Investigation of Bruise Damage and Storage on Cucumber Quality

: Bruise damage is one of the mechanical injuries that fresh produce can sustain during the postharvest supply chain. The study investigated the effect of drop impact levels, storage temperatures, and the storage period on the quality changes of cucumbers. A known mass ball was used to damage cucumbers once from three different drop heights (30, 60, and 90 cm) before they were stored for 24 days at 5 ◦ C, 10 ◦ C, and 22 ◦ C. The data showed that the bruise area ( BA ), bruise susceptibility ( BS ), yellowness, and chroma * increased with the increase in the drop height and storage temperature. The study found that the bruise area ( BA ) and bruise susceptibility ( BS ) of the damaged cucumbers increased substantially ( p < 0.05) with the increase in storage temperature and drop height. Due to the increment in drop height, storage temperature, and the storage period, the weight loss (Wl)% signiﬁcantly increased after 24 days of storage. The storage period affects the ﬁrmness of damaged cucumbers stored in all storage conditions. The highest value of lightness ( L *) was observed for the cucumbers bruised from the 60 cm drop height and stored at 22 ◦ C with a value of 43.08 on day 24 of storage. Hue *, redness ( a *), and total soluble solids ( TSS ) were all unaffected by the drop height. This study can serve as a resource for horticultural researchers and experts involved in the fresh fruit and vegetable supply chain. The study pays attention to the importance of postharvest supply chain activities, such as handling and storage to maintain the quality and prolong the shelf life of perishable produce, such as cucumbers.


Introduction
The cucumber (Cucumis sativus L.) is a popular vegetable that is produced in high quantities. In 2021, the total harvested area and production of cucumbers reached more than 2 million hectares and more than 93 million tons, respectively [1]. Cucumbers are used in salads and to make pickles. The cucumber is a high water content vegetable that is high in potassium, calcium, vitamin A, and vitamin. Reference [2] stated that cucumbers are one of the most versatile vegetables, since they may be utilized topically and they help to control stress. Additionally, cucumbers assist in relaxation and aid in digestion, and they reinforce cells by keeping them hydrated so they can perform efficiently. Cucumbers are also known to aid in slowing age-related cellular degradation. Fresh cucumber has several health benefits and has antioxidant, anti-inflammatory, and anti-cancer properties. Furthermore, cucumbers contain many vitamins that are beneficial for diabetes patients, since they contain little sugar and help the body in burning excess fat.
According to Al-Dairi et al. [3], visual appearance plays an important role in consumer decisions (up to 83 %) which are extremely influenced by the presence of flaws and damage. Bruising is determined to be one of the most common obstacles to purchasing produce, more so than the price [4], and because bruising is widespread, it is recognized to be one of the leading causes of fresh produce deterioration and quality loss [5]. According to Celik [6], bruising is a subcutaneous mechanical injury without skin rupture that is induced by an impact, quasi-static compression, or vibration. It consists of the local deterioration of external tissue, intracellular water extravasation, and the browning (oxidation) of phenolic

Cucumber Sample Preparation
Fresh cucumbers were purchased from the market and directly transported to the Postharvest Technology Laboratory at Sultan Qaboos University. A total of 215 cucumbers with a uniform shape, color, and surface condition were selected. The mean weight of the fresh cucumbers was 117.69 ± 25.51 g.

Bruising Measurements and Storage
The drop impact technique described by Pathare and Al-Dairi [7] (Figure 1) was used to bruise/damage the cucumbers used in this experiment. This method comprises the free fall of a steel ball (66.81 g) through a PVC hollow pipe into each cucumber from a height of 30 cm, 60 cm, and 90 cm that represent the low, medium, and high drop impacts, respectively. Upon applying the impact damage, the bruised region on the cucumbers was marked to facilitate the bruise recognition for further measurements. The impact energy (Ei) resulting from the impact test was calculated using Equation (1), as described by Pathare and Al-Dairi [14].
where m b is the ball mass (66.81 g), g is the gravitational constant (9.81 m s −2 ), and h represents the drop height (cm). The impact energies produced from the three drop heights were 0.197 J (low), 0.39 J (medium), and 0.59 J (high).

bility (BS) (Equation 3
( )) [7]. The bruise diameter (w1 and w2) was used to calculate the bruise area of the cucumber. The cucumber samples were stored at 5 °C, 10 °C, and 22 °C (63 cucumbers per storage condition) for 24 days. Each storage condition contained three groups of cucumbers bruised from the different drop heights. To study the bruise development and quality changes in the cucumbers, measurements for weight loss %, color attributes (L*, a*, b*, hue*, and chroma*), firmness, and total soluble solids (TSS) were taken at intervals of 2,4,8,12,16,20, and 24 days. Visual and daily observations were recorded to measure the occurrence of quality changes and bruising in cucumbers. For the analysis on day 0, the weight, firmness, color, and total soluble solids (TSS) of the cucumber samples were analyzed prior to the impact test and storage.

