E ﬀ ect of 1-Methyl Cyclopropane and Modiﬁed Atmosphere Packaging on the Storage of Okra ( Abelmoschus esculentus L. ): Theory and Experiments

: Okra possesses a short shelf-life which limits its marketability, thereby, the present study investigates the individual and combined e ﬀ ect of 1-methylcyclopropene (1-MCP) and modiﬁed atmosphere packaging (MAP) on the postharvest storage life of okra. The treated / untreated okra samples were stored at ambient (i.e., 27 ◦ C) and low (i.e., 7 ◦ C) temperatures for eight and 20 days, respectively. Results revealed that the 1-MCP and / or MAP treatment successfully inhibited fruit softening, reduction in mucilage viscosity, and color degradation (hue angle, ∆ E , and BI) in the product resulting in a longer period of shelf-life. However, MAP with or without 1-MCP was more e ﬀ ective to reduce weight loss in okra stored at both ambient and cold storage conditions. Additionally, ascorbic acid and total antioxidants were also retained in 1-MCP with MAP during cold storage. The 1-MCP in combination with MAP e ﬀ ectively suppressed respiration rate and ethylene production for four days and eight days at 27 ◦ C and 7 ◦ C temperature conditions, respectively. According to the results, relatively less chilling injury stress also resulted when 1-MCP combined with MAP. The combined treatment of okra pods with 1-MCP and MAP maintained the visual quality of the product in terms of overall acceptability for four days at 20 ◦ C and 20 days at 7 ◦ C.


Introduction
Okra (Abelmoschus esculentus L.) is a highly nutritious vegetable of tropical and subtropical regions of the world [1,2], also known as "Bhindi Tori" in Pakistan [3] and "ladies' fingers" in English-speaking The harvested okra was immediately transported to the Post Harvest Research Center (PHRC) laboratory of the institute. The fruit was sorted visually based on uniformity in color, shape, size, and free from disease symptoms.

Experimental Design
Pods were investigated for harvest day (day 0) analysis before the application of any treatment. After the initial investigation, the fruit was divided into two main groups. Each group was further divided into four equal lots, containing: (1) control (untreated); (2) 1-MCP (unpacked); (3) MAP (untreated with 1-MCP); (4) 1-MCP + MAP. One group was stored at ambient temperature (27 ± 2 • C) for eight days and the other was kept at low-temperature storage (7 ± 1 • C) for 20 days. The relative humidity for both the ambient and low-temperature storage was 80-85% [1,24].

1-MCP Application
For 1-MCP treatment, pods were kept in an air-tight chamber of volume 110 L. The 1-MCP (5 µL/L) gas was generated by adding 4.4 mL distilled water (45-50 • C) into the 0.88 g of 1-MCP powder (SmartFresh™, 0.14% active ingredient). The concentration of 1-MCP was calculated by the percentage of the active ingredient in 1-MCP powder and the volume of the chamber. The chamber was immediately sealed after adding water to 1-MCP powder for 16 h at 20 • C [24].

