Influence of Solution Combination for Postharvest Treatment Stage on Vase Life of Cut Hydrangea Flowers (Hydrangea macrophylla cv. ‘Verena’)
1
Postharvest Technology Division, National Institute of Horticultural and Herbal Science, RDA, Wanju 55365, Korea
2
Pear Research Institute, National Institute of Horticultural and Herbal Science, RDA, Naju 58216, Korea
*
Author to whom correspondence should be addressed.
Horticulturae 2021, 7(10), 406; https://doi.org/10.3390/horticulturae7100406
Submission received: 9 September 2021
/
Revised: 13 October 2021
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Accepted: 14 October 2021
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Published: 15 October 2021
(This article belongs to the Collection Postharvest Handling of Horticultural Crops)
Abstract
:Vase life is one of the most important factors that determines the marketability of cut flowers and is greatly affected by the water balance. The vase life of cut hydrangea flowers varies greatly depending on the postharvest solution management. Therefore, this study investigated the vase life of freshly harvested hydrangea (Hydrangea macrophylla ‘Verena’) according to the three types of preservative solutions (tap water (TW), 1% Chrysal Professional Ⅲ (CPⅢ), 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid (SHQC)) and the combination solutions (pretreatment; TW, 0.1% Chrysal RVB (RVB), Floralife Quick Dip (FQ), transport; TW, CPⅢ, Floralife Clear (FC), preservative; CPⅢ, FC) for each distribution stage (pretreatment–transport–consumer). In the preservative comparison experiment, compared with the control, SHQC and CPⅢ significantly increased the vase life in 2019 (0.7 days, 3.4 days) and 2020 (1.4 days, 3.1 days), respectively. In the comparative experiment, by solution combination, the group (RVB, FQ) using the pretreatment significantly extended the vase life by 5.9 days and 4.6 days compared with the TW. These results confirm the importance of preservative solutions and pretreatment, suggesting that appropriate pretreatment and preservatives should be used to improve the marketability of cut hydrangea flowers.
1. Introduction
Hydrangea (Hydrangea spp.) is an ornamental plant widely used in the garden as a potted plant and also for cut flower production. Especially, Hydrangea macrophylla is the most cultivated cultivar among the Hydrangea species. Hydrangea inflorescences are classified into two types: hortensia and lace caps, depending on the arrangement of decorative and nondecorative flowers. Hortensia-type hydrangea, which has a high market share in the cut flower market, is classified into two stages: fresh stage and antique stage, depending on the harvest stage [1].
Vase life of cut hydrangea flowers harvested in the fresh stage is usually short, between 7 and 15 days [2]. Vase life is one of the most important quality factors affecting the marketability and customers’ satisfaction of cut hydrangea flowers [3]. An important factor in determining the quality of cut flowers is known as vase life, which is affected by water absorption and evaporation [4]. Water absorption and evaporation of cut hydrangea flowers in all cut flowers is associated with catabolism, such as respiration, and decreases due to vascular occlusions by air embolism and microorganisms. In particular, microorganisms block the ends of cut flowers’ stems, inhibiting solution uptake and shortening vase life [1,5]. To solve this problem, some studies have been conducted to extend the vase life of cut flowers by adding various preservatives to vase water [6,7,8,9,10]. In addition, the most important problem after harvesting cut flower hydrangea is that if the water supply is not maintained, air embolism may occur. Air embolism in xylem conduits can partially or completely block the water transport path between roots and sinks for water in plants [11]. Wilting is sometimes caused by air embolism and is a criterion for the end of vase life, and the vase life of cut hydrangeas is shortened due to sepal browning and wilting [12]. To prevent wilting by air embolism, cut flowers should be pretreated immediately after harvesting, have moisture managed during transport, and obtain preservative solution treatment at the consumer stage.