Weight Loss % (Wl%)
An electric weight balance (model: GX-4000, Japan) with an accuracy of 0.01 g was used to weigh the cucumbers. The percentage of weight loss in the cucumbers was calculated using Equation (4).
The cucumber samples were stored at 5 • C, 10 • C, and 22 • C (63 cucumbers per storage condition) for 24 days. Each storage condition contained three groups of cucumbers bruised from the different drop heights. To study the bruise development and quality changes in the cucumbers, measurements for weight loss %, color attributes (L*, a*, b*, hue*, and chroma*), firmness, and total soluble solids (TSS) were taken at intervals of 2, 4, 8, 12, 16, 20, and 24 days. Visual and daily observations were recorded to measure the occurrence of quality changes and bruising in cucumbers. For the analysis on day 0, the weight, firmness, color, and total soluble solids (TSS) of the cucumber samples were analyzed prior to the impact test and storage.

Weight Loss % (Wl%)
An electric weight balance (model: GX-4000, Japan) with an accuracy of 0.01 g was used to weigh the cucumbers. The percentage of weight loss in the cucumbers was calculated using Equation (4

Color
The surface color of the cucumbers was measured using a colorimeter (model: NR110, Shenzhen ThreeNH Tech, Shenzhen, China) that was calibrated using a white plate. Color measurements were performed 6 times for each sample (162 readings per day) for 24 days of analysis to find the alternations in L* (lightness-darkness), a* (redness-greenness), b* (yellowness-blueness), chroma*, and hue* on the bruised cucumbers stored at 5 • C, 10 • C, and 22 • C. Furthermore, the total color difference (∆E*) was calculated using Equation (5), as described by Pathare et al. [16].

Firmness
The firmness test was conducted by penetrating the upper, middle, and lower regions of the cucumber by applying a hand penetrometer (model: FHP-803, LLC., Franklin, ME, USA) after 2,4,8,12,16,20, and 24 days and expressed in N.

Total Soluble Solids (TSS)
The TSS (Brix) of the cucumber was measured using a hand-held refractometer (model: PR-32 α, ATAGO Co., Ltd., Tokyo, Japan) and was calibrated at 20 • C. For each cucumber sample, three readings were taken (upper, middle, and lower regions). Each region was squeezed longitudinally to obtain a mixture of juice from all regions. From each group, 9 readings of TSS were taken (63 readings per day).

Statistical Analysis
To carry out all statistical analyses, SPSS 20.0 (International Business Machine Corp., New York, NY, USA) software was applied. The analysis of variance (ANOVA) was performed to assess the influence of three studied factors, including drop height, storage temperature, and storage duration on the bruise size measurements (bruise area (BA) and bruise susceptibility (BS)) as well as on the quality attributes (weight loss % (Wl%), color, firmness, and total soluble solids (TSS)) of the cucumbers at a 95% significance level. The values of all resulted data were shown as the mean ± standard deviation (SD). A Pearson correlation analysis was also conducted to study the correlation between the studied parameters.

