellan gum/chitosan composites containing thyme essential oils [<a href="#B58-polymers-16-02402" class="html-bibr">58</a>]. (<b>c</b>) Gellan gum/cellulose composites containing titanium oxide and copper oxide nanoparticles [<a href="#B31-polymers-16-02402" class="html-bibr">31</a>]. (<b>d</b>) Gellan gum/polyvinyl alcohol single-layer and triple-layer composites containing <span class="html-italic">Alhagi sparsifolia</span> flower extract [<a href="#B74-polymers-16-02402" class="html-bibr">74</a>]. (<b>a</b>–<b>c</b>) were reprinted with permission from Elsevier. (<b>d</b>) was reprinted under a CC-BY 4.0 license.</p> "> Figure 7
<p>Degradability of gellan-based composites. (<b>a</b>) Degradation of gellan gum/cellulose/chitosan composites [<a href="#B32-polymers-16-02402" class="html-bibr">32</a>]. Reprinted with permission from American Chemical Society. (<b>b</b>) Degradation of gellan gum films containing cranberry extract and <span class="html-italic">Lactococcus lactis</span> [<a href="#B30-polymers-16-02402" class="html-bibr">30</a>]. Reprinted with permission from Elsevier.</p> "> Figure 8
<p>Preservation of fruits and vegetables by gellan gum-based packaging materials. (<b>a</b>) Mangos coated with gellan gum/chitosan composites enriched with mustard essential oil [<a href="#B38-polymers-16-02402" class="html-bibr">38</a>]. (<b>b</b>) Fresh-cut peppers wrapped in gellan gum/cellulose films containing titanium oxide and copper oxide nanoparticles [<a href="#B31-polymers-16-02402" class="html-bibr">31</a>]. Both figures were reprinted with permission from Elsevier.</p> "> Figure 9
<p>Preservation of starch-based food products using gellan gum-based packaging materials. (<b>a</b>) Bread, protected with gellan/cellulose, that contains <span class="html-italic">Anethum graveolens</span> essential oil stored at room temperature. A, polypropylene bags; B, polypropylene wraps; C, D, E, gellan/cellulose films incorporating 0%, 2%, and 4% of essential oil, respectively [<a href="#B13-polymers-16-02402" class="html-bibr">13</a>]. (<b>b</b>) Chinese steamed bread coated with different gellan gum-based composites. BE, blackberry extract; BM, <span class="html-italic">Bifidobacterium longum</span>; BO, baobab seed oil; GE, gelatin; GG, gellan gum [<a href="#B40-polymers-16-02402" class="html-bibr">40</a>]. Both figures were reprinted with permission from Elsevier.</p> "> Figure 10
<p>Minced pork protected with <span class="html-italic">Aronia melanocarpa</span> extract-incorporated gellan gum/pea protein/chitosan bilayer films [<a href="#B72-polymers-16-02402" class="html-bibr">72</a>]. This was reprinted under a CC-BY 4.0 license.</p> "> Figure 11
<p>Colorimetric changes of different gellan gum-based indicators. (<b>a</b>) Rose anthocyanin-containing films responding to trimethylamine. AG, alginate; AN, anthocyanin; GG, gellan gum; TMA, trimethylamine [<a href="#B51-polymers-16-02402" class="html-bibr">51</a>]. (<b>b</b>) <span class="html-italic">Clitoria ternatea</span> anthocyanin-containing films responding to pH change [<a href="#B73-polymers-16-02402" class="html-bibr">73</a>]. (<b>c</b>) Methyl red/bromothymol blue-containing films responding to CO<sub>2</sub> change. GG, gellan gum; MB, methyl red/bromothymol blue; SC, sodium carboxymethyl cellulose; TA, tannic acid [<a href="#B53-polymers-16-02402" class="html-bibr">53</a>]. All figures were reprinted with permission from Elsevier.</p> "> Figure 12