In many previous studies, aluminum sulfate, 8-hydroxyquinolin, 8-hydroxyquinolin sulfate (8-HQS), 8-hydroxyquinolin citrate, ethanol, and sodium hypochlorite are typically used as preservatives. In particular, 8-HQS is one of the essential preservatives used in cut flowers and has been reported to have a positive effect [13,14,15]. 8-HQS mainly acts as an antibacterial agent and has been reported as a mechanism to increase moisture by physiologically reducing stem blockage in sterile tissue absorption [16]. Sucrose is the most commonly used sugar to extend the vase life of cut flowers, and exogenous application of sucrose can supply large amounts of respiratory substrate to cut flowers and induce the flowering of flowers that are harvested at the bud stage. It is also known to improve water relationships by acting as osmotically active molecules [17].
However, although many studies on the effects of 8-HQS and sucrose have been reported, studies comparing the effects of 8-HQS and sucrose with preservatives commercially used in actual farmhouses are lacking.
The market for hydrangea is largely divided into domestic and export, and is commonly subdivided into harvest–transport–sale. In order to maintain the quality of cut flowers, proper vase solution treatment (pretreatment after harvesting, water container during transportation, preservative solution after purchase) should be performed at each distribution stage.
We aimed to compare the effects of currently used preservatives and scientifically reported preservatives on the vase life of cut hydrangea flowers, and further investigate the effect of each combination of pretreatment, transport, and preservative treatment.
2. Materials and Methods
2.1. Plant Materials
The hydrangea cultivar used in this experiment were those that are widely sold in Korea, and all were harvested in fresh stages. The cut hydrangea flower samples were ’Verena’ grown in a farm in Gangjin, Jeollanam-do, South Korea (34°34′06″ N 126°50′08″ E). The flowers were harvested at the commercial stage, where about 80% of the florets showed the colors of the cultivar in June of 2019 and 2020. The harvested flowers were immediately pretreated in a cold storage at 4 °C for 24 h. After pretreatment, they were recut to a length 60 cm and put in a water container and transported to the postharvest laboratory within three hours. Then, the flowers were stored 72 h at 4 °C to transport conditions during simulated export. After simulated transport, the flower stems were recut to a length of 48 cm and five upper leaves were held on each stem for vase life evaluation.
2.2. Treatment Solutions
In this study, the first experiment is a comparative experiment with 3 types of preservation solutions, and the second experiment is a comparative experiment with 4 types of solution combinations for each postharvest treatment stage. The postharvest treatment stage was divided into a pretreatment stage at the farm, a transport stage during distribution, and a stage for preserving cut flowers after purchase.
For comparison by preservative solution treatment, the pretreatment and transportation solution were treated with tap water (TW), and then the preservation solution was used. The preservative solutions used were 1% Chrysal Professional Ⅲ (CPⅢ), 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid (SHQC), and TW as control. Preservative solution treatment was carried out by putting 700 mL of preservative solution prepared in advance in a glass bottle (1000 mL).
For comparison by solution combinations for each postharvest treatment stage, the pretreatment solution used were 0.1% Chrysal RVB (RVB), Floralife Quick Dip (FQ), and TW as control. For pretreatment, after the hydrangea flowers were harvested, they were immediately transferred to storage set at 4 °C and immersed in the pretreatment solution for 24 h. The transport solution used were CPⅢ, Floralife Clear (FC), and TW as control. The pretreated flowers were put in a water container containing transport solution, and then packed in a cardboard box and stored at 4 °C for 72 h, which was simulated transport with consideration for the transport period from packaging to sales. The preservative solution used were CPⅢ and FC. All solutions were prepared fresh at the initiation of the study. The conditions of the vase life evaluation room included a fluorescent lamp turned on for 12 h from 6 am to 6 pm every day with a room temperature of 22 ± 1 °C, and relative humidity of 60 ± 5%.
2.3. Relative Fresh Weight, Solution Uptake, Water Balance, and Vase Life
Fresh weight and solution uptake were measured once every 2 days. Fresh weight was calculated by subtracting the weight of the vase and solution from the total weight of the vase, solution, and flower. Relative fresh weight was calculated as the rate of fresh weight change, which was calculated as a percentage of fresh weight at the day of measurement compared with fresh weight at the day of initial.
