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Article

Impact of Harvesting Stages and Postharvest Treatments on the Quality and Storability of Tomato Fruits (Solanum lycopersicum L.) cv. Sangaw

by
Bzhwean Anwar Mouhamed
1,2,* and
Sidiq Aziz Sidiq Kasnazany
2
1
Director of Agriculture Training Center Region, General Director of Agriculture Research and Extension, Ministry of Agriculture and Water Rescores, Erbil 44001, Iraq
2
Horticulture Department, College of Agricultural Engineering Sciences, University of Sulaimani, Sulaymaniya 46001, Iraq
*
Author to whom correspondence should be addressed.
Coatings 2024, 14(9), 1143; https://doi.org/10.3390/coatings14091143
Submission received: 17 August 2024 / Revised: 2 September 2024 / Accepted: 3 September 2024 / Published: 5 September 2024
(This article belongs to the Special Issue Advanced Coatings and Films for Food Packing and Storage, 2nd Edition)
Browse Figures
Versions Notes

Abstract

:
The objective of this study was to evaluate the impact of harvesting stages (turning-color fruit and light red color) and postharvest treatments (distilled water, hot water at 35 °C, 10% Aloe vera, 2% CaCl2, 5% Mint, and 5% Catnip) for 5 min on the quality and storability of tomato fruits cv. Sangaw stored at 10 ± 1 °C and a relative humidity of 90%–95% for 20 days. Fruit harvested at the turning-color fruit stage presented significantly lower weight loss, greater firmness, and higher amounts of vitamin C, total phenol, and calcium (3.22%, 1118.31 g mm/s, 15.83 mg 100 g−1, 95.49 mg 100 mL−1 FW, and 0.14%, respectively). However, the tomatoes harvested from the light red color fruit stage presented the highest contents of total soluble sugars, total sugars, and lycopene (4.36%, 3.99%, and 41.49 mg kg−1, respectively). Notably, the postharvest treatment of tomato fruits with 2% CaCl2 significantly decreased weight loss and resulted in greater firmness, pH, total sugar, total phenol, and calcium contents (3.90%, 1212.39 g mm/s, 4.83, 3.85%, 95.60 mg 100 mL−1 FW, and 0.18%, respectively) than the control. Hence, coating with 10% Aloe vera resulted in the highest amount of total soluble solids and the highest amount of vitamin C. Tomato picked at the turning-color fruit stage and immersed in 5% Mint significantly lowered the loss of fruit weight, increased the total titratable acidity, and had the lowest content of lycopene. Additionally, the fruits harvested at the same stage and immersed in 2% CaCl2 retained greater firmness, total phenol content, and calcium content. On the other hand, fruits harvested in the light red stage and dipped in 5% Mint presented the highest total soluble sugars and total sugar contents. Finally, the harvested tomato fruits coated with 10% Aloe vera retained a relatively high level of vitamin C, indicating the storage life and quality of the tomato fruits.

