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Article

Influence of Different Packages and Storage Temperatures on the Quality of Edible Allium Species

Federal State Budgetary Scientific Institution “Federal Scientific Vegetable Center”, VNIISSOK, 143072 Odintsovo, Russia
*
Author to whom correspondence should be addressed.
Int. J. Plant Biol. 2023, 14(2), 512-519; https://doi.org/10.3390/ijpb14020040
Submission received: 4 February 2023 / Revised: 31 May 2023 / Accepted: 5 June 2023 / Published: 7 June 2023

Abstract

:
Allium resources in Russia are a potential source of genes for expanding the genetic base of agricultural crops. The leaves of Allium crops have a short freshness period and quickly deteriorate due to spoilage and loss of water. The aim of the work was to establish the yield and change in the quality of green leaves of Allium species introduced into the Moscow region during short-term storage, depending on the type of packaging, storage period, and temperature. Research methods: introduction and mobilization of existing plant genetic collection of representatives of the genus Allium L. was carried out as part of the implementation of the State task. Four to five-year-old plants of four species (A. altyncolicum, A. chyatophorum, A. nutans and A. turkestanicum) were grown on the collection plot of perennial onions of VNIIO, a branch of the FGBNU FNTSO. In the conditions of the Moscow region, the yield per leaf generation varied from 2.7 kg/m2 (A. altyncolicum) to 4.9 kg/m2 (A. cyathophorum). The maximum yield of marketable products was noted in hermetically sealed plastic bags when stored for 10 days at a temperature of +6 to +8 °C in a refrigerator with controlled conditions: A. turkestanicum—70.0%, A. cyathophorum—75.5%, A. altyncolicum—84.9%, A. nutans—92.9%. The maximum content of vitamin C during storage in hermetic bags with a density of 100 μm was found in A. altyncolicum (37.1 mg per 100 g) and A. nutans (42 mg per 100 g). A slight increase in the amount of sugars after storage for 10 days was noted in species with a linear leaf shape when stored in a polymer box. Temperature control is the most effective approach to extending the shelf life of fresh green leaves by measuring their weight loss and vitamin C.