Modified Atmosphere Packaging (MAP)
A preliminary trial was conducted a few days before to assess whether the low-density polyethylene (LDPE) film was suitable for preserving the okra samples at 27 • C and 7 • C for eight and 20 days, respectively, before conducting the actual experiment. The purpose of this assessment was to confirm that the CO 2 and O 2 concentrations inside the LDPE bags were within the recommended limit for okra storage; that is, CO 2 in the range of 4-10% and O 2 in the range of 3-5% [34]. Table 1 shows the effect of different packaging materials and control atmosphere (CA) technique on the shelf-life of okra at different storage temperatures and relative humidity ranges. For this study, LDPE was purchased through the local market having 30 µm thickness and permeability of 2150.4 mL/m 2 d atm for O 2 and 9120 mL/m 2 d atm for CO 2 at 20 • C (provided by the manufacturer). Okra pods (weight = 363 ± 15 g) were packed in each low-density polyethylene bag of 36 cm × 25.8 cm in size with 30 µm thickness. The samples were kept at RH 80-85% and storage temperature-ambient (27 ± 2 • C) and cold storage (7 ± 1 • C)-for eight and 20 days, respectively. The CO 2 and O 2 concentrations through each LDPE bag were measured at the end of the storage period with the help of a headspace gas analyzer (Model 902 D, Quantek Instruments, Grafton, MA 01519, United States of America). After eight days of storage at ambient temperature, O 2 and CO 2 concentration was 3.85 ± 0.3% and 12.40 ± 0.4%, respectively, and at the end of 20 days of cold storage O 2 and CO 2 was 3.27 ± 0.2% and 8.71 ± 0.3%, respectively. It was nearly in the acceptable range, which explains why the actual experiment was conducted using LDPE. Polypropylene O 2 (6.3-8.4%) CO 2 (10.7-11.8%) 15 • C 75% 9 days [12] Control Atmosphere 5% O 2 + 10% CO 2 11 ± 1 • C 90-93% 12 days [37] 4-10% CO 2 7-12 • C 90-95% [38] Sustainability 2020, 12, 7547 4 of 19 Therefore, for the main experiment, 40 okra pods of the weight 363 ± 15 g were packed in each LDPE bag (size = 36 cm × 25.8 cm with 30 µm thickness). A paper towel of size 46 cm × 10.2 cm was also placed inside each LDPE bag to absorb the condensed water released by the pods.

Fruit Quality Parameters
Fruit quality i.e., weight loss, moisture content, firmness, mucilage viscosity, skin color, ascorbic acid content, chilling injury, respiration rate, and ethylene production for treated and untreated okra pods, were analyzed with three replicates per treatment at every 4th day. The weight loss of pods was analyzed by using a digital weight balance (Sartorius GM 1501). Weight loss was expressed as the percentage weight loss to the initial weight using Equation (1) [39]: Weight loss (%) = Initial weight (g) − Weight on n th day (g) Moisture content (%) of the okra pods was measured with a moisture analyzer (KERN dlb 160-3a). The firmness of pods was recorded with a penetrometer (PCE-FM 200). A 2 mm diameter steel plunger/probe was used to conduct the test. Firmness was measured in unit kg. Mucilage viscosity was determined by the blending of whole okra pods (100 g) with double-distilled water (200 mL) for 5 min. The blended material was centrifuged (HERMLE Z 300) at 6000 rpm for 50 min. After centrifuge, mucilage was separated from the rest of the supernatant with the help of a pipette. Then the viscosity of the mucilage was measured by using HAAKE Viscotester 2 plus using Rotor No. 3 at 27 • C [37].
where coefficient x can be given as: where L i , a i , b i are the initial color measurements and L f , a f , b f are the color measurements of okra samples on the n th day. The ascorbic acid content of the okra specimen was determined by titrating fruit extract with 2,6-dichlorophenol indophenols dye. The fruit sample was grounded with a 3% metaphosphoric acid solution and made up to a 2 g volume of 100 mL. The fruit extract was titrated against 2,6-dicholorophenol indophenol dye after filtration and finally, ascorbic acid content was calculated in mg/100 g [41]. Chilling injury was measured as the extent of pitting spots with a brownish discoloration of the pods. Chilling injuries on the fruit skin of 40 samples were visually observed, estimated, and categorized into a linear scale ranging: 0 denoting absence of any chilling injury symptom; 1 denotes 1-25% brown pitting spots; 2 denotes 26-50% brown pitting spots; 3 denotes 51-75% brown pitting spots; 4 denotes 76-100% brown pitting spots on the skin of the individual fruit [24]. The chilling injury index was measured by using Equation (5) The antioxidant capacity was assessed in percent DPPH (2,2-Diphenyl-1-Picrylhydrazyl) scavenging activity (%). Plant extraction was carried out by homogenizing 0.5 g of dried powdered okra (drying conditions: pods were dried at 55°C in a tunnel dehydrator) with 5 