1. Introduction

Tomato (Solanum lycopersicum L.) belongs to the Solanaceae family; it is one of the favored vegetable crops and is widely consumed worldwide [1]. Tomatoes are major vegetable crops in the Kurdistan region and Iraq and are grown throughout the country [2]. According to FAOSTAT (2021) [3], the world production of fresh tomatoes was estimated at over 189 million tons, although production in Iraq (including the Kurdistan region) was estimated at approximately 744 thousand tons. Tomatoes are freshly consumed in salads and sandwiches or in multiple processed forms, such as sauces, pastes, juices, preserves, and dried [4]. Tomatoes contain large amounts of organic acids, reducing sugars, pectin, and carotenoids. Antioxidants, such as lycopene and phenolic compounds, are found in tomatoes and tomato products and are low in fat and calories, most importantly, to reduce the risk of heart disease in the prostate, lungs, and stomach [5].
Tomatoes have a short postharvest life, limited shelf life, and high moisture content, leading to deterioration. Inadequate processing facilities result in decreased income and significant loss of farmer production, affecting the country’s economy [6]. The farm suffers losses of up to 50% in tomato production from harvesting to consumption due to inadequate management practices, knowledge of optimal harvest stages, unsuitable handling treatments, and insufficient storage systems [7]. Tomato fruits exhibit climacteric respiration and can be picked at various stages, such as maturity, half-ripening, or ripening [8]. Consumers worldwide demand high-quality, chemical-free, and long-lasting fruits, leading to increased efforts to use natural, eco-friendly, safe, and antimicrobial preservatives [9]. In this case, hot water is used to treat harvested fruit, which has the potential for controlling insects and disease; maintaining fruit quality and chilling injury symptoms; improving shelf-life [10]; and decreasing cell wall activity, enzymatic degradation, the disruption of ethylene synthesis enzymes and the inhibition of ripening [11]. The use of edible coatings is one way to increase postharvest shelf-life, decrease weight loss, and extend storage life [12,13]. Recently, there has been increased interest in the use of Aloe vera as a coating to prevent fruit loss from moisture, softening, a slow rate of respiration, senescence, and reduced microorganism growth, thereby slowing oxidative browning [14]. The postharvest application of CaCl2 has been reported to maintain firmness, reduce physiological disorders, reduce respiration, increase shelf life, and delay the ripening and aging of apples, tomatoes, and peaches [15].
Recently, natural substances have been used to prolong the shelf-life of tomato fruits and maintain fruit quality during storage by controlling fungal growth. Plant extracts can extend fruit shelf-life by 8%–10%, providing an alternative to microbial pathogens that cause fruit decay [16]. Additionally, it is less harmful to both humans and animals than artificial or chemical preservatives [17]. The use of plant extracts and natural coatings as biopreservatives, which are multipurpose, easy to use as food, edible, and medicinal, environmentally friendly, safe, inexpensive, and antioxidant, inhibits fungal growth, antimicrobial, and anti-inflammatory activities, and have health benefits, has been attempted. The use of environmentally friendly and physical methods such as Mint and Catnip extracts for decay control and postharvest loss is gaining attention in agricultural practice. On the other hand, the widespread use of fungicides and other chemicals has caused several adverse effects on environmental and human health.
Therefore, this research focused on prolonging shelf-life and tomato quality under cold storage when fruits are harvested at the turning-color fruit stage and light red stages of maturity. The fruits were also treated with both leaf extracts, Mint (Mentha spicata L.) and Catnip (Nepeta cataria L.), in hot water and dipped into a mixture of Aloe vera gel and calcium chloride.

2. Materials and Methods

2.1. Study Site

A greenhouse experiment was conducted in the Sheikh Jamal private field at Krbchna, Sangaw, which is located 77 km southwest of Sulaymaniyah Province in the Iraqi Kurdistan region. The global position system (GPS) coordinates (latitude: 35°28′20″ N, longitude: 45°27′70″ E, altitude: 979 m) and a geographical map of the research area are shown in Figure 1 [18]. The research area has an arid and semiarid climate [19].

2.2. Growth Condition, Harvesting, and Postharvest Treatments

The Sangaw cultivar (Figure 2) of tomato plants was planted in a greenhouse from spring to summer 2021 under protected conditions and standard agricultural practices such as soil preparation, sowing, the addition of manure and fertilizers, irrigation, weed control, pest management, and plant growth regulators, etc. The fruits were harvested at two different stages of maturity on the basis of their skin color (turning-color fruit stage and light red color stage), with the calyx attached to the tomato plants in the early morning (4 to 5 a.m.) on 18 July 2021.
Picked fruits were kept at 15 °C for 12 h to remove heat from the field and maintain a uniform temperature. Afterward, the fruits were carefully brought to the laboratory to avoid internal bruising and to apply various treatments (distilled water, hot water at 35 °C, 10% (w/v) Aloe vera jelly, 2% (w/v) calcium, 5% (w/v) Mint, and 5% (w/v) Catnip). Samples with no apparent mechanical injuries, insects, or diseases were selected according to their color.
The fruits were subsequently divided to apply the postharvest treatments. Each stage tomato was divided into 6 groups for dipping in the solutions of the treatments for 5 min and then air-dried for 60 min. Each treated fruit was divided into 3 replicates, packed in plastic boxes, and stored in a cold storage room with a relative humidity of 90%–95% and a temperature of 10 ± 1 °C for 20 days with continuous monitoring.