1. Introduction

Consumers are increasingly aware of the need to consume seasonally available, new food sources characterized by a rich nutritional composition and a significant content of phytochemicals with a high antioxidant capacity [1]. In fact, numerous studies show that healthy eating and the prevention of various degenerative diseases are closely linked and that by consuming foods rich in biologically active compounds and phytonutrients, we can have a significant positive impact on health. One of the important components of a healthy diet today is the minimal impact on the environment. This means that a healthy diet includes foods that are rich in nutrients as well as those that are less harmful to the environment, such as fruits, vegetables, and medicinal plants [2]. Therefore, when planning a healthy daily diet, it is important to include those foods that are characterized by a rich composition of specialized, environmentally friendly metabolites. One of the neglected plant species, especially in terms of nutrition, is representative of the genus Allium L.
The economic value and prospects of Allium L. are indisputable since they are food, medicinal, honey, and ornamental plants [3,4,5,6]. Allium L. resources in Russia are a potential source of genes for expanding the genetic base of agricultural crops [1].
The genus Allium L. attracts the attention of researchers due to the presence of valuable medicinal, nutritional, and decorative properties, adaptive capabilities, resistance to pests and diseases, and ecological plasticity in its representatives, which contributes to the competitiveness of species and the manifestation of a high degree of adaptation outside natural areas and wide geographical distribution. It is precisely because of the rich nutritional composition and the content of phytochemicals with high therapeutic potential and the range of biological activity, from antioxidant to antimicrobial, that this plant species can be considered a functional food with a high production potential for various functional foods and foods of natural origin [7,8].
As a result of changing consumer habits, the global market for minimally processed fruits and vegetables has rapidly developed in recent years [9,10]. By 2022, this market is estimated to reach $346.05 billion [11,12]. Some of the minimally processed foods on the market are mixed vegetables for salads, soups, and sandwiches [13]. Allium species are well known for their use in food flavorings and seasonings, and for their therapeutic role due to their antioxidant, anti-inflammatory, and hypocholesterolemic properties [14,15].
A. altyncolicum grows in the Southern Altai, a narrow local endemic mesohygrophyte, and a rhizome bulbous plant. The phenorhythmotype is a long-term vegetative, summer green with forced winter dormancy and early summer blooming. Leaves remain green until severe frost sets in [16,17].
A. chyatophorum is endemic to China. It grows in mountain meadows and on slopes at an altitude of 2700–4600 m, and its leaves are flat and narrow [18].
A. nutans is endemic to the steppe communities of southern Siberia, northern Kazakhstan, and the southern Urals. It grows on rocky steppe and meadow slopes, on bedrock outcrops [19].
In nature, the range of A. turkestanicum covers Central Asia from the Aral Sea to Balkhash and the Tien Shan. It is endemic and grows on outcrops of variegated rocks [20].
Fresh vegetables are metabolically active for long periods after harvesting due to both endogenous activities, such as respiration, and external factors, such as physical injury, microbial flora, water loss, and storage temperature. Green onions deteriorate quickly and have a short sales period in the distribution network. Freshly cut green onion leaves stored at 0 °C can be stored for up to 4 weeks. Currently, green onions are stored in supermarkets and chains, as a rule, at a temperature of +6 to +8 °C and above. Moisture loss or transpiration is an important physiological process that affects the main qualities of fresh vegetables such as saleable weight, appearance, texture, and flavor. A loss in weight of only 5% often causes fresh produce to lose freshness and appear wilted. To preserve the quality and extend the shelf life of herbs, it is necessary, first of all, to reduce water losses. This can be achieved using various types of packaging, including a plastic bag.
Allium leaves are highly perishable products that quickly lose their marketability mainly due to high metabolic rate, water content, weight loss, softening, discoloration, and microbial and enzymatic spoilage, combined with poor management and transportation to the consumer. Important indicators of the quality of green onions are freshness, the absence of mechanical damage and decay, and an even and healthy minimum cut [21]. An alternative storage method is needed to extend the shelf life of the leaves.
The purpose of the study is to determine the yield and study the changes in the quality of green leaves of Allium L. species introduced into the Moscow region during short-term storage, depending on the type of packaging, duration, and temperature of storage.

2. Materials and Methods

In connection with the study and maintenance of germ plasm, the Allium collection was created at VNIIO, a branch of the Federal State Budget Scientific Institution of the Federal Scientific and Practical Center for Ecology from 12 subgenera, 34 sections, 80 species ex situ: (a) seeds; (b) field “live” collections.
The list of studied Allium species in the food direction is presented according to the standards adopted in the International Plant Names Index (IPNI) or The Plant List database (Table 1, Figure 1). In the Russian Federation, the commercial varieties A. altyncolicum and A. nutans are cultivated in the fields, while A. chyatophorum and A. turkestanicum are cultivated in gardens by the population. The tested Allium was obtained from various botanical gardens in Russia.
Plants were grown on the collection plot of perennial onions, VNIIO, a branch of the Federal State Budget Scientific Institution of the Federal Scientific and Practical Center for Natural Resources (Moscow region, 55°36′ N 38°1′ E). The sown area of each species was 20 m2. The soil of the experimental plot is an alluvial meadow and has a high level of natural fertility.
The selection of standard products for storage was carried out in accordance with the requirements of the Interstate Standard GOST 34214-2017 “Fresh green onions. Specifications”. Leaf samples were taken in the morning hours in the phase of mass growth of plants in adult generative individuals, growing for 3 years under the conditions of introduction. Fresh green onion leaves were packed in plastic bags (Logo Paket, Russia) with a density of 100 μm, size 35 × 50 cm, and weight of 900 g. Samples placed in an open polymer box lined with polyethylene bag (Logo Paket, Russia) served as controls. After cutting, the leaves were stored in an adjustable refrigerating chamber for 5 days and 10 days at a temperature of +6 to +8 °C. Two variants of leaf storage were studied: an open polymer box lined with a polyethylene bag and a hermetically plastic bag with a density of 100 µm.
The samples were weighed on the day of the experiment, and on the 5th and 10th days for data collection. The experiment was based on a single-factor completely randomized experiment with three repetitions. Storage was carried out for 5 days at a temperature of +10 to +12 °C, and 10 days at a temperature of +6 to +8 °C in a refrigerator with controlled storage conditions. Relative air humidity was 90 ± 3%. Relative humidity and temperature were controlled with a DT-171 temperature and humidity recorder (China). A comparative evaluation of products was carried out in terms of natural weight loss, separation of absolute waste, and changes in the chemical composition. Yellowed or rotted leaves were separated and weighed. The determination of the mass fraction of green onions that do not meet the quality requirements was calculated according to GOST 34214-2017 “Fresh green onions. Specifications”.
Biochemical analyzes were carried out before and after the expiration of the shelf life: dry matter–thermostatic weight method (drying at 105 °C); sugars, according to Bertrand; vitamin C, according to Murri; and nitrates ionometrically, according to the TsINAO method [22].
The data obtained were analyzed for statistical significance using the Microsoft Excel 2007 program. For each type of onion, the arithmetic mean values of the studied parameters and the standard deviation of the sample from the mean were calculated [23].