mL of extraction mixture (90% Methanol: 8% Acetone: 2% HCl). The homogenate was centrifuged at 3000 RPM for 1 h at 4 • C. The plant extract 0.5 mL was added to 3 mL of a methanol solution of DPPH (0.03%). The mixture was incubated in darkness for 30 min at ambient temperature. The changes in color (violet-yellow) of the mixture were read as absorbance at 517 nm using a UV-VIS spectrophotometer. Antioxidant capacity was calculated using Equation (6): where A 0 is the absorbance of DPPH in methanol, A 1 is the absorbance of DPPH with the sample extract solution [42]. Respiration rate was measured by incubating 40 fruits in a 5 L air-tight desiccator for 1 h at 25 • C. CO 2 and C 2 H 4 concentrations were recorded with a headspace CO 2 analyzer (Model 902 D, Quantek Instruments, USA) CO 2 m (model 8560) and ethylene analyzer Drager Pac III. The ethylene production was measured in mgC 2 H 4 kg −1 h −1 and respiration rate was exhibited as mg CO 2 kg −1 h −1 , using Equation (7)

Statistical Analysis
The physicochemical parameter data obtained from this experimental study was analyzed using a two-way factorial design in Minitab. Storage days and treatment methodologies were the two factors considered for the analyses. A comparison of means was performed using the Tukey test at a significance level of p ≤ 0.05. Results obtained from statistical analyses are presented as means ± standard deviations. Pearson correlation was also applied to data to interpret the relations among the parameters due to the effect of 1-MCP and MAP treatment with the storage time and temperature.

Results & Discussion
Weight loss is one of the main issues that occurs during okra storage, which influences its marketability. A highly significant (p ≤ 0.05) effect of 1-MCP and MAP treatment with respect to storage temperature and time was observed on weight loss of okra. 1-MCP and MAP reduced the weight loss, but the difference was found among the specimens stored at different temperatures. However, MAP with or without 1-MCP was more significant in reducing weight loss in samples stored at both ambient and cold storage conditions than the 1-MCP alone. Figure 1a shows, control okra stored at ambient temperature had lost 15.21 ± 0.7% of its weight in just four days, although this value was significantly decreased in MAP (6.07 ± 0.1%), especially for okra treated with both 1-MCP and MAP (5.28 ± 0.2%). The behavior of okra at ambient temperature showed that MAP and 1-MCP can decrease the weight reduction in pods up to four days at ambient temperature. Similarly, the avocado sample treated with the 1-MCP (i.e., 0.45 µL L −1 ) stored at 20 • C reduced the weight loss from the avocado sample during the first few days of storage [20].  Figure 1b shows that lowering the storage temperature reduces the weight reduction and 1-MCP + MAP was most effective (6.13 ± 0.22%) in weight retention. The same was observed during okra storage at ambient (24 ± 2 °C) and cold temperature (5 ± 1 °C) [39]. Moreover, 1-MCP acts as an ethylene inhibitor, thus it reduces the changes linked with the ripening process, and in return, fruits remain fresh for a longer time period [20,44]. However, modified atmosphere packaging reduces weight loss due to the restrained water vapor diffusion through the plastic films that increase vapor pressure inside packages [32,36]. The efficiency of both 1-MCP and MAP on weight loss reduction is associated with controlled biochemical activities like transpiration and respiration [45].
Moisture content in okra after harvest was recorded at 88.7 ± 0.36%, which was significantly reduced in control samples at the end of storage. The diminution was greater in samples kept at ambient temperature than the cold stored okra. However, after eight days at ambient temperature, MAP and 1-MCP + MAP treated okra showed nearly identical moisture loss pattern, which was 71.21 The values indicate mean (±) standard deviation. According to the Tukey test, the bars with different letters represent the significance level with each other at p ≤ 0.05. Figure 1b shows that lowering the storage temperature reduces the weight reduction and 1-MCP + MAP was most effective (6.13 ± 0.22%) in weight retention. The same was observed during okra storage at ambient (24 ± 2 • C) and cold temperature (5 ± 1 • C) [39]. Moreover, 1-MCP acts as an ethylene inhibitor, thus it reduces the changes linked with the ripening process, and in return, fruits remain fresh for a longer time period [20,44]. However, modified atmosphere packaging reduces weight loss due to the restrained water vapor diffusion through the plastic films that increase vapor pressure inside packages [32,36]. The efficiency of both 1-MCP and MAP on weight loss reduction is associated with controlled biochemical activities like transpiration and respiration [45].