Relative fresh weight (% of initial) = (Wt/W0) ∗ 100
Wt = the weight of flower stem (g) at the day of measurement
W0 = the weight of flower stem (g) at the day of initial
Solution uptake was investigated by subtracting the weight of the vase and solution on the day of measurement from the weight of the vase and solution on the previous day. Total solution uptake was calculated by adding up all daily solution uptakes. Water balance was investigated by subtracting transpiration from solution uptake, and transpiration was investigated by subtracting the total weight (sum of the weight of the vase, solution, and cut flower) on the day of measurement from the total weight on the previous day. Vase life was defined by the duration from the initial experiment to the occurrence of wilting, browning, and drying. The degree of flower wilting, browning, drying and vase life of flowers was determined according to the morphological stages and appearance of symptoms such as drying, brown edges, wilting flower, and bent neck (Figure 1).
2.4. Statistical Analysis
The experiment with preservative solution 3 treatment and postharvest solution combination 4 treatments was conducted in completely randomized design (CRD) with three replicates and three flowers for each replication. For statistical analysis, data were subjected to Brown–Forsythe and Welch analysis of variance (ANOVA) using the SPSS 20 (SPSS Inc., Chicago, IL, USA), while the significance of differences was assessed using Duncan’s multiple range test (p < 0.05).
3. Results
3.1. Relative Fresh Weight Due to Preservative Solution
Fresh weight results were expressed as relative fresh weight with the results for each preservative solution treatment shown in Figure 2. Relative fresh weight in SHQC treatment increased sharply until 8 days (2019) and 10 days (2020), respectively (Figure 2). As a result, in 2019, TW and CPⅢ treatment maintained, as compared with initial weights, whereas the SHQC treatment increased at 8 days (Figure 2a). As a result, in 2020, a pattern similar to the 2019 result was shown, and the TW and CPⅢ treatment maintained the initial weight, while the SHQC treatment increased the fresh weight compared with the initial weight. (Figure 2b).
3.2. Solution Uptake and Total Solution Uptake Due to Preservative Solution
Solution uptake decreased until the 10th day after preservative solution treatment in all treatments, and TW treatment was the the lowest until 6 days after treatment, but there was no significant difference between treatments. In addition, CPⅢ treatment and SHQC treatment maintained solution uptake as much as the initial solution uptake level until the end of vase life (Figure 3a). Total solution uptake in 2019 was 199.08 g/stem in CPⅢ treatment, which was higher than tap water treatment (138.00 g/stem) and SHQC treatment (163.54 g/stem) (Table 1). As a result, in 2020, the initial solution uptake of the three treatments was 15.3, 15.9, and 16.3 g/stem, respectively, and the difference in absorption between TW, CPⅢ, and SHQC treatments was 0.6~1 g/stem, which was similar. Changes in solution uptake during the preservation period of cut flowers were 8.9, 11.4, and 12.0 g/stem at 19 days, respectively. The difference in solution uptake between TW and treatment with CPⅢ and SHQC ranged from 2.5 g/stem to 3.1 g/stem, and there was a statistically significant difference between the control and treatment groups (Figure 3b). In 2020, the total solution uptake of CPⅢ and SHQC was 135.28 and 132.71 g/stem, respectively, which was statistically significantly higher than TW treatment (Table 1).
3.3. Water Balance Due to Preservative Solution
The water balance results according to the preservative solution treatment showed a similar trend to the 2019 and 2020 results, and the water balance in the SHQC treatment was maintained longer than that of other treatments. The number of days to maintain the water balance was the date at which water balance value changed from a positive value to a negative value. As a result, in 2019, the number of days to maintain water balance in SHQC treatment was 8, which was maintained for 2–4 days longer than 6 days for CPⅢ treatment, and 4 days for TW (Figure 4a). In the study conducted in 2020, the number of days of maintaining water balance in SHQC treatment was 10, which was 2–4 days longer than 8 days for CPⅢ treatment, and 6 days for TW (Figure 4b).