2.3. Fruit Quality Assays and Biochemical Tests

After storage, the following parameters were recorded to determine fruit quality: fresh weight loss (%) according to El-Badawy [20]; firmness (g mm/s) measured with an analyzer of texture, CT3 TEXTURE ANALYZER Manual No. M08-372-F1116 (BROOKFIELD ENGINEERING LABORATORIES, INC. 11 Commerce Boulevard, Middleboro, MA 02346 USA); and speed range from 0.1 mm/s to 2.0 mm/s, as described by the AOAC [21], the pH of the fruit juice was measured with a pH meter (pH/ISE/ORP/Temperature Meter, Benchtop, Digital, Model pH 211, HI2211-01, Hanna Equipments; made in Mumbai, India) [22], the total soluble solids (TSS%) were measured by a Digital Pocket Refractometer (ATAGO; Digital Hand-held “Pocket” Refractometer; Brand: ATAGO CO., LTD; Model: PL-1; made in Tokyo, Japan) [23]. The total titratable acidity (TTA%) was calculated as described by Tomadoni et al. [24], the total sugar content (%) was determined according to Joslyn [25], the lycopene content (mg kg−1) was measured as described by Suwanaruang et al. [26], the vitamin C content (mg 100 g−1 FW) was calculated via the method described by Ranganna [27], the total phenol content (mg 100 mL−1 FW) was estimated via a spectrophotometer (Shimadzu—UV-1700, Spectrometer (Molec.): UV/VIS, Kyoto, Japan) at a wavelength of 535 nm [27], and calcium (%) was determined via Walsh and Beaton [28].

2.4. Statistical Analysis

The experiment was carried out as a factorial experiment consisting of two factors:
  • Factor 1 involves two levels of maturity stages (turning-color fruit and light red color).
  • Factor 2 included six levels of postharvest treatments (distilled water, hot water at 35 °C, 10% Aloe vera, 2%CaCl2, 5% Mint, and 5% Catnip), and their interaction effects between factor 1 and factor 2, the experiment that included 36 treatments (2 maturity stages × 6 postharvest treatments × 3 replications = 36 experimental units). A complete randomized design (CRD) was used. The analysis of variance (ANOVA) and data were analyzed by Duncan’s multiple range test (DMRT) at the 0.05 level via the statistical (XL-STAT) program.

3. Results and Discussion

3.1. Loss of Fresh Weight

Tomato fruits are harvested at different maturity stages, which significantly affects the loss of fresh weight (LFW), which is the first indicator of deterioration and a decrease in the quality of tomato fruits. As shown in Table 1, the variation in fresh weight loss was significant between the two stages of maturity. Compared with that of fruits stored in the light red color stage (6.04%), significantly less weight loss (3.21%) was noted in the turning-color fruit stage.
Regarding the postharvest treatments, it can be noticed from the data presented in the same table that the weight loss decreased significantly in all postharvest treatments except the control treatments. Among all the treatments, fruits immersed in 2% CaCl2 for 5 min presented LFW (3.90%).
The effects of the interaction between maturity stages and postharvest treatments on LFW. The lowest values (2.12%) were observed from the turning-color fruit stage with 5% Mint extract, whereas the highest value (7.99%) was observed at the light red maturity stage with distilled water (Table 1). Postharvest losses significantly affect the quality of fresh produce and are the major cause of deterioration. In general, lower weight loss allows for a longer storage life of the tomatoes, and a 5%–10% loss is acceptable for most agricultural products, including tomatoes [11]. These results were similar to those of the studies of Famuy et al. [29], in which the highest fresh weight loss occurred in the light red stage of maturity; likewise, low weight loss in the turning-color fruit stage could be stored for a longer period. Weight loss is an important indicator of the quality and shelf-life of fruits [30]. The loss of fruit occurs from moisture and carbohydrates [31] due to the loss of water through evaporation and carbon reserves as a result of respiration [32]. The severity of storage loss depends on the degree of maturity [8]. The water content and waxy layer present in fruits act as barriers to loss [33]. The juice content was significantly greater in the yellow stage than in the other mature stages, which may be due to the slightly developed wax on the skin fruit at the break color stage during storage. Surface wax, the most mature form of wax, is lost [34]. The coating prevents water loss and protects the fruits from damage caused by mechanical injury. Compared with papaya fruits coated with Aloe vera (7.93%), those not coated with Aloe vera lost more weight (22.50%) during storage [35]. The hygroscopic characteristics of Aloe vera may be the reason for this beneficial effect in terms of reducing moisture loss. Aloe vera helps create water barriers between the fruit and its environment, thus preventing external transfer [36]. Furthermore, CaCl2 has also been linked to decreased weight loss because of its more effective protective effect in mitigating fresh weight loss than the control [30]. CaCl2 could be due to the main role of calcium in creating calcium pectate hydrogels by retaining more water, which slows the process of dehydration [37]. Similar results were reported by Hao et al. [38], who used 2% CaCl2 and two temperatures (40 and 50 °C) of hot water-dipped tomato fruits for 2 min.