Moisture content in okra after harvest was recorded at 88.7 ± 0.36%, which was significantly reduced in control samples at the end of storage. The diminution was greater in samples kept at ambient temperature than the cold stored okra. However, after eight days at ambient temperature, MAP and 1-MCP + MAP treated okra showed nearly identical moisture loss pattern, which was 71.21 ± 0.9%, and 72.8 ± 2.2%, respectively at the end of storage, see Figure 2a. Whereas, at cold storage, the minimum moisture loss (82.2 ± 1.1%) was observed in 1-MCP + MAP treated okra followed by Sustainability 2020, 12, 7547 7 of 19 MAP (80.1 ± 0.9%) and 1-MCP (76.9 ± 1.2%) after 20 days, shown in Figure 2b. These results show that the 1-MCP with MAP keeps the fruit fresh by maintaining its water content for a longer time period [45]. Although, temperature is the main factor contributing to moisture loss, lowering the temperature of storage led to better moisture retention [39]. Okra stored at high temperature induces weight loss due to excessive moisture loss [46,47].
Sustainability 2020, 12, x FOR PEER REVIEW 7 of 21 ± 0.9%, and 72.8 ± 2.2%, respectively at the end of storage, see Figure 2a. Whereas, at cold storage, the minimum moisture loss (82.2 ± 1.1%) was observed in 1-MCP + MAP treated okra followed by MAP (80.1 ± 0.9%) and 1-MCP (76.9 ± 1.2%) after 20 days, shown in Figure 2b. These results show that the 1-MCP with MAP keeps the fruit fresh by maintaining its water content for a longer time period [45]. Although, temperature is the main factor contributing to moisture loss, lowering the temperature of storage led to better moisture retention [39]. Okra stored at high temperature induces weight loss due to excessive moisture loss [46,47]. Firmness is another freshness indicator that determines the quality of okra as loss in firmness is assessed as a sign of senescence. According to the results presented in Figure 3a,b, okra firmness was retained significantly (p ≤ 0.05) when treated with the 1-MCP and/or MAP, however, it was more obvious in the samples treated with 1-MCP + MAP. The firmness of the okra treated with 1-MCP + MAP was 0.69 ± 0.04 kg at ambient temperature, which decreased to 0.47 ± 0.01 kg at ambient temperature during eight days of storage. Similarly, fruit firmness retention with the application of 1-MCP has also been reported in plum, avocado, and eggplant [20,27,39,44]. The reduction in fruit firmness with the 1-MCP application was due to the decline in ethylene production and the fruit Firmness is another freshness indicator that determines the quality of okra as loss in firmness is assessed as a sign of senescence. According to the results presented in Figure 3a,b, okra firmness was retained significantly (p ≤ 0.05) when treated with the 1-MCP and/or MAP, however, it was more obvious in the samples treated with 1-MCP + MAP. The firmness of the okra treated with 1-MCP + MAP was 0.69 ± 0.04 kg at ambient temperature, which decreased to 0.47 ± 0.01 kg at ambient temperature during eight days of storage. Similarly, fruit firmness retention with the application of 1-MCP has also been reported in plum, avocado, and eggplant [20,27,39,44]. The reduction in fruit firmness with the 1-MCP application was due to the decline in ethylene production and the fruit softening enzymatic activities [20,44,45]. Additionally, okra firmness was retained by reducing storage temperature and the application of 1-MCP treatment [23]. Both 1-MCP and MAP inhibited the softening of pear and plum fruit during cold storage. During fruit softening, the fruit passes through different compositional changes that reduce its ascorbic acid content [48]. According to Table 2, the treatment effect with storage time and temperature showed a highly positive correlation between fruit firmness and mucilage viscosity (R = 0.99). softening enzymatic activities [20,44,45]. Additionally, okra firmness was retained by reducing storage temperature and the application of 1-MCP treatment [23]. Both 1-MCP and MAP inhibited the softening of pear and plum fruit during cold storage. During fruit softening, the fruit passes through different compositional changes that reduce its ascorbic acid content [48]. According to Table  2, the treatment effect with storage time and temperature showed a highly positive correlation between fruit firmness and mucilage viscosity (R = 0.99).     