3.4. Vase Life Due to Preservative Solution
The use of a preservative was effective in extending the vase life following the treatment with a preservative solution (Table 2). As a result, in 2019, the vase life of CPⅢ treatment and SHQC treatment was extended by 0.7–3.4 days as compared with the TW treatment. The minimum vase life of CPⅢ treatment was 18 days and the maximum vase life was 23 days, which exceeded the vase life of TW and SHQC treatment. In the 2020 results, the vase life was extended with the CPⅢ treatment and SHQC treatment as compared with the TW. In both 2019 and 2020, CPⅢ treatment and SHQC treatment with a preservation solution at the consumer stage was effective in extending the vase life of cut hydrangea flowers.
3.5. Relative Fresh Weight Due to Combination of Postharvest Solution
The results of relative fresh weight by solution combination for each postharvest treatment stage are shown in Figure 5a. There was a slight difference in the maintenance period of fresh weight for each treatment. As compared with other treatments, the RVB–CPⅢ–CPⅢ combination had the longest fresh weight maintenance period of 23 days and showed a difference of about 5 days. During vase life, the RVB–CPⅢ–CPⅢ combination was higher than those without pretreatment. It was similar to the FQ–FC–FC combination, and there was no significant difference.
3.6. Solution Uptake and Total Solution Uptake Due to Combination of Postharvest Solution
The results of solution uptake and total solution uptake by solution combination for each postharvest treatment stage are shown in Table 3 and Figure 5b. Solution uptake gradually decreased during the preservation period of cut flowers commonly for all treatments. In particular, the solution uptake of cut flowers treated with the TW–TW–CPⅢ and TW–CPⅢ–CPⅢ combination decreased sharply from 18 days. On the other hand, the RVB–CPⅢ–CPⅢ combination and FQ–FC–FC combination maintained solution uptake during vase life as compared with other combinations. This finding was statistically significant both by using Duncan’s multiple range test between absolute values, and with repeated measurements. The total solution uptake by each postharvest solution was 164.92 g/stem in the RVB–CPⅢ–CPⅢ combination, which was the highest as compared with other treatments, but there was no statistically significant difference between treatments.
3.7. Water Balance Due to Combination of Postharvest Solution
The results of water balance according to the solution management in the overall process from preharvest treatment to preservation solution showed a dramatic effect depending on the treatment (Figure 5c). The effect of maintaining the water balance according to the treatment of the transport solution used in the distribution stage was insignificant. The number of days for maintaining water balance between the TW–TW–CPⅢ combination and the TW–CPⅢ–CPⅢ combination was the same 9 days; therefore there was no difference between TW and CPⅢ used as a transport solution. However, due to the use of pretreatment, the number of days for maintaining water balance was slightly extended. The number of days for maintaining water balance of the RVB–CPⅢ–CPⅢ and the FQ–FC–FC combination with the pretreatment was 23, which was extended by 5 more days than the TW–TW–TW and the TW–CPⅢ–CPⅢ combination without pretreatment. In addition, there was a difference in the time when the water balance value rapidly decreased, depending on whether or not pretreatment was used. The combination with pretreatments such as RVB and FQ started to decrease from day 18, while the combination without pretreatment decreased sharply from day 18.
3.8. Vase Life Due to Combination of Postharvest Solution
The effect of pretreatment performed in the postharvest treatment stage was clearly different in the results of vase life according to the 4 groups of postharvest solution combinations (Table 4, Figure 6). The average vase life of the group pretreated with RVB and FQ were 29.9 and 28.6 days, respectively, which was longer than that of the group without pretreatment. In particular, the vase life of the RVB–CPⅢ–CPⅢ combination was 27 days at the minimum and 35 days at the maximum, which exceeded the vase life range of the TW–TW–CPⅢ combination. Through these results, it was confirmed that the use of an appropriate pretreatment agent is an important factor to extend vase life and improve quality.