3.2. Firmness

Firmness is one of the most imperative points and plays an important role in the quality attributes of tomato fruits with respect to consumer acceptance [39]. As shown in Table 2, with respect to tomato firmness, the turning-color fruit stage (1118.31 g mm/s) is significantly firmer than the light red-colored stage (911.88 g mm/s). For the postharvest treatments, there was a significant difference in firmness among the 2% CaCl2, 10% Aloe vera, 5% Mint, and 5% Catnip treatments compared with the distilled water (control) treatment, where these treatments preserved the firmness of the fruits significantly more than the control treatment. Research conducted by Senevirathna and Daundasekera [40] revealed that the firmest fruits were those treated with 2% CaCl2, whereas the lowest firmness was found in control fruits.
Similarly, the interaction between the stage of maturity and the immersion treatment of fruits harvested in the turning-color fruit stage with 2% CaCl2 resulted in the highest firmness (1251.25 g mm/s), whereas the lowest value (701.50 g mm/s) was observed for light red fruits immersed in distilled water.
The firmness obtained in this study was comparable with the results reported by Arthur [41], who reported that breaker- and pink-stage fruits were much firmer than light red fruits [30]. The tomato fruits in the CaCl2 treatment were firmer than those in the other treatments and the control. Generally, fruit firmness decreases with increasing maturity. Fruit softening occurs in the cell wall via the enzymes hydrolase (polygalacturonase and pectinestarase), which cause changes in the structure and composition of the cell wall, increasing pectin solubilization and decreasing firmness [42]. There are other reasons for decreasing firmness during storage, such as moisture loss [43], polysaccharide degradation, or the presence of ethylene in fruits [44]. Poovaiah [45] reported that the application of calcium to fruits improves fruit quality and maintains firmness; it is the most important mineral involved in middle lamellae, helps to bind polygalactonic acid, provides rigidity and a strong membrane with delayed senescence, and reduces the respiration rate and transpiration in tomato fruits. With respect to the use of hot water after harvesting fruits, previous results were similar to those of Safdar Khan [11], who reported that tomato fruits treated with hot water were firmer than untreated fruits. This may be due to the inhibition of cell wall hydrolytic enzymes. In terms of Aloe vera application, table grapes retain significantly more firmness during cold storage [46].

3.3. pH of Fruit Juice

As shown in Table 3, there was no significant difference in the pH value between fruits in the turning-color fruits stage and those in the light red maturity stage stored at 10 °C and 90%–95% RH for 20 days. On the other hand, significant differences were found between the 2% CaCl2 treatment and the other treatments, with 2% CaCl2 resulting in the highest value (4.83). The high pH value clearly resulted from the interaction between the light red color stage of fruits immersed in 2% CaCl2, whereas the lowest value was obtained from the interaction between the turning-color fruits stage immersed in 5% Catnip extract. pH represents the acidity/alkalinity value that can be dramatically altered by the growth of microbes. Calcium had a significant effect on pH. The highest value (4.49) was recorded for the control treatment. The lowest value (4.47) was obtained from the calcium treatment [47]. Since the decrease in pH was greater in the control treatment, it may have returned to acid oxidation during storage, which led to a lower pH value. Additionally, the reason could be related to the development of microorganisms, which cause the development of organic acids [48]. Similarly, calcium chloride lowered the pH value [49]. Therefore, acidity is influenced by the different organic acids that are consumed during respiration, so acidity tends to decrease as the fruit ripens or as storage time increases with increasing fruit pH [8].

3.4. Total Titratable Acidity (TTA%)

In the present study, no significant difference in TTA% was detected between tomato fruits stored during the two stages of maturity. On the other hand, significant differences in acidity were observed between treated and untreated tomato fruits, with the highest acidity content (0.67%) recorded in the 5% Mint extract group and the lowest value (0.48%) obtained in the distilled water treatment group after the storage period (Table 4).
The interaction effect between the maturity stage and postharvest treatment had a significant effect on the TTA of tomato fruits. Tomatoes harvested in the turning-color fruits stage immersed with the 5% Mint extract were the most effective at preserving acidity, while the lowest value of acidity was recorded for the light red color treated with distilled water. This may be due to the decrease in TTA in fruits treated with distilled water (control), which quickly consumed the acid content during the respiration process and increased metabolic activity [50]. TTA plays an important role in determining fruit maturity. Organic acids are the second most important energy source after carbohydrates as substrate materials for respiration [51]. Our results were also confirmed by Tripathi and Dubey [52], who reported that Aloe vera induces a greater TTA and increases the TSS in coated berries, which indicated that, compared with coated berries, uncoated fruits are more developed to ripen during storage periods because they utilize acids for respiration during storage [53] and accelerate the metabolic activities of living tissues or convert them into sugars via gluconeogenesis [54]. Conversely, total sugars and TSS increased during storage [55].