<p>Freshness monitoring for aquatic food products. (<b>a</b>) Mulberry anthocyanin-containing film responding to spoilage of Chinese mitten crab [<a href="#B96-polymers-16-02402" class="html-bibr">96</a>]. (<b>b</b>) <span class="html-italic">Clitoria ternatea</span> anthocyanin-containing films responding to spoilage of shrimp. CT, <span class="html-italic">Clitoria ternatea</span> anthocyanin; G, gellan gum; HSPI, heat-treated soy protein isolate [<a href="#B73-polymers-16-02402" class="html-bibr">73</a>]. (<b>c</b>) RGB (red, green, blue) hue value changes of rose anthocyanin-containing films responding to increase in total volatile basic nitrogen (TVB-N) content during carp storage [<a href="#B51-polymers-16-02402" class="html-bibr">51</a>]. All figures were reprinted with permission from Elsevier.</p> "> Figure 13
<p>Freshness monitoring for other animal-derived food products. (<b>a</b>) Purple kale anthocyanin-containing film responding to chilled beef spoilage [<a href="#B94-polymers-16-02402" class="html-bibr">94</a>]. (<b>b</b>) RGB (red, green, blue) hue value changes of rose anthocyanin-containing films responding to the increase in total volatile basic nitrogen (TVB-N) content during chicken storage [<a href="#B51-polymers-16-02402" class="html-bibr">51</a>]. (<b>c</b>) RGB hue value changes in red radish anthocyanin-containing films responding to the increase in acidity and TVB-N during milk storage [<a href="#B44-polymers-16-02402" class="html-bibr">44</a>]. (<b>a</b>,<b>b</b>) were reprinted with permission from Elsevier. (<b>c</b>) was reprinted with permission from the American Chemical Society.</p> "> Figure 14
<p>Freshness monitoring for fruits and vegetables. (<b>a</b>) Mushrooms protected with red cabbage extract-containing gellan gum film [<a href="#B43-polymers-16-02402" class="html-bibr">43</a>]. (<b>b</b>) Strawberries protected with methyl red/bromothymol blue-containing films. GG, gellan gum; MB, methyl red/bromothymol blue; SC, sodium carboxymethyl cellulose; TA, tannic acid [<a href="#B53-polymers-16-02402" class="html-bibr">53</a>]. Both figures were reprinted with permission from Elsevier.</p> ">
Abstract
:1. Introduction
2. Preparation of GG-Based Films and Coatings
2.1. Gel Matrix Materials
2.2. Functional Compounds
2.2.1. Functional Compounds for Active Packaging
2.2.2. Functional Compounds for Intelligent Packaging
2.3. General Steps to Prepare GG-Based Films and Coatings
2.3.1. Preparation of Film-Forming Solutions
2.3.2. Fabrication of GG-Based Films
2.3.3. Fabrication of GG-Based Coatings
2.3.4. Fabrication of Multi-Layered Films and Coatings
3. Physicochemical Properties of GG-Based Composites
3.1. Mechanical Properties
3.2. Water Barrier Properties
3.2.1. Water Vapor Permeability
3.2.2. Contact Angle
3.3. Oxygen Permeability
3.4. Optical Properties
3.5. Antioxidant and Antimicrobial Properties of GG-Based Composites
3.5.1. Antioxidant Properties
3.5.2. Antimicrobial Properties
3.6. Release Properties of GG-Based Composites
3.7. Degradability of GG-Based Composites
4. Active Packaging of GG-Based Packaging Materials
4.1. Active Packaging for Fruits and Vegetables
4.1.1. Firmness
4.1.2. Weight Loss
4.1.3. Respiration
4.1.4. Phenolic Compounds
4.1.5. Ascorbic Acid
4.1.6. Microbial Growth
4.1.7. Browning Progress
4.2. Active Packaging for Starch-Based Food Products
4.3. Active Packaging for Animal-Derived Food Products
4.3.1. Active Packaging for Pork
4.3.2. Active Packaging for Aquatic Foods
4.3.3. Active Packaging for Poultry