Mucilage viscosity is an important quality attribute that accounts for consumer appeal [49]. Mainly, consumers show strong intent to purchase highly viscous pods because of their use as a thickener for stews and soups [50]. Okra mucilage is usually present in the pod walls and is a water-soluble polysaccharide formed by large molecules of sugars that are associated with minerals and proteins [8]. Figure 4a,b shows okra specimens at cold storage showed a less severe decline in comparison with the ambient stored pods and this decline increases with the increase in storage period. This reduction in viscosity is due to the metabolic activities that breakdown polysaccharide chains during the storage period. Fresh produce respire during storage which results in the production of carbon dioxide and water and, as mucilage is soluble in water, thereby, its viscosity decreases during this biological process [51]. Although, low-temperature storage slows down the metabolic processes of the okra causing less reduction in viscosity. The highest mucilage viscosity was observed for 1-MCP + MAP and that is mainly due to the controlled metabolic activities, see Figure 4a,b.
The ascorbic acid is a nutritional and quality index for okra [47]. It is a water-soluble antioxidant that usually decreases with the increase in light intensity, storage temperature, and storage period [25]. Table 3 shows the level of ascorbic acid in okra decreased with the increase in storage temperature and storage period. The initial ascorbic acid content of okra after harvest was 21.6 ± 0.42 mg/100 g that declined over storage time nonetheless, but the diminution was progressively higher in okra stored at ambient temperature especially in untreated (control) pods. Whereas the MAP retained more ascorbic acid than the 1-MCP alone treated samples at both storage temperatures. In a similar way, the concentration of ascorbic acid in okra and broccoli fruits was more retained by MAP at cold storage temperatures [12,32]. In the present study, the results indicated that the 1-MCP combined with MAP was the most effective treatment to maintain an acceptable level of ascorbic acid content throughout the storage period, however, this retention was more obvious in cold-stored samples (Table 3). After 20 days of low-temperature storage, ascorbic acid contents of 1-MCP + MAP was significantly higher (i.e., 18.2 ± 0.42 mg/100 g) as compared with the fruit stored in MAP (i.e., 16.9 ± 0.30 mg/100 g) and 1-MCP without MAP (i.e., 15.3 ± 0.30 mg/100 g). Similarly, in pear during 210 days of cold storage, 1-MCP and MAP were effective to retain the ascorbic acid content [31]. The ascorbic acid is a nutritional and quality index for okra [47]. It is a water-soluble antioxidant that usually decreases with the increase in light intensity, storage temperature, and storage period [25]. Table 3 shows the level of ascorbic acid in okra decreased with the increase in storage temperature and storage period. The initial ascorbic acid content of okra after harvest was 21.6 ± 0.42 mg/100 g that declined over storage time nonetheless, but the diminution was progressively higher in okra stored at ambient temperature especially in untreated (control) pods. Whereas the MAP retained more ascorbic acid than the 1-MCP alone treated samples at both storage temperatures. In a similar way, the concentration of ascorbic acid in okra and broccoli fruits was more retained by MAP at cold storage temperatures [12,32]. In the present study, the results indicated that the 1-MCP combined with MAP was the most effective treatment to maintain an acceptable level of ascorbic acid content throughout the storage period, however, this retention was more obvious in cold-stored samples (Table 3)  Retention of bright green color is a primary indicator for quality evaluation of okra in the market [12]. During storage, darkening, or browning of okra pods ridges is a major problem affecting its appearance [39]. The color of okra was assessed in hue angle (h • ), the total color change (∆E), and browning index (BI) that was calculated by individually measuring color parameters L, a, and b. According to Table 3, hue angle was rapidly declined in okra specimens stored at ambient temperature, but this decline was less intensive in MAP (i.e., 112.33 • ± 0.42) and 1-MCP + MAP (i.e., 113.91 • ± 0.52) than the 1-MCP without MAP (i.e., 109.91 • ± 0.65). Conversely, a comparatively slight decline in hue angle was observed in 1-MCP with MAP at cold storage, with final values of 115.96 • ± 0.49.