3.5. Total Soluble Solids (TSS%)

Table 5 shows that significant differences were observed between the stages of maturity of the TSS in the tomato fruit cv. Sangaw stored for 20 days at 10 ± 1 °C and 90%–95% RH. Compared with those in the turning-color fruit stage, the fruits harvested in the light red stage were more effective at attaining the highest values of TSS, with values of 4.36 and 3.82%, respectively. In addition, significant differences were found between the postharvest immersion treatments; the highest TSS (4.27%) was from the 10% Aloe vera. The difference was significant compared with that of the distilled water treatment (control), which resulted in the lowest (3.93%) amount of TSS. The data in the same table show that significant differences in the effects of the interaction between the stages of maturity and the postharvest treatment on the TSS content were detected. The maximum value (4.60%) was obtained from the turning-color fruit stage fruits immersed in 5% Mint, whereas the lowest value (3.57%) was obtained from the turning-color fruit stage fruits immersed in 35 °C hot water.
During storage, the main cause of weight loss is water loss, which results in a relatively high sugar content in the fruit. The study was carried out by Agar and Kaska [56], who reported the same results. In the ripening stage, polysaccharide degradation occurs, and polysaccharides are converted to simple sugars, thereby increasing the TSS [57]. Compared with those in the pink stage, the fruits in the breaker stage presented a low TSS percentage. Generally, increased TSS develops with maturity and during storage [31] and may be returned to starch breakdown and converted to sugars or polysaccharides by hydrolysis in the cell wall [58].

3.6. Total Sugar Percentage

After storage for 20 days, the total sugar content was significantly affected by the maturity stage (Table 6). The highest total sugar content (3.99%) was obtained in light red fruits, followed by 3.38% recorded in tomato fruits picked at the turning-color fruit stage. Regarding the effect of postharvest treatments, the maximum content was recorded at 2% CaCl2, and the minimum value recorded in distilled water was (3.85%) and (3.45%), respectively. With respect to the interaction effect between the maturity stage and the postharvest treatment on the total sugar content in the tomato fruits after the storage period, the highest value resulted from the interaction between 5% Mint at light red color fruits, whereas the lowest value was from the interaction between distilled water at the turning-color fruit stage of maturity. In addition, no significant differences were found between 5% Mint and 5% Catnip in light red color fruits. Sugar content was significantly affected by the harvest stages; it increased from the turning to the light red-colored fruit stage. Additionally, a similar increase in sugar content was detected in citrus fruit at the mature stage [8]. The same result obtained by Moneruzzaman et al. [59] was that the sugars varied according to the harvest stage. Sugar level increased with the development of maturation fruits from the green to the red color stage. The increase in sugars may be due to starch being converted into sugars.
Sugars have been shown to increase during ripening and decline after peak ripening [60], as indicated in previous works by Migliori et al. [61], which showed that the sugar content increased from the pink stage to the red stage of tomato fruits. In general, products with higher respiration rates will ripen faster and have a shorter shelf life than products with lower respiration rates. The metabolic activity of tissues can be monitored by the respiration rate [62]. Accordingly, the rate of change in sugars is an indicator of the respiration rate in fruits. Furthermore, starch conversion to sugar occurs before peak climacteric respiration; the respiration rate indicates the rate at which respiratory substrates (starch, sugars, and organic acids) are broken down [63].