Results and Discussions
3.1. Bruise Area (BA) and Bruise Susceptibility (BS) of Cucumbers Table 1 shows the results of the bruise area (BA) of cucumbers damaged from three different drop heights (30, 60, and 90 cm) after 24 days of storage at 5, 10, and 22 • C. In this study, the BA and BS of damaged cucumbers significantly increased (p < 0.05) with the increase in storage temperature and drop height. The study obtained no relationship between BA and BS with storage duration (p > 0.05). The highest drop height (90 cm, 0.590 J) and storage at 5 • C increased the BA average value of cucumbers from 109.47 mm 2 on day 2 to 151.88 mm 2 on day 8. Later, the BA increased on day 12 (204.88 mm 2 ) and then decreased to reach 161.64 mm 2 on day 24. The BA value was the highest for the 90 cm bruised cucumbers stored at 10 • C, where the BA showed an increment from 190.32 mm 2 to 209.57 mm 2 on days 2 and 24, respectively (Table 1). At 22 • C storage conditions, the BA was reduced by 13.14% from days 2 to 24 in the high impact (90 cm) bruised cucumbers.
The results showed that the BS was influenced by the drop height and storage temperature (p < 0.05), but not by the storage duration (p > 0.05) ( Figure 2). With storage days, an increasing trend in BS was observed as the drop height was reduced ( Figure 2). The  Generally, the study showed that reducing the storage temperature increased the BS of cucumbers to damage. Regarding impact damage, a drop height of 30 cm (low impact level) showed the greatest BA and BS than the drop heights of 60 cm and 90 cm at 5 and 10 °C. At 20 °C, the drop height of 60 cm revealed the greatest bruising size than for the other drop heights (30 and 90 cm). Thus, the BS values obtained for the study may not be an appropriate parameter to compare the sensitivity and incidence of cucumbers to im- Generally, the study showed that reducing the storage temperature increased the BS of cucumbers to damage. Regarding impact damage, a drop height of 30 cm (low impact level) showed the greatest BA and BS than the drop heights of 60 cm and 90 cm at 5 and 10 • C. At 20 • C, the drop height of 60 cm revealed the greatest bruising size than for the other drop heights (30 and 90 cm). Thus, the BS values obtained for the study may not be an appropriate parameter to compare the sensitivity and incidence of cucumbers to impact bruising. Similarly, Hussein et al. [17] reported that the BS was higher in the order of 20 cm > 40 cm > 60 drop heights for the first 2 months of storage at a cold temperature (5 • C) for pomegranate fruit. The overall increase in BA and BS of cucumbers with increasing storage duration is due to the reduction in turgor pressure in terms of cold storage. Fresh fruit and vegetables, such as cucumbers, contain a huge percentage of water that is responsible for the tissue turgidity of the produce, and this is reduced because of the continuous loss in the moisture content during storage at cold temperatures; therefore, increasing the produce sensitivity to bruise damage [17]. The reduction observed in BA on the last day of storage could be the result of the drying effect of the cucumber peel because of excessive moisture loss in fruit stored for more than 20 days, thus leading to the hardening of the fruit peel [18].
In contrast, Pathare et al. [19] revealed that the bruise area and susceptibility of pomegranate fruit were greatly influenced by the impact level, storage temperature, and storage duration, particularly at 22 • C. Furthermore, Cui et al. [20] revealed that as storage temperatures decreased, the incidence of tomato bruising decreased. In the study conducted by Tabatabaekoloor [21], he found that raising the drop height from 5 to 15 cm increased the BA by 15% due to an increase in potential energy, which enhances the contact intensity. Pathare and Al-Dairi [14] found a correlation between the drop height and the presence of BA in bananas, and the association between the bruise size/area and impact energy emphasizes the importance of the impact level or drop height (i.e., impact energy increases with height) in increasing pomegranate bruising.

Weight Loss (Wl%)
A statistical difference (p < 0.05) was found between Wl% for all studied factors, including drop height, storage temperature, and storage duration ( Figure 3). The weight loss % in cucumbers increased during the entire period of storage (24 days). Following 24 days of storage, the highest Wl% value of cucumbers stored at 5 • C was 34.21% impacted by the 30 cm height. However, the Wl% at 10 • C and 22 • C were 37.418% (30 cm drop height) and 30.53% (30 cm drop height), respectively ( Figure 3).
Hussein et al. [17] found that bruised fruit had a higher Wl% due to tissue injury and probable changes in the cell wall tissue permeability, resulting in a higher rate of transpiration during storage. Similarly, Al-Dairi and Pathare [22] recorded a significant decline in Wl% in tomato fruit stored at ambient temperature due to respiration and water dehydration processes after 12 days of storage, when compared to storage at a cold temperature. On day 16, cucumbers stored at 5 • C had white spots/ rots and tended to shrink more. The reduction in weight in shrunken cucumbers could be attributed to the reduction of water stress production surrounding each part of the cucumber, which reduces the rate of respiration [23]. Fresh cucumber weight loss is mostly due to water loss produced by transpiration and respiration processes [11]. Pathare et al. [24] showed that weight loss % was strongly impacted by the storage temperature, impact heights, and storage duration, particularly at ambient temperature.
The reduction in weight in shrunken cucumbers could be attributed to the reduction water stress production surrounding each part of the cucumber, which reduces the rate respiration [23]. Fresh cucumber weight loss is mostly due to water loss produced by tra spiration and respiration processes [11]. Pathare et al. [24] showed that weight loss % w strongly impacted by the storage temperature, impact heights, and storage duration, p ticularly at ambient temperature.