4. Discussion
Cut hydrangea flowers are sensitive to water stress, and when water is insufficient, the water balance of the calyx changes to a negative value. The main causes of water stress are interruption of water supply and vascular occlusion at the tip of the stem [18]. Most cut flowers, including cut hydrangea flowers, have a high initial solution uptake rate, but decrease over time, mainly due to vascular blockage by microorganisms and air embolism [9]. The impact of kept water relations on extending the vase life is constructed on the conclusion that cut hydrangeas are sensitive to water shortage caused by disturbing the postharvest water balance [9,12,19]. If these causes persist, they wither and the quality of the cut flowers deteriorates, which is the standard for the end of the vase life [1]. Asrar [13] reported that solution uptake through preservative treatment improved the water balance and freshness of flowers and reduced premature wilting, thereby improving the vase life of cut flowers, which is similar to our comparative results of preservative treatment. In our study, we observed the vase life of cut hydrangea flowers according to the combination of a preservation solution at the consumer stage and solution combination for each postharvest treatment stage after harvest for the purpose of improving the marketability of cut hydrangea flowers. For hydrangeas grown in Korea, it usually takes 2–3 days for export to the destination country. During this period, water management should be focused on the pretreatment stage immediately after harvest and the transportation stage. Pretreatment immediately after harvest is an essential step as it artificially supplies nutrient moisture to cut flowers whose supply of moisture and nutrients is interrupted [20]. In addition, the use of preservatives as a post-treatment concept to help prolong the flower viewing period at the consumer stage is also effective in extending the vase life. In particular, the various chemical solutions used in this study, such as RVB, CPⅢ, SHQC, FQ, and FC, generally have a specific purpose, so proper use is required. Previous studies reported that there was a strong correlation between solution uptake and fresh weight [5,21], and the combined effect of sucrose and antibacterial agents on the fresh weight of cut flowers was significantly greater than that of single treatment [22]. Sucrose supply is known to increase vase life, and it has been reported that it may act as an osmotic active molecule constituting a water relationship, as well as a nutrient source for tissues [23,24,25]. Similar to these reports, in our study, RVB as a pretreatment and SHQC as a preservative solution absorbed more solution than TW treatment and improved water balance. In addition, SHQC treatment with 2% sucrose significantly increased the fresh weight as compared with TW treatment. These results at fresh weight are similar to those of solution uptake positively affected by 8-HQ with 2% sucrose. Ku and Cho [26] also used 8-HQS to increase vase life of cut hydrangeas. They performed three different experiments [1% and 3% sucrose + 250 mg/L 8-HQS, varying pH levels (3.5–5.5 and 7.5), organic acids (citric and ascorbic)] and 3% sucrose + 250 mg/L 8-HQS. As a result, it was reported that 8-HQS (pH 3.5), or 3% sucrose + 250 mg/L 8-HQS + 100 mL citric acid, was effective in improving the cut flower quality of hydrangeas. As such, the maintenance of the water balance according to the increase in solution uptake and the decrease in transpiration can have a positive effect on fresh weight by preventing the water loss of cut flowers. In addition, pretreatment using RVB, which consists of sucrose and disinfectant, and transportation and preservation processing using CPⅢ, which is used for a different purpose than RVB, is one of the postharvest management technologies that must be performed in the entire distribution process, from harvesting to sales. When managing in this way, it was confirmed that the effect of maintaining the marketability was excellent.
5. Conclusions
This study was set up to highlight the importance of using the right pretreatment and preservatives at farms and in distribution stages by showing the potential effects on maintaining the commerciality of cut hydrangea flowers and extending the vase life. In the preservation solution comparison experiment, treatment with 1% CPⅢ and SHQC significantly extended the vase life of cut hydrangea flowers by 3.1 days and 1.4 days, respectively, as compared with control. In the comparative experiment of solution combination for each postharvest treatment stage, the pretreatment group using RVB and FQ significantly extended the vase life of cut hydrangea flowers to 5.9 and 4.6 days, respectively, as compared with control group (TW–TW–CPⅢ). These results show that using a pretreatment solution is effective in improving the quality of cut hydrangea flowers after long-term distribution. However, SHQC used in the preservation solution comparison experiment was conducted to explore the possibility of replacing commercial preservatives, but did not obtain beneficial results, such as extending the vase life of cut hydrangea flowers and maintaining freshness. Therefore, new research on finding the optimal combination of sucrose, 8-HQS, and citric acid, and developing eco-friendly pretreatments and preservatives using natural materials should be performed.