On the other hand, a drastic change in total color (∆E) was observed for the okra specimen kept at ambient conditions than the cold stored samples. Less intensive total color change was noticed in 1-MCP with MAP during okra specimen storage at 7 • C. Table 3 shows, the highest value of the browning index was observed in control samples (untreated) at both storage temperatures. During ambient temperature storage, the browning index increased by 270.7% in control pods, compared to an increase by 126-130% in MAP and 1-MCP + MAP treated pods. Likewise, during 20 days of cold storage, the browning index of MAP and 1-MCP + MAP treated samples increased by 32-44% compared to 125.5% in the control. This less intensive change in color of okra specimen treated with 1-MCP + MAP was may be due to the suppressed ethylene production and controlled respiration rate. Similarly, Chinese pear fruit treated with 1-MCP suppressed ethylene production that reduced the drastic change in bright green color up to some extent of the storage period [52]. Moreover, the rate of chlorophyll degradation in okra was diminished by decreasing the storage temperature and by covering the fruit with PVC film [1]. The bright green color of okra was well retained by 1-MCP during storage at 7 • C [24]. Table 3 shows that the 1-MCP and/or MAP effect with respect to storage temperature and days has a positive correlation between Hue angle and respiration rate (R = 0.94) and browning index and ethylene production (R = 0.91). This relationship between color change and ethylene production has also been reported in the literature for Chinese pear fruits [52].
Okra pods are very sensitive to low-temperature storage. Storage of fruits (or agricultural products) below room temperature for a long period of time after harvesting, results in chilling injury disorder (browning and pitting) on the fruit surface [53]. As shown in Figure 5, chilling injury symptoms were observed in samples kept at 7 • C for 20 days. The pictorial representation of the chilling injury in the okra pod samples indicates that control samples showed the highest level of chilling injury after 20 days of storage at 7 • C. As shown in Figure 5, the okra pod samples treated with 1-MCP exhibited a delay in developing chilling injury until the 8th day of the storage period at 7 °C, while 1-MCP + MAP retarded chilling injury symptoms up to the 12th day of the storage period. At the end of storage (i.e., 20 days), chilling injury indices were 2.7 ± 0.17, 2.1 ± 0.20, 1.7 ± 0.17, and 1.4 ± 0.15 in control, 1-MCP, MAP, and 1-MCP + MAP, respectively. The development of chilling injury in fruits is related to a decrease in membrane integrity which occurs due to stress and senescence [24]. As senescence increases with the increase in ethylene production [19], therefore, reducing ethylene production is an effective way to control chilling injury. Moreover, as MAP decreases the ethylene in the atmosphere around the fruit and 1-MCP binds the ethylene receptors [19], therefore, both MAP and 1-MCP can limit the chilling injury stress in fruits. The 1-MCP significantly alleviated the chilling injury in cold-stored citrus and grapefruit [54]. The development of chilling stress in banana was significantly delayed by the presence of modified atmosphere packaging [55]. Similarly, MAP+1-MCP both delayed effectively the chilling injury stress and retained the nutritional quality of peppers and sweet peppers [25,56]. Table 4 shows the effect of different postharvest techniques alleviating chilling injury.  