4.3.4. Active Packaging for Other Animal-Derived Food Products
5. Intelligent Packaging of GG-Based Colorimetric Indicators
5.1. Mechanism of Colorimetric Films
5.2. Colorimetric Properties of GG-Based Composites
5.3. Applications of GG-Based Colorimetric Indicators
5.3.1. Intelligent Packaging for Aquatic Food Products
5.3.2. Intelligent Packaging for Other Animal-Derived Food Products
5.3.3. Intelligent Packaging for Fruits and Vegetables
6. Conclusions
7. Research Outlooks
Author Contributions
Funding
Conflicts of Interest
References
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Gel Base | Additives | Conditions | Refs. |
---|---|---|---|
GG up to 0.8%, levan up to 0.8% | Glycerol 0.4%, citric acid 0.04% | Polymers dissolved at 50 °C, dried at 50 °C overnight. | [12] |
GG 2%, eggshell nanoparticles 1–3% | Glycerol 0.5% | Nanoparticles prepared by high-energy milling (2 h). Film solution cast and dried at 40 °C for 8 h. | [48] |
GG 2%, polyvinyl alcohol 1% | Glycerol 30%, Caucasian whortleberry extract 0–9 mg/mL, myrtle essential oil 0–9 mg/mL | Solvent casting: polymers dissolved at 75 °C, additives incorporated, solution cast and dried at 35 °C for 24 h. | [9] |
GG:κ-carrageenan:xanthan gum = 1:4:2 | Not applicable | Polymers dissolved at 60 °C, cooled to room temperature, and cast and dried at 25 °C for 48 h. | [57] |
GG:κ-carrageenan:xanthan gum = 2:6:1, | Glycerol 2.0 g, TiO2 1–7% | Polymers dissolved at 80 °C, TiO2 added, cooled to room temperature, cast and dried at 25 °C for 48 h. | [34] |
GG:Polyacrylamide:sodium citrate:sodium chloride:citric acid = 3:3:3:2:2, | Glycerol 2.0 g, ZnO 1–5% | Polymers dissolved at 80 °C, ZnO added, solution cast and dried at 25 °C for 72 h. | [11] |
GG 0.2%, citrus pectin 1% | Glycerol 0.5%, CaCl2 5 mM, EDTA 0.05 M, antimicrobial supernatant 50 AU/mL | Polymers dissolved at 75 °C, additives incorporated, solution cast and dried at 35 °C for 17 h, conditioned at 23 °C for 48 h. | [42] |
GG 1%, agar 1%, montmorillonite clay 0–10% | Glycerol 1%, CaCl2 | Polymers dissolved at 80 °C, clay added, solution cast and dried at 25 °C for 48 h. | [52] |
GG 1%, black rice extracts 0–12% | Glycerol 1% | GG dissolved at 50 °C, extracts added, solution cast and dried at 40 °C for 5 h. | [93] |
GG 1%, alginate 1%, ZnO 5%, | Glycerol 0.8%, black rice anthocyanin, and curcumin | GG layer cast first, GG dissolved at 60 °C, anthocyanin, and curcumin added, alginate-ZnO layer casted afterward and dried at 25 °C for 60 h. | [41] |
GG 1%, CMC, starch 2%, | Glycerol 0.8%, roselle anthocyanin, nisin | GG dissolved at 70 °C, cooled to 40 °C, roselle anthocyanin added, casting for outer layer with CMC, starch, and nisin | [67] |
GG 0.5%, apple pectin 2% | Glycerol 2.2%, nisaplin | Polymers dissolved at 70 °C, nisaplin added, solution cast and dried at 35 °C for 11 h. | [65] |
GG 1%, Chitosan 2% | Glycerol 0.25%, thyme essential oil emulsion 2–6% | GG layer cast first, polymers dissolved at 70 °C, dried at room temperature for 4 h, followed by chitosan–nanoemulsion layer containing essential oil emulsion, dried at room temperature for 12 h | [58] |
GG 0.7%, xanthan gum 0.3%, alginate 0.7%, hydroxypropyl methylcellulose 0.7% | Glycerol, beeswax, fructose, sorbitol, or polyethylene glycol, 1% | Polymers dissolved at 50 °C, cooled, cast and dried at 28 °C for 3 h | [98] |
Functional Compounds | Gel Base | Tensile Strength (MPa) | Elongation at Break (%) | Refs. |
---|---|---|---|---|
