Application of Processing and Packaging Hurdles for Fresh-Cut Fruits and Vegetables Preservation
Abstract
:1. Introduction
2. Principal Modes of Deterioration of Fresh-Cut Fruits and Vegetables
2.1. Microbial Spoilage
2.2. Physiological Activity
2.3. Factors Related to Degradation of Sensory Characteristics
2.3.1. Water Loss
2.3.2. Texture Changes
2.3.3. Color Changes
2.3.4. Flavor/Taste and Nutritional Changes (Changes of Composition)
3. Hurdles Applied in the Preservation and Shelf-Life Extension of Fresh-Cut Fruits and Vegetables
3.1. Conventional Hurdles
3.1.1. Short Time Heat Treatments
3.1.2. Low Temperatures
3.1.3. Chemical Preservation (with or without pH Control)
3.1.4. Water Activity Decrease
3.1.5. Biological Methods (Biopreservation)
3.2. Emerging Techniques in the Hurdle Integrated Technology
4. Protection of Fruits and Vegetables by Appropriate Packaging Methods
4.1. Gas and Controlled/Modified Atmosphere, Edible Coatings and Other Forms of Packaging (This Will Be Described in Detail in the Following Section)
4.2. Active Packaging of Fruits and Vegetables (Including Antimicrobial Packaging)
- -
- Antimicrobial sachets: enclosure into packages of sachets that contain volatile antimicrobial agents
- -
- Antimicrobial films: incorporation of volatile or nonvolatile antimicrobial compounds into the formulation of packaging films
- -
- Antimicrobial edible coatings: direct application on the food surface of antimicrobial edible coatings or films. In this case, the main component of the coating may be a polymer with antimicrobial property (e.g., chitosan), or additional antimicrobial agents are added in the film-forming solution [6].
4.3. Smart Labels for Fruits and Vegetables
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Matrix Tested | Hurdles Applied | Main Indices Studied | Main Results | References |
---|---|---|---|---|
Fresh-cut cantaloupe |
| aerobic mesophilic plate count, anaerobic mesophilic plate count and yeast and mold populations | A 28- and 24-day shelf-life extension of the combined method compared to the untreated and alginate-coated samples, respectively. | [54] |
Fresh-cut tomatoes |
|
| A 74- and over 240-day shelf-life extension of OD and the combined method (OD-HHP) compared to the untreated samples, respectively. | [55] |
Fresh-cut apple |
|
|
| [56] |
Fresh-cut bell peppers |
|
| The optimized condition of the combined treatment was SAEW + US + 60 °C for 1 min, with minimal changes in quality indices | [57] |
Fresh-cut apple | Ultrasound Ascorbic acid | Enzyme inactivation (monophenolase, diphenolase, and peroxidase) | The combined application of ultrasound and ascorbic acid showed synergistic inhibitory effects on enzymes related to enzymatic browning. | [58] |
Fresh-cut peach and apricot |
|
| Shelf-life estimated at 309 and 320 days at 4 °C, for OD/HP peach and apricot, respectively, compared to approximately 68–86 days, for OD samples, when non-treated samples are expected with a shelf life of 5–7 days at cold storage. | [59] |
Fresh-cut apples |
|
| Combined application of CMC (1%) with HR (0.01%) + AA (0.5%) + CaCl2 (0.2%)—the most effective treatment for quality preservation and reduction of surface browning in fresh-cut wedges during storage for 7 days at 5 ± 2 °C. | [60] |
Fresh-cut lotus roots |
|
| Dipping in an AA + CM antibrowning treatment and 100% CO2 MAP with a heat treatment extended the shelf-life to 21 days at 5 °C. | [61] |
Fresh-cut apples |
|
|
| [62] |
Fresh-cut strawberry |
|
| Shelf life was significantly extended for both OHP and OD (up to 10 and 4 months at 5 °C, respectively) compared to untreated samples (7 days at 5 °C). The addition of L-cysteine added in the OD solution exhibited an exceptional red color intensity and stability. | [63] |
Fresh-cut rocket |
|
| The 20 kJ UV-C/m2 treatment reduced the microbial load of the fresh-cut rocket during 8 days of storage at 5 °C. | [64] |
Freshcut pear cubes |
|