Author Contributions
Conceptualization, I.-S.S. and H.Y.; methodology, I.-S.S. and H.Y.; validation, J.-H.L., S.L. and J.-W.C.; investigation, H.Y.; resources, I.-S.S.; data curation, J.-H.L., S.L. and J.-W.C.; writing—original draft preparation, H.Y.; writing—review and editing, I.-S.S. and H.Y.; visualization, H.Y.; supervision, I.-S.S.; project administration, I.-S.S. All authors have read and agreed to the published version of the manuscript.
Funding
This work was carried out with the support of “Research Program for Agriculture Science & Technology Development (Project No. PJ01434201)” Rural Development Administration, Korea.
Data Availability Statement
Data is contained within the article. The data presented in this study are available in article.
Acknowledgments
This study was supported by (2021) the RDA Fellowship Program of (National Institute of Horticultural & Herbal Science), Rural Development Administration, Korea.
Conflicts of Interest
The authors have declared that no conflicts of interest exist.
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Figure 1.
The main senescence symptoms of cut hydrangea flowers ‘Verena’ (a) browning (b) wilting.
Figure 2.
Changes in the relative fresh weight of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in (a) 2019 and (b) 2020. Vertical bars indicate standard deviation of means (n = 9). TW, tap water; CPⅢ, 1% Chrysal Professional Ⅲ; and SHQC, 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid.
Figure 2.
Changes in the relative fresh weight of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in (a) 2019 and (b) 2020. Vertical bars indicate standard deviation of means (n = 9). TW, tap water; CPⅢ, 1% Chrysal Professional Ⅲ; and SHQC, 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid.
Figure 3.
Changes in the vase solution uptake of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in (a) 2019 and (b) 2020. Vertical bars indicate standard deviation of means (n = 9). TW, tap water; CPⅢ, 1% Chrysal Professional Ⅲ; and SHQC, 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid.
Figure 3.
Changes in the vase solution uptake of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in (a) 2019 and (b) 2020. Vertical bars indicate standard deviation of means (n = 9). TW, tap water; CPⅢ, 1% Chrysal Professional Ⅲ; and SHQC, 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid.
Figure 4.
Changes in the water balance of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in (a) 2019 and (b) 2020. Vertical bars indicate standard deviation of means (n = 9). TW, tap water; CPⅢ, 1% Chrysal Professional Ⅲ; and SHQC, 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid.
Figure 4.
Changes in the water balance of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in (a) 2019 and (b) 2020. Vertical bars indicate standard deviation of means (n = 9). TW, tap water; CPⅢ, 1% Chrysal Professional Ⅲ; and SHQC, 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid.
Figure 5.
Changes in the relative fresh weight in (a) vase solution uptake, (b) water balance, and (c) cut hydrangea flowers ‘Verena’ by solution combination for each postharvest treatment stage in 2020. Vertical bars indicate standard deviation of means (n = 9). TW, tap water; CPⅢ, 1% Chrysal Professional Ⅲ; RVB, 0.1% Chrysal RVB; FQ, Floralife Quick Dip; and FC, Floralife Clear. The order of TW–TW–CPⅢ indicates the order of pretreatment solution, transport solution, and preservation solution.
Figure 5.
Changes in the relative fresh weight in (a) vase solution uptake, (b) water balance, and (c) cut hydrangea flowers ‘Verena’ by solution combination for each postharvest treatment stage in 2020. Vertical bars indicate standard deviation of means (n = 9). TW, tap water; CPⅢ, 1% Chrysal Professional Ⅲ; RVB, 0.1% Chrysal RVB; FQ, Floralife Quick Dip; and FC, Floralife Clear. The order of TW–TW–CPⅢ indicates the order of pretreatment solution, transport solution, and preservation solution.