TiO2 nanoparticles | GG | ↑ from 48.2 to 56.1 | ↓ from 28.2 to 23.0 | [34] |
TiO2 nanoparticles | GG, carrageenan, xanthan gum | ↑ from 40.5 to 56.1 | ↓ from 30.6 to 23.0 | [34] |
ZnO nanoparticles | GG/xanthan gum | ↑ from 22.1 to 35.5 | ↓ from 30 to 25.1 | [77] |
ZnO nanoparticles | GG | ↑ from 33.5 to 43.8 | ↑ from 24.6 to 32.8 | [34] |
SiO2 nanoparticles | GG/cellulose | ↑ from 28.2 to 45.1 | ↓ from 23.1 to 34.2 | [89] |
Eggshell nanoparticles | GG | ↓ from 73.79 to 54.93 | ↓ from 36.7 to 25.4 | [48] |
Black rice anthocyanins | GG/zein | ↑ from 7.58 to 8.91 | ↓ from 7.68 to 5.37 | [93] |
Elderberry anthocyanins | GG/gelatin | ↑ from 5.46 to 14.57 | No influence (17.92–18.59) | [95] |
Clitoria ternatea anthocyanins | GG | No influence (~11) | No influence (~6) | [73] |
Rosemary essential oil | GG/cellulose | ↓ from 14.56 to 8.63 | ↓ from 12.13 to 7.78 | [78] |
Dill essential oil | GG/cellulose | ↑ from 5.82 to 10.39 | ↓ from 95.82 to 78.87 | [13] |
Cranberry extract, Lactococcus lactis | GG | ↑ from 17.92 to 32.52 | ↑ from 12.32 to 19.23 | [30] |
Anethum graveolens essential oil | GG/cellulose | ↑ from 5.82 to 10.36 | ↓ from 95.82 to 78.87 | [13] |
Functional Compounds | Gel Base | Methods | Major Results | Refs. |
---|---|---|---|---|
ZnO | GG | Antibacterial: Salmonella enterica, Bacillus cereus, Staphylococcus aureus, Cronobacter, sakazakii, Escherichia coli | 1% ZnO showed no antibacterial effect S. aureus was the most susceptible to the films B. cereus was most resistant to the films | [11] |
TiO2 nanoparticles | GG, carrageenan, xanthan gum | Antibacterial: Pseudomonas aeruginosa, S. aureus, Acinetobacter baumannii, E. coli | 3% TiO2 showed no antibacterial effect 5–7% TiO2 showed antibacterial effects | [34] |
TiO2 nanoparticles | GG | Antibacterial: S. aureus, Streptococcus, E. coli, and P. aeruginosa | The inhibition zone was comparable with the penicillin control sample. | [35] |
Silver nanoparticles | GG | Antifungal: Candida spp. (C. albicans, C. lusitaniae, C. haemulonii, C. krusei, C. glabrata) | All the fungal species were sensitive to Ag nanoparticles. The minimum required concentration of Ag for inhibiting the growth of all fungal species was 0.063 mg/mL. | [88] |
SiO2 nanoparticles | GG, cellulose | Antibacterial: B. cereus, E. coli, S. aureus, Cronobacter sakazakii, Salmonella enterica, Salmonella Typhimurium | ↑ Antimicrobial effects, with a dose-dependent manner. The film was more active against S. aureus and less active against B. cereus. | [89] |
Coffee parchment waste | GG | Antifungal: Fusarium verticillioides, Fusarium sp., Colletotrichum gloeosporioides | Blanks did not show growth inhibition. The presence of caffeine and phenolic compounds in the films was beneficial for acquiring natural antifungal properties. | [36] |
Mustard essential oil | GG, chitosan | Antibacterial: E. coli, S. aureus, B. anthracis | ↑ Antimicrobial effects with a dose-dependent manner. Sensibility: B. anthracis > S. aureus > E. coli | [38] |
Rosemary essential oil | GG, cellulose | Antibacterial: E. coli, S. aureus, Salmonella Typhimurium, P. fluorescence | Inhibitory effects increased with the increase in concentration. P. fluorescence showed the lowest sensitivity. | [78] |
Thyme essential oil | GG, starch | Antifungal: B. cinerea | No inhibitory effect was observed on an inoculated apple. | [104] |