Color
In terms of storage days, all color values for all treated cucumbers followed a similar pattern. Alterations in the L* value (lightness) was significantly affected (p < 0.05) by storage temperature and storage duration, however, no significant (p > 0.05) relationship was observed between the L* value and drop height ( Figure 4). The highest L* value was recorded in 60 cm bruised cucumbers stored at 22 • C with a value of 43.08. However, the lowest value of L* was observed for the 90 cm drop height bruised cucumbers stored at 10 • C with a value of 24.81 after 24 days of storage. The values for the L* color parameter for cucumbers stored at 5 • C on day 24 were 27.61, 27.74, and 31.14 for 30 cm, 60 cm, and 90 cm drop height, respectively. Table 2 shows a decrease in the values of a* (redness) of bruised cucumbers during 24 days of storage at 5 • C, 10 • C, and 22 • C. The a* value significantly differed (p < 0.05) with storage duration, with no significant differences (p > 0.05) with respect to drop height and storage temperature. The average a* value on day 0 was −1.28. On the last day of storage, the highest reduction in a* value was observed on 90 cm bruised cucumbers (−6.56) stored at 5 • C. At this storage condition (5 • C), the a* values of 30 cm and 60 cm bruised cucumbers were −4.44 and −5.30, respectively, on the last day of storage. The smallest reduction in a* value was recorded in cucumbers damaged from the 60 cm drop height with a value of −3.80, followed by those impacted by the 90 cm drop height (−3.90) and stored at 22 • C. At 10 • C storage temperature conditions, the a* values were −6.84 on day 20 and −0.94 on day 24. cm bruised cucumbers was 102.92, 134.28, and 113.61 on days 0, 4, and 24, respectively. Additionally, the chroma* value was significantly affected (p < 0.05) by the storage duration and drop height with no relationship with (p > 0.05) storage temperature ( Table 2). The results show that there was an increase in chroma* values between the first day and the last day (day 24) of storage. The highest value (29.95) was on day 24 for cucumbers stored at 22 °C and impacted by the 60 cm height. However, the lowest value was recorded (2.17) on day 0 for the 60 cm bruised cucumbers stored at 10 °C.  With storage duration, an increasing trend in the color attribute of b* was observed. The b* (yellowness) was statistically influenced (p < 0.05) by the storage duration and impact level (drop height). However, the effect of the storage temperature on the b* value of bruised cucumbers was not significant (p > 0.05). The b* value was increased gradually at all three temperatures during storage ( Figure 5). The results showed that the medium impacted (60 cm, 0.393 J) bruised cucumbers provided the highest value of b* (29.60) stored at 22 • C. This was followed by bruised cucumbers subjected to a low impact (30 cm, 0.197 J) with a value of 20.65 at 22 • C. However, the smallest b* value was 9.75 for cucumbers stored at 10 • C and impacted by a 90 cm drop height.
Regarding the hue* value (color purity), there was a significant (p < 0.05) influence of both storage duration and temperature on the color parameter, while the effect of the drop height was not significant (p > value) ( Table 2). This study reported that the hue* value increased slowly at 5 • C, 10 • C, and 22 • C storage temperature on day 2 and then decreased rapidly on day 8. However, at the low-temperature condition (5 • C), the hue* value of 60 cm bruised cucumbers was 102.92, 134.28, and 113.61 on days 0, 4, and 24, respectively. Additionally, the chroma* value was significantly affected (p < 0.05) by the storage duration and drop height with no relationship with (p > 0.05) storage temperature ( Table 2). The results show that there was an increase in chroma* values between the first day and the last day (day 24) of storage. The highest value (29.95) was on day 24 for cucumbers stored at 22 • C and impacted by the 60 cm height. However, the lowest value was recorded (2.17) on day 0 for the 60 cm bruised cucumbers stored at 10 • C. at room temperature showed a high variation in total color differences, particularly at an ambient temperature. The changes observed in this study are attributed to the conversion of the cucumber surface from a green to a more yellowish color. According to Bodner and Scampicchio [27],bruising is one of the factors that causes fruit discoloration. The observed changes in color characteristics could be attributed to the rapid chlorophyll breakdown during the storage of bruise-damaged cucumbers [24].