3.7. Vitamin C

Vitamin C is a natural antioxidant in many fruits and vegetables and has important nutritional advantages for human health. It is used as an index of overall quality deterioration. The levels of vitamin C in tomato fruits vary greatly depending on the stage of harvesting. Compared with those harvested at the turning-color fruits stage the tomato fruits harvested at the turning-color stage of maturity presented greater vitamin C contents (Table 7). Regardless of the postharvest treatment, 10% Aloe vera resulted in the highest content of vitamin C, while the lowest value was obtained from the control (distilled water). However, no significant differences were found between the control and 35 °C hot water. Additionally, no significant differences were found between most of the dipping tomato fruits after harvest in vitamin C content between 10% Aloe vera, 2% CaCl2, 5% Mint, and 5% Catnip. These last treatments are significantly superior to previous (control and 35 °C hot water) treatments. On the other hand, it is clear from the data presented in the same table regarding the vitamin C content that fruit dipped in 10% Aloe vera in the turning-color fruits stage of maturity resulted in the highest value (16.99 mg 100 g−1 FW), whereas the minimum value (10.29 mg 100 g−1 FW) was obtained from the interaction effect between the control and light red-colored fruits. These results were in accordance with those of Grierson and Kader [64], in which the content of 100 g ranged from 15 to 23 mg.
These results are also in accordance with the findings of Bhattacharya [65], who reported that the ascorbic acid content of fresh fruit reached its maximum just before ripening and then decreased due to the action of an enzyme called ascorbic acid oxidase. Dandago et al. [66] reported that an increase in ascorbic acid is an indication that the fruit is still in the ripening stage, whereas a decrease in ascorbic acid indicates senescent fruit. These findings are in agreement with the results of Moneruzzaman et al. [8], who reported that the maximum vitamin C content in tomato fruits was recorded at the breaker stage and was reduced at the yellow and pink stages of maturity. In addition, coated oranges have a higher vitamin C content than uncoated oranges [67], which is in agreement with our results. Furthermore, Brishti et al. [35] reported that Aloe coated in papaya fruits had a higher concentration of vitamin C during storage.
The same result was reported for Aloe gel-coated nectarines by Ahmed et al. [68]. This was due to the low oxygen permeability of the coating, which delayed the deterioration of the oxidative reaction of the vitamin C content [69]. According to Srinu et al. [70], coating fruits reduces respiration and preserves vitamin C in those fruits. In previous studies, treating strawberry fruits with 1, 2, and 3% CaCl2 resulted in the highest levels of sugars, total titratable acidity, and vitamin C, the best overall acceptability, a shelf life of 7 days [71], and a slight decrease in the retention of a high amount of vitamin C [72]. High acidity and phenolic compounds are responsible for the stability of vitamin C in the breaking stage of storage because of its protective effect and antioxidant properties [73]. These results are in agreement with those of Dumas et al. and Toor and Savage [74,75].

3.8. Lycopene Content

The color assessment is the most remarkable exterior attribute for estimating the ripeness and shelf-life of tomato fruits, and it is a key factor in determining what the consumer prefers [76]. Tomato fruit contains major antioxidant compounds, such as carotenoids (lycopene) and ascorbic acid. The amount of these components varies with the stage of maturity; the present findings are in accordance with the reports of [77]. Table 8 shows that the lycopene content in fruits harvested in the light red color after being stored for 20 days at 10 °C was significantly greater (41.49 mg kg−1) than that in fruits at the turning-color fruit stage of maturity (32.92 mg kg−1). With respect to the postharvest treatments, there was a non-significant effect between all the treatments except the control, with a significantly greater content of lycopene (48.29 mg kg−1). As indicated in the same table, the effect of the combination of the maturity stage and postharvest treatments was obtained from light red fruit treated with distilled water (58.57 mg kg−1), while there was no significant difference between the other treatments. These results are in line with those obtained by Ali et al. and Daraghmah and Qubbaj [12,78]. The red color of a ripe tomato results from a new synthesis of carotenoids such as lycopene and beta-carotene [79]. The results indicated that the delay of lycopene synthesis in tomato fruits treated with 35 °C hot water, 10% Aloe vera, 2% CaCl2, 5% Mint, and 5% Catnip might result from the preservation of chlorophyll content and reduced biosynthesis of carotenoids [12]. All these reports revealed a similar delay in ripening, the breakdown of chlorophyll, and lycopene formation during red color development following the postharvest application of the Aloe vera coating, CaCl2, and water [40,80]. The reason for the delay in color formation is the inhibition of lycopene or lycopene precursor (pristoene and phyto-fluene) biosynthesis [81].

3.9. Total Phenol Content

Table 9 shows that the total phenol content in the tomato fruits significantly differed. The total phenol content was influenced by the fruit stage of maturity, where the turning-color fruit stage of the tomato fruits presented the highest value (95.49 mg 100 mL−1 FW) of total phenol content compared with that of the light red color fruits, which presented a statistically significant decrease (63.75 mg 100 mL−1 FW) in total phenol content. However, the total phenol content was significantly greater in the fruit samples subjected to 2% calcium chloride treatment (95.60 mg 100 mL−1 FW). These results showed that CaCl2 treatment had a significant effect on retaining the total phenol content of the tomato fruits. The lowest total phenol content (62.26 mg 100 mL−1 FW) was observed in the distilled water treatment. The interaction effect between the stage of maturity and the number of postharvest dips was statistically significant. The fruits that were dipped in 2% CaCl2 for 5 min and harvested in the turning-color fruits stage presented the highest total phenol content, whereas the lowest content was in distilled water for the light red fruits.
Indeed, tomatoes are rich sources of nutrients and phytochemicals, including phenolic compounds (chlorogenic acid, caffeic acid, and rutin), which are several bioactive components in fresh tomatoes and tomato-based products [82]. Phenolic content levels are highly variable and may be influenced by the degree of maturity, variety, and agricultural practices [83]. However, under open field conditions, some factors affect phenolic compounds, such as genetics, light, temperature [84], and geographical and seasonal factors [85].