Nisin | GG, guar gum | Antibacterial: B. subtilis, E. coli Antifungal: Saccharomyces cerevisiae | Films showed more effective antimicrobial activity against B. subtilis than E. coli The inhibitory effect against S. cerevisiae was not as apparent as that against the other bacteria. | [60] |
Nisin | GG, pectin | Antibacterial: L. monocytogenes | A neat film and a film containing (129.7 IU/mL) nisin did not prevent the growth. The minimum inhibitory concentration of nisin was 171.5 IU/mL. | [65] |
Three different natural polycationic polymers | GG, chitosan | Antibacterial: S. enteritidis, S. aureus | S. aureus cells attach more to the film surfaces than the S. enteritidis. ↑ Antimicrobial effects | [56] |
Not applicable | Oxidized GG | Antibacterial: E. coli, S. aureus Antifungal: Aspergillus niger | Antibacterial and antifungal activity was improved with an increasing oxidation level | [102] |
Functional Compounds | Gel Base | Food | Major Results | Refs. |
---|---|---|---|---|
Thyme essential oil | GG, starch | Apples and persimmons stored at 25 °C for 14 d | ↓ Weight loss, ↑ firmness maintenance, ↓ respiration rate, ↓ severity of gray mold | [104] |
Geraniol and pomegranate extract | GG | Fresh-cut strawberries stored at 5 °C for 7 d | ↓ Microbial growth, ↑ firmness maintenance, ↓ off-odor | [86] |
Thymol–β-cyclodextrin microcapsules | GG, konjac glucomannan | Blueberries stored at 2 °C for 56 d | ↓ Decay rate, ↓ weight loss, ↓ respiration rate, ↓ softening and senescence, ↑ cuticular waxes, ↓ lipid oxidation, ↓ terpenes, ↓ benzaldehyde, ↑ esters, ↑ aldehydes | [84] |
Lactococcus lactis and cranberry extract | GG | Fresh-cut apples and potatoes stored at 4 °C for 10 d | ↓ Browning, ↑ firmness maintenance, ↑ antioxidant activity | [30] |
Oregano essential oil | GG | Mandarin stored at 6 °C for 24 d and at 15 °C for 7 d | ↓ Weight loss, ↑ firmness maintenance, ↑ color preservation, ↑ total phenolic and content, ↑ antioxidant activity ↑ ascorbic acid maintenance, ↓ microbial growth | [39] |
Ascorbic acid | GG | Litchi stored at 5 °C for 7–14 d | ↓ Weight loss, ↑ color maintenance, ↑total soluble solids preservation | [109] |
Vanillin and geraniol | GG, apple fiber | Banana stored at 5 °C for 12 d | ↑ Firmness maintenance, ↑ color maintenance, ↑ antioxidant activity, ↓ yeasts/molds growth, ↑ sensory shelf-life by 4 d | [83] |
Not applicable | GG, chitosan, alginate | Apricot stored at 4 °C and 80% RH for 15 d | ↑ Ascorbic maintenance, ↑ external color maintenance, ↑ carotenoids maintenance, ↓ weight loss, ↑ firmness maintenance, ↑ firmness maintenance, ↓ peroxidase, ↓ polyphenol oxidase | [8] |
Mustard essential oil | GG, chitosan | Mango stored at 25 °C and 80% RH for 20 d | ↓ Total soluble solids increase, ↓ titratable acidity decrease, ↑ vitamin C maintenance, ↓ decay rate, ↑ firmness maintenance | [38] |
Not applicable | GG, chitosan, lactoferrin | Strawberry stored at 25 °C and 50% RH for 6 d | ↓ Weight loss, ↓ titratable acidity decrease, ↓ total soluble solids increase, ↓ microbial growth | [70] |
1-MCP | GG | Jackfruit bulbs stored at 5 °C for 14 d | ↓ Total soluble solids increase, ↓ titratable acidity decrease, ↓ respiration rate, ↑ firmness maintenance, ↓ microbial growth | [108] |
Anethum graveolens essential oil | GG, pineapple peel cellulose | Bread stored at room temperature for 3 weeks | ↓ Microbial growth | [13] |
Natamycin, essential clove oil | GG, citrus pectin | Tortilla stored at 22 °C and 50% RH for 30 d | Sample with a high density of polyethylene exhibited a sour odor. The active film did not negatively affect the sensory attributes of the food. | [64] |