Firmness
The firmness of damaged cucumbers was statistically affected (p < 0.05) by the storage duration. Storage temperatures and drop heights showed no significant effect on the firmness of bruise-damaged cucumbers (p > 0.05). In this study, as the drop height increased, the firmness of cucumbers tended to decrease. The initial firmness value of the  (Table 2), while the lowest value (0.24) was recorded in cucumbers impacted by a drop height of 30 cm and stored at 22 • C ( Table 2). The results show that the total color change during the experimental period increased until day 20. Korese et al. [25] observed similar findings where the color properties and ∆E* were affected by the storage period and were higher in week 12 than in week 1. Pathare and Al-Dairi [7] found that the total color change of bruised tomatoes was highly influenced by the storage temperature, storage duration, and impact level (drop height). Furthermore, Al-Dairi et al. [26] recorded that tomatoes stored at room temperature showed a high variation in total color differences, particularly at an ambient temperature. The changes observed in this study are attributed to the conversion of the cucumber surface from a green to a more yellowish color. According to Bodner and Scampicchio [27],bruising is one of the factors that causes fruit discoloration. The observed changes in color characteristics could be attributed to the rapid chlorophyll breakdown during the storage of bruise-damaged cucumbers [24].

Firmness
The firmness of damaged cucumbers was statistically affected (p < 0.05) by the storage duration. Storage temperatures and drop heights showed no significant effect on the firmness of bruise-damaged cucumbers (p > 0.05). In this study, as the drop height increased, the firmness of cucumbers tended to decrease. The initial firmness value of the cucumber was 92.77 N. The smallest firmness value for medium impact (60 cm) bruised cucumbers stored at 10 • C was 26.87 N after 24 days of storage. As presented in Figure 6, the firmness value of the cucumbers showed a fluctuating trend until day 8 of storage. The firmness values decreased rapidly until day 12 of storage. Further results showed that the quality of cucumbers can be maintained up to day 8.
The firmness values decreased rapidly until day 12 of storage. Further results showed that the quality of cucumbers can be maintained up to day 8.
According to Azadbakht et al. [28], the firmness of the pear was reduced as the bruise and impact levels increased over the storage duration. Furthermore, Li et al. [29] confirmed that bruising was one of the main factors that contributed to the reduction in firmness due to increased polygalacturonase activity on fresh produce. The main cause of loss of firmness in fruits and vegetables is pectin depolymerization. The loss of integrity in the cell walls of cucumbers, as well as an increase in evaporation, transpiration, and metabolic activity of fruits stored in room settings, may lead to a drop in fresh produce firmness with an increased storage duration [11]. Furthermore, Al-Dairi et al. [30] discovered that the firmness values of damaged banana fruits were affected by storage temperature and duration, with the maximum value reported at 22 °C.  According to Azadbakht et al. [28], the firmness of the pear was reduced as the bruise and impact levels increased over the storage duration. Furthermore, Li et al. [29] confirmed that bruising was one of the main factors that contributed to the reduction in firmness due to increased polygalacturonase activity on fresh produce. The main cause of loss of firmness in fruits and vegetables is pectin depolymerization. The loss of integrity in the cell walls of cucumbers, as well as an increase in evaporation, transpiration, and metabolic activity of fruits stored in room settings, may lead to a drop in fresh produce firmness with an increased storage duration [11]. Furthermore, Al-Dairi et al. [30] discovered that the firmness values of damaged banana fruits were affected by storage temperature and duration, with the maximum value reported at 22 • C.

Total Soluble Solids (TSS)
The study found no statistical difference (p > 0.05) between TSS and the studied factors (drop height, storage temperature, and storage duration). The TSS value ranged between 2.84 and 4.23 • Brix for cucumbers stored at 5 • C, whereas the TSS values of cucumbers stored at 10 • C and 22 • C ranged between 2.97 and 3.82 • Brix and 3.00 and 3.66 • Brix, respectively (Figure 7). The highest content of TSS was recorded on the last day of storage on 90 cm bruised cucumbers at 5 • C with a value of 4.23 • Brix. The cucumber stored at 5 • C (90 cm drop height) on day 4 had the lowest TSS value (2.84 • Brix). The results of the study agreed with the findings obtained by Montero et al. [31], where the TSS content of grapefruits was significantly reduced by impact bruising. However, Maia et al. [32] found that high bruising incidence increased the TSS content of banana fruit. According to Pathare and Al-Dairi [7], storage temperature and storage duration had a high influence on the TSS value of pear fruit. In their study, they found that storage at 22 • C recorded the highest TSS levels in pears. In another study by Pathare et al. [19], they revealed that storage at 5 • C showed the smallest reduction in TSS.