Figure 6.
Appearance of cut hydrangea flowers ‘Verena’ by solution combination for each postharvest treatment stage in 2020. (A–D): First day after preservative solution, (E–H): 22nd day after preservative solution, (I–L): 29th day after preservative solution (A,E,I): TW–TW–CPⅢ, (B,F,J): TW–CPⅢ–CPⅢ, (C,G,K): RVB–CPⅢ–CPⅢ, (D,H,L): FQ–FC–FC.
Figure 6.
Appearance of cut hydrangea flowers ‘Verena’ by solution combination for each postharvest treatment stage in 2020. (A–D): First day after preservative solution, (E–H): 22nd day after preservative solution, (I–L): 29th day after preservative solution (A,E,I): TW–TW–CPⅢ, (B,F,J): TW–CPⅢ–CPⅢ, (C,G,K): RVB–CPⅢ–CPⅢ, (D,H,L): FQ–FC–FC.
Table 1.
Total solution uptake of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in 2019 and 2020.
Table 1.
Total solution uptake of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in 2019 and 2020.
| Year | Pretreatment Solution | Transport Solution | Preservative Solutions | Total Solution Uptake (g/stem) | F/p Value | Brown– Forsythe Value |
|---|---|---|---|---|---|---|
| 2019 | TW | TW | TW z | 138.00 b y | 4.759/0.058 ns x | 0.095 |
| TW | TW | CPⅢ | 199.08 a | |||
| TW | TW | SHQC | 163.54 ab | |||
| 2020 | TW | TW | TW | 105.12 b | 4.206/0.27 * | 0.028 |
| TW | TW | CPⅢ | 135.28 a | |||
| TW | TW | SHQC | 132.71 a |
z Abbreviations: TW = tap water; CPⅢ = 1% Chrysal Professional Ⅲ; SHQC = 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid. y a, ab, b: Mean separation within columns by Duncan’s multiple ranges test at p < 0.05. x Minimum vase life and maximum vase life (day). ns, *: Nonsignificant or significant at p < 0.05, respectively.
Table 2.
Vase life and main factor of senescence of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in 2019 and 2020.
Table 2.
Vase life and main factor of senescence of cut hydrangea flowers ‘Verena’ kept in each preservative solution treatment in 2019 and 2020.
| Year | Pretreatment Solution | Transport Solution | Preservative Solutions | Vase Life (days) | F/p Value | Brown– Forsythe Value | |||
|---|---|---|---|---|---|---|---|---|---|
| Average | Min. x | Max. | MF r | ||||||
| 2019 | TW z | TW | TW | 17.3 b y | 17 | 18 | B | 3.652/0.092 ns | 0.163 |
| TW | TW | CPⅢ | 20.7 a | 18 | 23 | B/W | |||
| TW | TW | SHQC | 18.0 ab | 17 | 19 | W | |||
| 2020 | TW | TW | TW | 20.9 b | 20 | 21 | B | 6.316/0.006 ** | 0.012 |
| TW | TW | CPⅢ | 24.0 a | 21 | 28 | B/W | |||
| TW | TW | SHQC | 22.3 ab | 20 | 24 | W/B | |||
z Abbreviations: TW = tap water; CPⅢ = 1% Chrysal Professional III; SHQC = 2% sucrose + 250 mg/L 8-hydroxquinoline + 100 mg/L citric acid. y a, ab, b: Mean separation within columns by Duncan’s multiple ranges test at p < 0.05. x Minimum vase life and maximum vase life (day). r Main factor in determining the vase life of cut flowers (B, browning; W, wilting). ns, **: Nonsignificant or significant at p < 0.01, respectively.
Table 3.
Total solution uptake of cut hydrangea flowers ‘Verena’ by solution combination for each postharvest treatment stages in 2020.