Not applicable | GG, waxy corn starch | Rice cakes stored at 25 °C with 45% RH for 4 d | ↓ Retrogradation, ↑ moisture maintenance (3.36% for uncoated sample vs. 1.08% for coated sample), ↑ texture profile | [111] |
Functional Compounds | Gel Base | Food | Major Results | Refs. |
---|---|---|---|---|
Polyester, phenolic acids | GG, starch | Pork stored at 5 °C and 48% RH for15 d | ↓ pH decrease, ↓ TBARS, ↓ TVB-N, ↓ microbial growth, ↓ weight loss, ↓peroxide index, ↓ ΔE of meat | [26] |
Aronia melanocarpa extract | GG, pea protein, chitosan | Pork stored at 4 °C for 7 d | ↓ TVB-N, ↓ weight loss (20% for active film-protected sample vs. 37.72 for unwrapped sample), | [72] |
Alhagi sparsifolia flower extract | GG, PVA | Dried shrimp stored at 37 °C for 40 d | ↓ TBARS value by 47.5%, ↓ peroxide index, ↓ protein oxidation. Bilayer films were more effective than single-layer film. | [74] |
Not applicable | GG, konjac glucomannan | Snakehead fillets stored at −20 °C for 150 d | ↑ Hardness, ↑ springiness, ↑ chewiness, ↓ TVB-N, ↓ TBARS | [62] |
Anthocyanin, nisin | GG, cellulose, starch | Chicken breast stored at 4 °C for 10 d | ↓ TBARS, ↑shelf-life of by 1–2 d, ↓ pH increase | [67] |
Caucasian whortleberry extract, myrtle essential oil | GG, PVA | Turkey breast stored at 4 °C for 15 d | ↓ TVB-N, ↓ peroxide value, ↓ TBARS, ↓ pH decrease, ↑ sensory properties | [9] |
Basil essential oil | GG | Egg stored at 25 °C for 42 d | ↓ Weight loss, ↑ Haugh unit, ↑ yolk index, ↓ total aerobic plate count, ↑ pH maintenance | [80] |
Potassium sorbate | GG, aloe gel | Cheese stored at 25 °C for 12 d | ↓ Weight loss, ↓ growth of Penicillium roqueforti | [29] |
Dye and Gel Base | Gel base | Colorimetric Response | Application | Major Results | Refs. |
---|---|---|---|---|---|
Black rice extracts | GG and zein | Red (pH 2) to pale pink (pH 4–6), purple (pH 8–10) and finally taupe (pH 11–12) | Largemouth bass fillets stored at 4 °C for 10 d | The ΔE of film at 2–6 d ranged from 6.83 to 9.08. Pink to brown (8 d, ΔE = 13.14, spoilage point). Grayish-brown (10 d, rotten) | [93] |
Roselle anthocyanins | GG, carboxymethyl cellulose, starch | Red (pH 2–3), dark pink (pH 4), red (pH 5–6), light pink (pH 7), red (pH 8), dark green (pH 12), and yellow-green (pH 13) | Chicken stored at 4 °C for 10 d | The bilayer films were pink on days 0–6, reddish-brown on days 8 and yellowish-brown on day 10 Extended chicken shelf-life by 2 d | [67] |
Methyl red, bromothymol blue | GG, cellulose | Orange → pink → yellow → green → blue trend at different pH conditions | Lamb meat stored at 4 °C for 7 d | From orange-red on 0 d, orange-yellow on 1–4 d, yellow-green on 5–6 d, to green on 7 d The values of TVC, pH and TVB-N were positively correlated with each other | [114] |
Black rice anthocyanins and curcumin | GG | Orange-red → orange → yellow → gray-yellow → red-brown → black-red → bright red as the pH went from 2 to 12 | Not applicable | Not applicable | [49] |
Red radish anthocyanins | GG, gelatin | From deep orange red to light carmine (pH range of 2–7), purple (pH 8–9), yellow-green (pH 10), yellow (pH 11–12) | Milk placed in an incubator at 25 °C with 75% RH for 48 h. Black carp placed in an incubator at 4 °C with 75% RH for 10 d | Milk: The acidity of milk showed 18 °T at 25 h, R value of the film was ∼240 Carp: color of film changed color from orange-red to green (7 d), followed by yellow-green. TVB-N value showed 20 mg/100 g at 5.5 d, and B value of film showed ∼87. | [44] |