Total Soluble Solids (TSS)
The study found no statistical difference (p > 0.05) between TSS and the studied tors (drop height, storage temperature, and storage duration). The TSS value ranged tween 2.84 and 4.23 °Brix for cucumbers stored at 5 °C, whereas the TSS values of cuc bers stored at 10 °C and 22 °C ranged between 2.97 and 3.82 °Brix and 3.00 and 3.66 ° respectively (Figure 7). The highest content of TSS was recorded on the last day of sto on 90 cm bruised cucumbers at 5 °C with a value of 4.23 °Brix. The cucumber stored °C (90 cm drop height) on day 4 had the lowest TSS value (2.84 °Brix). The results o study agreed with the findings obtained by Montero et al. [31], where the TSS conte grapefruits was significantly reduced by impact bruising. However, Maia et al. [32] fo that high bruising incidence increased the TSS content of banana fruit. Accordin Pathare and Al-Dairi [7], storage temperature and storage duration had a high influ on the TSS value of pear fruit. In their study, they found that storage at 22 °C recorded highest TSS levels in pears. In another study by Pathare et al. [19], they revealed that age at 5 °C showed the smallest reduction in TSS.

Pearson Correlation
To study the relationship between the quality attributes and bruising size parameters, the Pearson correlation test was performed (Table 3). A significant correlation (*, p < 0.05; **, p < 0.001) was found between the quality attributes of cucumbers. The BA of cucumbers impacted by the 30 cm drop height and stored at 5 • C recorded a high positive correlation with Wl% (r = 0.988 **), b* (r = 0.953 **), and ∆E* (r = 0.918 **), and a strong negative correlation with a* (r = 0.909 **). For quality attributes, Wl% was greatly correlated with Wl% across all treatments with r > 0.840. In all bruised cucumbers stored at 5 • C, the firmness exhibited a good relationship with color attributes, such as a* (r ≥ −0.747) and b* (r ≥ 0.734). Additionally, the a* values showed a strong correlation with b* in the majority of bruised cucumbers stored at different conditions. A weak correlation was observed between the firmness values and total soluble solids (TSS) of all tested conditions after 24 days of storage. The highest correlation found between total soluble solids and ∆E* (r = 0.804) was recorded for cucumbers bruised by the 90 cm height and stored at 10 • C. Table 3. Pearson correlation coefficients (r) between the bruise area (BA), bruise volume (BV), bruise susceptibility (BS), weight loss % (Wl%), firmness, lightness (L*), redness (a*), yellowness (b*), chroma*, hue*, the total color difference (∆E*), and total soluble solids (TSS) of cucumbers impacted by three drop height levels (30, 60, and 90 cm) in three storage conditions (5 • C, 10 • C, 22 • C) during 24 days of storage. Significant correlations of two-tailed tests are indicated: *, p < 0.05; **, p < 0.001.

Conclusions
This study investigated the effect of the drop height, storage temperature, and storage period on the quality and properties of cucumbers. The bruising damage measurements were influenced by the storage temperature and drop height. Cucumbers impacted by the maximum drop height (90 cm-0.590 J) increased BA and BS during storage. Once the cucumbers were subjected to an impact from a 90 cm drop height for a 24-day storage period, a rapid increase (L*, a*, b*, and hue*) was recorded in cucumbers stored at 22 • C, where more color deterioration and ripening were observed. The drop height did not affect the hue* value, but the temperature and duration of storage did. There was a significant influence of both storage duration and drop height on the chroma* value. The firmness is significantly affected by storage duration and does not affect the drop height and temperature. The total color change (∆E*) values significantly differed with all studied factors. Fresh produce that has been bruised can be stored at 10 • C to preserve its qualitative features. This means that storage management is considered an important strategy to maintain the quality of fresh produce, such as cucumber, and to overcome mechanical damage issues during the supply chain.