As shown in Figure 5, the okra pod samples treated with 1-MCP exhibited a delay in developing chilling injury until the 8th day of the storage period at 7 • C, while 1-MCP + MAP retarded chilling injury symptoms up to the 12th day of the storage period. At the end of storage (i.e., 20 days), chilling injury indices were 2.7 ± 0.17, 2.1 ± 0.20, 1.7 ± 0.17, and 1.4 ± 0.15 in control, 1-MCP, MAP, and 1-MCP + MAP, respectively. The development of chilling injury in fruits is related to a decrease in membrane integrity which occurs due to stress and senescence [24]. As senescence increases with the increase in ethylene production [19], therefore, reducing ethylene production is an effective way to control chilling injury. Moreover, as MAP decreases the ethylene in the atmosphere around the fruit and 1-MCP binds the ethylene receptors [19], therefore, both MAP and 1-MCP can limit the chilling injury stress in fruits. The 1-MCP significantly alleviated the chilling injury in cold-stored citrus and grapefruit [54]. The development of chilling stress in banana was significantly delayed by the presence of modified atmosphere packaging [55]. Similarly, MAP+1-MCP both delayed effectively the chilling injury stress and retained the nutritional quality of peppers and sweet peppers [25,56]. Table 4 shows the effect of different postharvest techniques alleviating chilling injury. Alleviated chilling injury stress with lower membrane permeability and lipid peroxidation [24] Hot water dipping 5 • C 90 ± 2% Reduced chilling injury disorder and oxidative stress [13] The DPPH radical scavenging activity was calculated after harvest (i.e., 0 days of storage) and at the end of the storage period of both the ambient (i.e., eight days) and cold (i.e., 20 days) stored samples. The DPPH scavenging activity of okra pods at 0-day investigations was 62.4 ± 0.18%. This activity was diminished to 41.3 ± 0.61% and 49.5 ± 0.30% in control samples at ambient and cold storages, respectively. A similar effect was observed for pear fruit, the antioxidant activity was decreased with the increase in storage period [57]. This decrease was less intensive in treated pods than the untreated okra. It has been reported that the decrease in antioxidant activity values was probably due to the degradation of ascorbic acid and phenolic compounds during biosynthesis [58,59]. Figure 6 shows that the 1-MCP + MAP at low-temperature storage maintained well the antioxidant capacity (i.e., 60.7 ± 0.49%). This may be due to the more retention in ascorbic acid comparative to other treated and untreated samples. Figure 7 shows the standard calibration curve for ascorbic acid that was used for the DPPH scavenging activity. 1-MCP 7 °C 80-85% Alleviated chilling injury stress with lower membrane permeability and lipid peroxidation [24] Hot water dipping 5 °C 90 ± 2% Reduced chilling injury disorder and oxidative stress [13] The DPPH radical scavenging activity was calculated after harvest (i.e., 0 days of storage) and at the end of the storage period of both the ambient (i.e., eight days) and cold (i.e., 20 days) stored samples. The DPPH scavenging activity of okra pods at 0-day investigations was 62.4 ± 0.18%. This activity was diminished to 41.3 ± 0.61% and 49.5 ± 0.30% in control samples at ambient and cold storages, respectively. A similar effect was observed for pear fruit, the antioxidant activity was decreased with the increase in storage period [57]. This decrease was less intensive in treated pods than the untreated okra. It has been reported that the decrease in antioxidant activity values was probably due to the degradation of ascorbic acid and phenolic compounds during biosynthesis [58,59]. Figure 6 shows that the 1-MCP + MAP at low-temperature storage maintained well the antioxidant capacity (i.e., 60.7 ± 0.49%). This may be due to the more retention in ascorbic acid comparative to other treated and untreated samples. Figure 7 shows the standard calibration curve for ascorbic acid that was used for the DPPH scavenging activity.  Okra is a vegetable with a high respiration rate that is a major cause limiting its shelf-life [17]. As shown in Figure 8a, 1-MCP and MAP treatment suppressed ethylene production for four days at ambient and eight days at cold storage conditions, and afterward, ethylene production attained peak as shown in Figure 8a,b Similarly, in avocado fruit treated with 1-MCP at 0.45 l L −1 for 12 or 24 h and stored at 20 °C, ethylene production was delayed for six and 10 days, respectively [40]. On the other hand, ethylene production of control okra (kept at ambient temperature) increased continuously after harvest and reached a peak value of 1.12 ± 0.05 mg kg −1 h −1 at the end of eight days of storage. However, control samples stored at 7 °C showed a decrease in ethylene production in the initial days of storage and then gained a peak of 0.88 ± 0.03 mg kg −1 h −1 towards the end of the storage period (i.e., 20 days).  