Table 3.
Total solution uptake of cut hydrangea flowers ‘Verena’ by solution combination for each postharvest treatment stages in 2020.
| Pretreatment Solutions | Transport Solutions | Preservative Solutions | Total Solution Uptake (g/stem) | F/p Value | Brown– Forsythe Value |
|---|---|---|---|---|---|
| TW z | TW | CPⅢ | 141.18 a y | 2.024/0.130 ns | 0.133 |
| TW | CPⅢ | CPⅢ | 143.78 a | ||
| RVB | CPⅢ | CPⅢ | 164.98 a | ||
| FQ | FC | FC | 158.48 a |
z Abbreviations: TW = tap water; CPⅢ = 1% Chrysal Professional Ⅲ; RVB = 0.1% Chrysal RVB; FQ = Floralife Quick Dip; FC = Floralife Clear. y a: Mean separation within columns by Duncan’s multiple ranges test at p < 0.05.). ns: Nonsignificant at p < 0.01, respectively.
Table 4.
Vase life and main factor of senescence of cut hydrangea flowers ‘Verena’ by solution combination for each postharvest treatment stage in 2020.
Table 4.
Vase life and main factor of senescence of cut hydrangea flowers ‘Verena’ by solution combination for each postharvest treatment stage in 2020.
| Pretreatment Solution | Transport Solution | Preservative Solution | Vase Life (Days) | F/p Value | Brown–Forsythe Value | |||
|---|---|---|---|---|---|---|---|---|
| Average | Min. x | Max. | MF r | |||||
| TW z | TW | CPⅢ | 24.0 b y | 21 | 28 | W | 9.674/0.000 *** | 0.000 |
| TW | CPⅢ | CPⅢ | 25.0 b | 20 | 29 | B | ||
| RVB | CPⅢ | CPⅢ | 29.9 a | 27 | 35 | B | ||
| FQ | FC | FC | 28.6 a | 23 | 31 | B | ||
z Abbreviations: TW = tap water; CPⅢ = 1% Chrysal Professional Ⅲ; RVB = 0.1% Chrysal RVB; FQ = Floralife Quick Dip; and FC = Floralife Clear. y a: Mean separation within columns by Duncan’s multiple ranges test at p < 0.05. x Minimum vase life and maximum vase life (day). r Main factor in determining the vase life of cut flowers (W, wilting; B, browning). ***: significant at p < 0.001, respectively.
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Yang, H.; Lim, S.; Lee, J.-H.; Choi, J.-W.; Shin, I.-S. Influence of Solution Combination for Postharvest Treatment Stage on Vase Life of Cut Hydrangea Flowers (Hydrangea macrophylla cv. ‘Verena’). Horticulturae 2021, 7, 406. https://doi.org/10.3390/horticulturae7100406
AMA Style
Yang H, Lim S, Lee J-H, Choi J-W, Shin I-S. Influence of Solution Combination for Postharvest Treatment Stage on Vase Life of Cut Hydrangea Flowers (Hydrangea macrophylla cv. ‘Verena’). Horticulturae. 2021; 7(10):406. https://doi.org/10.3390/horticulturae7100406
Chicago/Turabian StyleYang, Haejo, Sooyeon Lim, Ji-Hyun Lee, Ji-Weon Choi, and Il-Sheob Shin. 2021. "Influence of Solution Combination for Postharvest Treatment Stage on Vase Life of Cut Hydrangea Flowers (Hydrangea macrophylla cv. ‘Verena’)" Horticulturae 7, no. 10: 406. https://doi.org/10.3390/horticulturae7100406
APA StyleYang, H., Lim, S., Lee, J. -H., Choi, J. -W., & Shin, I. -S. (2021). Influence of Solution Combination for Postharvest Treatment Stage on Vase Life of Cut Hydrangea Flowers (Hydrangea macrophylla cv. ‘Verena’). Horticulturae, 7(10), 406. https://doi.org/10.3390/horticulturae7100406
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