3.10. Calcium Content

Table 10 shows the significant differences in calcium content between the two maturity stages of tomato fruits. The highest value (0.14%) was recorded from the turning-color fruit stage, whereas the lowest value (0.10%) was observed from the light red fruit stage. Furthermore, tomato fruits dipped in 2% CaCl2 were significantly superior to those subjected to the other postharvest treatments. The same table shows that there were significant differences in calcium content among the stages of maturity combined with postharvest dipping; the highest value (0.21%) was recorded from the interaction between fruits in the turning-color fruits stage dipped in 2% CaCl2, whereas the lowest value (0.07%) was observed from the light red stage fruits dipped in distilled water (control).
In recent years, the application of CaCl2 to fruits has received considerable attention before and after harvest because of its beneficial effects on extending shelf life, delaying fruit color development, slowing ethylene production, maintaining quality [40], slowing ripening and senescence, maintaining firmness, slowing the respiration rate, and inducing disorders in fruits and vegetables [86]. Calcium chloride can be associated with the formation of a calcium network with pectin in cell wall fruits [87] and increases the rigidity and strength of the middle lamella to form calcium pectate [88].

4. Conclusions

Like other fruits, tomato fruits change constantly after harvest. They are living tissues that cannot be stopped, but they can be slowed down within certain limits to extend their shelf life, and we proceed to find some postharvest treatments to extend their storage life and marketability and maintain quality. Therefore, farmers and producers of tomato fruits can prolong storability, maintain quality, and export to distant regions with minimal losses when harvested at the turning-color fruit stage and dipped in 2% CaCl2. The use of some natural substances, such as Aloe vera and plant extracts, is because these materials are safe, healthy, and environmentally friendly.

Author Contributions

Conceptualization, S.A.S.K.; methodology, B.A.M.; data curation, B.A.M.; formal analysis, S.A.S.K.; writing—original draft preparation, S.A.S.K. and B.A.M.; writing—review and editing, S.A.S.K. and B.A.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

This article contains all the data.

Acknowledgments

The authors are grateful to Sheikh Jamal Jalal Krbchna for helping us carry out this research.

Conflicts of Interest

The authors declare no conflicts of interest.