Okra is a vegetable with a high respiration rate that is a major cause limiting its shelf-life [17]. As shown in Figure 8a, 1-MCP and MAP treatment suppressed ethylene production for four days at ambient and eight days at cold storage conditions, and afterward, ethylene production attained peak as shown in Figure 8a,b Similarly, in avocado fruit treated with 1-MCP at 0.45 l L −1 for 12 or 24 h and stored at 20 • C, ethylene production was delayed for six and 10 days, respectively [40]. On the other hand, ethylene production of control okra (kept at ambient temperature) increased continuously after harvest and reached a peak value of 1.12 ± 0.05 mg kg −1 h −1 at the end of eight days of storage. However, control samples stored at 7 • C showed a decrease in ethylene production in the initial days of storage and then gained a peak of 0.88 ± 0.03 mg kg −1 h −1 towards the end of the storage period (i.e., 20 days). The present study shows a similar trend for the respiration rate as was observed for ethylene production. According to Table 2, a positive, as well as highly significant correlation, was observed between ethylene and respiration rate (i.e., R = 0.98). As shown in Figure 9a,b, respiration rate (mg CO2 kg −1 h −1 ) in okra treated with 1-MCP and MAP alone increased after four (ambient storage) and eight days (cold storage) and attained their peaks at the end of storage. However, okra treated with 1-MCP + MAP peaked on the 16th day of cold storage. Overall, 1-MCP + MAP decreased the rate of respiration and ethylene production most strongly, especially after 20 days of cold storage.
The rate of respiration and ethylene production increases with the increase in temperature [60]  The present study shows a similar trend for the respiration rate as was observed for ethylene production. According to Table 2, a positive, as well as highly significant correlation, was observed between ethylene and respiration rate (i.e., R = 0.98). As shown in Figure 9a,b, respiration rate (mg CO 2 kg −1 h −1 ) in okra treated with 1-MCP and MAP alone increased after four (ambient storage) and eight days (cold storage) and attained their peaks at the end of storage. However, okra treated with 1-MCP + MAP peaked on the 16th day of cold storage. Overall, 1-MCP + MAP decreased the rate of respiration and ethylene production most strongly, especially after 20 days of cold storage.
Sustainability 2020, 12, x FOR PEER REVIEW 17 of 21 ethylene production rates by reducing the activity of ethylene biosynthesis enzymes compared with the fruits stored at the normal atmosphere [31,45].

Conclusions
This study aimed to investigate the effects of 1-methylcyclopropene (1-MCP) and modified atmosphere packaging (MAP) on postharvest storage life of okra at two storage conditions; ambient (i.e., 27 ± 2 °C) and low temperature (i.e., 7 ± 1 °C). Results revealed that control (untreated) okra lost its quality within four days because of high moisture and weight loss, while 1-MCP and MAP retained the quality promisingly up to four days at ambient temperature. At low-temperature storage, 1-MCP combined with MAP kept okra quality maintained by controlling its respiration rate and water and weight loss during the storage period (i.e., 20 days). However, control (untreated) okra at low-temperature storage condition lost its quality after eight days due to severe water loss and the The rate of respiration and ethylene production increases with the increase in temperature [60] and 1-MCP inhibit this increase by binding ethylene receptors that reduce the activity of ripening enzymes [61]. This shows that the storage temperature had a significant effect on the longevity of ripening inhibition after 1-MCP treatment. At high-temperature storage, pear treated with 1-MCP recovered its ripening ability more quickly than the low-temperature storage specimens [62]. Similarly, cold-stored pear and plum treated with 1-MCP and MAP inhibited respiration and ethylene production