Mulberry anthocyanins | GG, gelatin | From light pink to colorless (pH 2–6), from light green to yellowgreen (pH 7–10), orange color (pH 11–12) | Crucian carp at 4 °C with 75% RH for 9 d | Color of film changed from pink to light green (6 d). TVB-N value increased from 4.7 to 20.7 mg/100 g (6 d) | [33] |
Clitoria ternatea extract | GG, heat-treated soy protein isolate | Red (pH < 3), violet (pH 3.0–5.0), blue (pH 5.0–6.0), blue-green (pH 7.0–9.0), green (pH 10.0–11.0) and brownish-yellow (pH > 11.0) | Shrimp at room temperature (25 °C) for 24 h | Colors of films changed from blue (initial) to bluish-green ΔE of films was correlated with the increase in TVB-N values | [73] |
Broussonetia papyrifera fruit anthocyanin | GG, mica nanosheets, konjac glucomannan, carrageenan | Crimson (pH 2–3), light red and almost colorless (pH 4–6), blue-grey (pH 7–11), yellow (pH 12) | Shrimp at 4 °C for 5 d and 25 °C for 15 h | 25 °C: color of films showed no changes in the first 6 h. Color of films changed from purple to yellow/blue at 9 h 4 °C: pH and TVB-N increased to 7.45 and 29.33 g/100 g after 3 d. ΔE of films responded well to shrimp spoilage | [55] |
Elderberry anthocyanins | GG, guar gum | Color shifted from red to pink, lavender to purple, and dark purple to yellow-brown as the pH went from 2 to 12 | Shrimp stored in a 4 °C for 4 d | The color of the film changed from mauve to lighter on 1 d, and eventually showed a yellowish-green. Color change responds well to variations in pH. Anthocyanin layer inhibited protein degradation | [95] |
Mulberry anthocyanin | GG, chitosan, polyvinyl alcohol, alginate | Not applicable | Chinese mitten crab stored at 4 °C for 10 d | The color of films showed a visible change from pink to dark green, correlated with the TVB-N level (increased to 31.23 mg/100 g on day 8). | [96] |
Methyl red, bromothymol blue | GG, alginate, cellulose, tannic acid | A consistent dark red tint, turning brown-red (pH 4–5), followed by gray-green (pH 6–8), and ultimately a deep green (pH 9–10). | Strawberry stored at 4 °C for 14 d | ΔE change in the composite film containing 6% tannic acid was the largest. Double-layer film delayed the rotting and deterioration of strawberry. | [53] |
Red cabbage anthocyanins | GG | Red (pH 2), pink (pH 3), purplish-red (pH 4–6), purple (pH 7), blue (pH 8–9), green (pH 10) | Mushroom stored at 4 °C for 15 d | The color of films was dark purplish-red before storage, and it changed to light red during storage. The surface of mushroom lost its luster and gradually turned yellow in color. | [43] |
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Li, H.; Gao, K.; Guo, H.; Li, R.; Li, G. Advancements in Gellan Gum-Based Films and Coatings for Active and Intelligent Packaging. Polymers 2024, 16, 2402. https://doi.org/10.3390/polym16172402
Li H, Gao K, Guo H, Li R, Li G. Advancements in Gellan Gum-Based Films and Coatings for Active and Intelligent Packaging. Polymers. 2024; 16(17):2402. https://doi.org/10.3390/polym16172402
Chicago/Turabian StyleLi, Hang, Kun Gao, Huan Guo, Rongfeng Li, and Guantian Li. 2024. "Advancements in Gellan Gum-Based Films and Coatings for Active and Intelligent Packaging" Polymers 16, no. 17: 2402. https://doi.org/10.3390/polym16172402
APA StyleLi, H., Gao, K., Guo, H., Li, R., & Li, G. (2024). Advancements in Gellan Gum-Based Films and Coatings for Active and Intelligent Packaging. Polymers, 16(17), 2402. https://doi.org/10.3390/polym16172402