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Coatings 14 01143 g001
Figure 1. Site study of the experiment.
Figure 1. Site study of the experiment.
Coatings 14 01143 g001
Coatings 14 01143 g002
Figure 2. Tomato fruit of the Sangaw cultivar.
Figure 2. Tomato fruit of the Sangaw cultivar.
Coatings 14 01143 g002
Table 1. Fresh weight loss% of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Table 1. Fresh weight loss% of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruit5.24 c2.28 e4.09 d2.84 e2.12 e2.65 e3.21 b
Light red color fruits7.99 a5.99 bc3.97 d4.96 cd6.37 b6.99 ab6.04 a
Main effects of
postharvest treatments		6.62 a4.13 bc4.03 bc3.90 c4.24 bc4.82 b
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 2. Firmness (g mm/s) of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Table 2. Firmness (g mm/s) of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruits987.08 bc1077.33 abc1135.50 ab1251.25 a1079.58 abc1179.08 ab1118.31 a
Light red color fruits701.50 e741.25 de1044.83 abc1173.52 ab953.17 bcd857.00 cde911.88 b
Main effects of
postharvest treatments		844.29 d909.29 cd1090.17 ab1212.39 a1016.38 bc1018.04 bc
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 3. pH values of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Table 3. pH values of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruits4.64 de4.70 cde4.77 abc4.81 ab4.70 cde4.63 e4.71 a
Light red color fruits4.74 bcd4.75 bc4.70 cde4.86 a4.70 cde4.68 cde4.74 a
Main effects of
postharvest treatments		4.69 bc4.73 b4.74 b4.83 a4.70 bc4.65 c
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 4. TTA% of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Table 4. TTA% of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruits0.52 bc0.61 ab0.65 ab0.53 bc0.73 a0.63 ab0.61 a
Light red color fruits0.45 c0.53 bc0.64 ab0.66 ab0.61 ab0.53 bc0.57 a
Main effects of
postharvest treatments		0.48c0.57 bc0.65 ab0.60 ab0.67 a0.58 ab
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 5. TSS% of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Table 5. TSS% of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruits3.67 ef3.57 f4.03 cde4.13 abc3.77 def3.70 ef3.82 b
Light red color fruits4.20 abc4.33 abc4.50 ab4.23 bcd4.60 a4.40 abc4.36 a
Main effects of
postharvest treatments		3.93 b3.95 b4.27 a4.18 ab4.18 ab4.05 ab
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 6. Total sugar percentage of tomato fruits cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days in different maturity stages, and postharvest treatments with their combinations.
Table 6. Total sugar percentage of tomato fruits cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days in different maturity stages, and postharvest treatments with their combinations.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruits3.17 g3.27 fg3.37 ef3.61 d3.43 e3.41 e3.38 b
Light red color fruits3.73 d3.86 c3.96 bc4.08 ab4.20 a4.12 a3.99 a
Main effects of
postharvest treatments		3.45 d3.56 c3.67 b3.85 a3.81 a3.76 a
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 7. Vitamin C (100 g−1 FW) was added to the fruits of the tomato cultivar Sangaw, which were stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages.
Table 7. Vitamin C (100 g−1 FW) was added to the fruits of the tomato cultivar Sangaw, which were stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruits14.76 a–d14.19 b–e16.99 a16.58 ab16.65 ab15.82 a–c15.83 a
Light red color fruits10.29 f11.99 ef14.79 a–d13.75 c–e13.02 de14.28 a–c13.02 b
Main effects of
postharvest treatments		12.52 b13.09 b15.89 a15.17 a14.83 a15.05 a
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 8. Lycopene content (mg kg−1) of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Table 8. Lycopene content (mg kg−1) of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruits38.15 bcd29.54 d31.60 cd35.14 bcd28.85 d34.35 bcd32.92 b
Light red color fruits58.57 a38.23 bcd32.67 cd35.96 bcd43.05 b40.43 bc41.49 a
Main effects of
postharvest treatments		48.29 a33.88 b32.14 b35.55 b35.95 b37.39 b
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 9. Total phenol content (mg 100 mL−1 FW) of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Table 9. Total phenol content (mg 100 mL−1 FW) of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages and postharvest treatments with their combinations.
Maturity
Stage		Postharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects Of Maturity Stage
Turning-color fruits72.80 d87.00 c93.13 bc118.66 a103.40 b97.93 bc95.49 a
Light red color fruits51.73 e66.00 d66.47 d72.53 d62.40 de63.40 d63.75 b
Main effects of
postharvest treatments		62.26 c76.50 b79.80 b95.60 a82.90 b80.66 b
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
Table 10. Calcium content (%) of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages after different combinations of postharvest treatments.
Table 10. Calcium content (%) of tomato fruits from cv. Sangaw stored at 10 ± 1 °C and 90%–95% RH for 20 days at different maturity stages after different combinations of postharvest treatments.
Maturity StagePostharvest Treatments
Distilled Water35 °C
Hot Water		10%
Aloe vera		2% CaCl25% Mint5% CatnipMain Effects of Maturity Stage
Turning-color fruits0.09 e–h0.11 d–g0.18 b0.21 a0.13 cd0.12 d–f0.14 a
Light red color fruits0.07 h0.08 gh0.12 de0.15 bc0.10 d–h0.09 f–h0.10 b
Main effects of
postharvest treatments		0.08 d0.09 cd0.15 b0.18 a0.11 c0.10 cd
Means with different letters indicate a significant difference in the maturity stage effect within a column and the postharvest treatments effect within a row, and their interactions at the 5% level according to Duncan’s multiple range test.
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MDPI and ACS Style

Mouhamed, B.A.; Kasnazany, S.A.S. Impact of Harvesting Stages and Postharvest Treatments on the Quality and Storability of Tomato Fruits (Solanum lycopersicum L.) cv. Sangaw. Coatings 2024, 14, 1143. https://doi.org/10.3390/coatings14091143

AMA Style

Mouhamed BA, Kasnazany SAS. Impact of Harvesting Stages and Postharvest Treatments on the Quality and Storability of Tomato Fruits (Solanum lycopersicum L.) cv. Sangaw. Coatings. 2024; 14(9):1143. https://doi.org/10.3390/coatings14091143

Chicago/Turabian Style

Mouhamed, Bzhwean Anwar, and Sidiq Aziz Sidiq Kasnazany. 2024. "Impact of Harvesting Stages and Postharvest Treatments on the Quality and Storability of Tomato Fruits (Solanum lycopersicum L.) cv. Sangaw" Coatings 14, no. 9: 1143. https://doi.org/10.3390/coatings14091143

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