Constant storage temperature delays firmness decreasing and pectin solubilization of apple during post‐harvest storage

Chen, Lan; Pan, Yiou; Jia, Xiaoyu; Wang, Xiaodong; Yuan, Junwei; Li, Xihong

doi:10.1111/jfpp.15655

Cited by 10 publications

(12 citation statements)

References 77 publications

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“…The mechanical strength of parenchyma cell walls, the extension between adjacent pulp cells, and the degree of cell turgor are major determinants of flesh firmness [ 17 ]. Generally, the depolymerization of pectin and multiple polysaccharides is regarded as an important factor that results in firmness decrease in most fruits [ 18 , 19 ]. The hydrolysis of pectin and the loss of neutral sugars from polysaccharides weaken cube firmness.…”

Section: Resultsmentioning

confidence: 99%

Systematic Study of the Sensory Quality, Metabolomics, and Microbial Community of Fresh-Cut Watermelon Provides New Clues for Its Quality Control and Preservation

Cai

Wang

et al. 2022

Foods

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As a popular form of fruit consumption, fresh-cut watermelon is of great convenience for its consumers. Owing to the lack of comprehensive knowledge about the quality changes of fresh-cut watermelon during its shelf life, guidelines and standards are unavailable currently. To clarify the deterioration process and its underlying mechanism in fresh-cut watermelon, the sensory parameters, metabolomics, and microbial community of fresh-cut watermelon during a three-day storage at both room temperature (RT) and refrigerator temperature were systematically studied in this work. Results revealed that the whole property of the watermelon stored at refrigerator temperature kept stable, while pulps stored at RT had substantially deteriorated after 36 h. The decay was reflected in the significant decrease in soluble solid contents, firmness, pH, and color parameters in the sensory perspective. At the metabolic level, significantly declined malate, citrate, uridine, uridine 5-monophosphate, and amino acids, and increased ethanol and lactate contents, were observed as deterioration markers, which partially resulted from the activities of pyruvate dehydrogenase and alcohol dehydrogenase and the burst of genera Enterobacteriaceae and Leuconostocaceae. This study unveiled the underlying mechanisms of quality changes in fresh-cut watermelon under its primary storage conditions to provide fundamental information and potential clues for its quality control and preservation.

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Section: Resultsmentioning

confidence: 99%

Systematic Study of the Sensory Quality, Metabolomics, and Microbial Community of Fresh-Cut Watermelon Provides New Clues for Its Quality Control and Preservation

Cai

Wang

et al. 2022

Foods

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“…The results of this study agree with that of Dhillon et al [27] where exposing pear fruits to 20±1C° decreased fruit firmness and increases fruit TSS and total sugars which are also considered as ripening markers. Keeping high acidity in fruits from control treatment for both cultivars and seasons may be due to decreasing in respiration and ethylene production [28], and its role in decreasing pectin dissolving [29] and delaying fruits ripening. Increasing the fruit's TSS may be due to increasing the activity of hydrolysis enzymes like invertase and starch phosphorylase [30] or as a result to increasing the soluble organic material as a result of water loss from fruits (tables 2 and 3).…”

Section: Resultsmentioning

confidence: 99%

Pear Fruits Ripening Response to Ethylene and Temperature Treatments

Tahir¹

2021

KJAR

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A factorial experiment with complete randomized design carried out in Erbil governorate, Iraq on two varieties of pears (Pyrus communis L.) spadona and compote cv. to investigate the effects of ethylene and temperature treatments on fruits ripening. The experiment includes four treatments; the control (cold storage at 0±1 C° and 85-90 relative humidity), the second was putting the fruits in ambient temperature with exposure to ethylene gas (300 mg/l) for 24 hours, third and fourth treatments were putting the fruits in the ripening cabinet at 20 C° either for 8 days, or 12 days. Results indicate that compote variety was differing significantly in decreasing weight loss and fruits firmness and increasing fruits peel pigments content and peroxidase enzyme activity compared to spadona variety. Slower ripening process was gained from cold storage treatment where the fruits remain non-ripened compared to other treatments, whereas ripening fruits at 20C° for 12 days fastened the ripening process by giving highest TSS, and lowest fruits firmness, in addition to percent of weight loss. For the condition of northern Iraq, the best treatment for ripening pear fruits is treating with ethylene gas or ripening the fruits at 20C° for 8 days.

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“…In addition, the suppression effect of the TF0.1 condition was more marked compared to the TF1 condition. Likewise, fruits, such as peaches [16] and apples [17], and vegetables, such as mushrooms, broccoli, and tomatoes [14], have been observed to be firmer and experience less weight loss when stored under low TF conditions. Besides, TSS and TA are important quality parameters of fruit, and as fruit senescence progresses, TSS and TA are consumed as respiratory metabolic substrates [45].…”

Section: Discussionmentioning

confidence: 99%

“…Peach exposed to higher TF (1 ± 2 • C) exhibited higher respiration and poorer soluble solids content compared to fruit in the CT environment (1 ± 0.1 • C) [16]. TF is detrimental to the storage quality of fresh agricultural products has been confirmed for apple [17], mature green tomato [18], strawberries [19], and table grapes [20,21]. All these reports provide evidence that the TF condition will accelerate the senescence of fresh horticultural produce, while the CT condition is helpful to maintain the quality of products.…”

Section: Introductionmentioning

confidence: 92%

Isothermal Storage Delays the Senescence of Post-Harvest Apple Fruit through the Regulation of Antioxidant Activity and Energy Metabolism

Chen

Wang

Hai-fen

et al. 2023

Foods

Self Cite

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The purpose of this work was to elucidate the influence of TF (5 ± 5 °C, and 5 ± 1 °C) and CT (5 ± 0.1 °C served as an isothermal state) storage environment on the antioxidant ability and energy metabolism in post-harvest apple fruit during storage. Specifically, compared with fruit in TFs groups, the quality attributes of apples in the CT group, including firmness, fresh weight, contents of SSC, and TA were maintained at a higher level. In addition, fruit stored in the CT environment revealed a suppressed respiration rate and EL, lower MDA, O2·−, and H2O2 accumulation but increased the activities of SOD, CAT, APX, and GR. At the end of storage, the SOD, CAT, APX, and GR activities of fruit in the CT group were 38.14%,48.04%, 115.29%, and 34.85% higher than that of the TF5 group, respectively. Fruit in the CT environment also revealed higher AsA, GSH, total phenols, and total flavonoid content. In addition, fruit stored in the CT environment maintained higher ATP content, EC, and more active H+-ATPase, Ca2+-ATPase, CCO, and SDH. At the end of storage, the SDH and CCO activities of fruit in the TF0.1 group were 1.74, and 2.59 times higher than that in the TF5 group, respectively. Taken together, we attributed the fact that a constant temperature storage environment can retard the fruit senescence to the enhancement of antioxidant capacities and maintaining of higher energy status in apple fruit.

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Constant storage temperature delays firmness decreasing and pectin solubilization of apple during post‐harvest storage

Cited by 10 publications

References 77 publications

Systematic Study of the Sensory Quality, Metabolomics, and Microbial Community of Fresh-Cut Watermelon Provides New Clues for Its Quality Control and Preservation

Systematic Study of the Sensory Quality, Metabolomics, and Microbial Community of Fresh-Cut Watermelon Provides New Clues for Its Quality Control and Preservation

Pear Fruits Ripening Response to Ethylene and Temperature Treatments

Isothermal Storage Delays the Senescence of Post-Harvest Apple Fruit through the Regulation of Antioxidant Activity and Energy Metabolism

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