| The combination of mild heat treatment (3 min at 95 °C)/MAP under aseptic conditions improved the stability. | [65] |
Fresh-cut leafy salad (lollo rosso lettuce, lollo verde lettuce, and rocket) |
| Total viable count, Pseudomonas spp., lactic acid bacteria, vitamin C, color, and texture | Development and validation of adequate predictive shelf-life models. | [66] |
Dandelion leaves |
| Total viable count, Pseudomonas spp., lactobacilli, yeasts, and molds, Enterobacteriaceae spp., texture, enzymatic activity, vitamin C concentration and sensory evaluation | MAP resulted in a 1-day extension of shelf life compared to conventional aerobic storage in perforated films. Development and validation of adequate predictive shelf-life models. | [67] |
Plum and strawberry |
| Moisture loss, gas and water vapor transfer | Development and validation of adequate simulation program for the preservation of packed fruit. | [13] |
Peach and cherry tomatoes |
| In package CO2, O2, and C2H4 | Biodegradable laser-microperforated PLA films were designed for fruit packaging and preservation. | [68] |
Fresh-cut tomatoes |
| GO volatile release, total viable count, yeasts and molds, coliforms and E. coli, sensory evaluation | Tomato was affected by the highest concentration of GO capsules, showing lower microbial growth and higher sensory quality. | [69] |
Papaya |
|
| Sachets containing cinnamon, oregano, and lemongrass resulted in a significant reduction in the growth of mesophilic aerobic bacteria, yeasts, and molds. | [70] |
Fresh spinach |
| AIT release, antimicrobial effect against E. coli O1§75:H7, yeasts, and moulds | The load of E. coli O157:H7 on spinach leaves decreased by 1.6–2.6 log CFU/leaf at 4 °C and 2.1–5.7 log CFU/leaf at 25 °C within 5 days. | [71] |
Mangoes |
| Weight loss, firmness, colour, soluble solids, vitamin C, titratable acid, and nutritional value | Mango showed quality degradation after 21 days of storage. The chlorine dioxide microcapsule antibacterial film preserved the high quality for longer storage periods. | [72] |
Tomatoes |
| Respiration rate, ethylene | Coating increased the internal CO2 concentration and decreased the internal O2 levels in tomato samples. | [73] |
Cherry tomatoes |
| Color, weight loss, firmness, soluble solids, pH, and molds and yeasts | The edible coating with protein hydrolysate inhibited the proliferation of molds and yeasts. | [74] |
Tomatoes | Edible coating with Flourensia cernua extract | Sensory evaluation, weight loss, firmness, pH, colour | The edible coating incorporated with F. cernua extract was the most effective in delaying pathogenic fungi growth and preserving the visual appearance of the final product at the end of the storage period. | [75] |
Peach |
| Carotenoids content, phenolic content, reducing activity, titratable acidity, total soluble content, weight loss, and vitamin C content | The single and combined application of aloe-based coating slowed down the maturation processes of the fruit, delayed the weight loss, and preserved the sensory properties of the final products. | [76] |
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Giannakourou, M.C.; Tsironi, T.N. Application of Processing and Packaging Hurdles for Fresh-Cut Fruits and Vegetables Preservation. Foods 2021, 10, 830. https://doi.org/10.3390/foods10040830
Giannakourou MC, Tsironi TN. Application of Processing and Packaging Hurdles for Fresh-Cut Fruits and Vegetables Preservation. Foods. 2021; 10(4):830. https://doi.org/10.3390/foods10040830
Chicago/Turabian StyleGiannakourou, Maria C., and Theofania N. Tsironi. 2021. "Application of Processing and Packaging Hurdles for Fresh-Cut Fruits and Vegetables Preservation" Foods 10, no. 4: 830. https://doi.org/10.3390/foods10040830
APA StyleGiannakourou, M. C., & Tsironi, T. N. (2021). Application of Processing and Packaging Hurdles for Fresh-Cut Fruits and Vegetables Preservation. Foods, 10(4), 830. https://doi.org/10.3390/foods10040830