3. Results and Discussion

Under the conditions of the introduction of the Moscow region, the maximum leaf yield was recorded in A. cyathophorum—4.9 kg/m2 per leaf generation. The increase in yield is due to high productivity (1.2 kg/plant) and a large number of leaves (469 pieces). The leaves are flat, 43.3 cm long, and 1.2 cm wide (Table 2). In A. nutans variety broad-leaved, the productivity per leaf generation was 0.98 kg, while the yield was fixed at 3.9 kg/m2. The increase in yield is associated with a large number of leaves (240 pieces/plant) and leaf width (1.5 cm). The productivity of A. turkestanicum was noted at the level of 0.8 kg/plant, the yield was 3.2 kg/m2. In A. altyncolicum, the productivity was 0.7 kg/plant, and the yield was 2.7 kg/m2.
Of the packaging methods we studied, the maximum yield of Allium after storage was in hermetic bags, since there was practically no natural weight loss in them. In the bag-lined polymer box, the natural weight loss was high (Table 3). The shelf life of Allium leaves at ambient temperature is 24 h.
In hermetically plastic bags with a density of 100 microns, moisture condensation was noted during the storage of products. The reason is that the high air humidity and low O2 levels inside the plastic bags have led to the accumulation of moisture, a by-product of respiration, resulting in condensation, which provides a favorable environment for the growth of rot-causing microorganisms.
Higher temperatures significantly increase decay and loss of turgor, shortening the period of implementation. Thus, the storage temperature regime of +10 to +12 °C for 5 days was on average worse in all respects compared to the temperature regime of +6 to +8 °C for 10 days.
A. altyncolicum had the most dry substances (14.3%), mono- (2.92%), di- (2.11%), and total (5.035%) sugars in freshly cut leaves, and vitamin C in A nutans (37.6 mg%) (Table 4). This indicates a high biological value of these samples for rational human nutrition.
After storage, biochemical analysis of green onion leaves was carried out on the best storage option (10 days at a temperature of +6 to +8 °C). The content of quality indicators of green leaves of Allium representatives after storage was calculated, taking into account the weight loss of products.
An increase in the content of vitamin C during storage in hermetic bags was found in A. altyncolicum (37.1 mg per 100 g) and A. nutans (42.0 mg per 100 g). In other species, the maximum value of this indicator was noted before storage. The same phenomenon was noted during the storage of vegetable coriander greens in plastic bags [24].
In species with a linear leaf shape, when stored for 10 days in a polymer box, there was a tendency to increase the amount of sugars after storage, but a slight decrease in this indicator was recorded in A. altyncolicum with horn-shaped leaves compared to the data before storage.
A slight increase in the content of nitrates in the leaves by 3–4 mg/kg was established when stored in a hermetically plastic bag, and when stored in a polymer box lined with a plastic bag, the content of nitrates decreased by an average of 9 mg/kg.

4. Conclusions

Today, consumers are looking for products with a beneficial effect because they are more concerned about their health and well-being. Allium leaves can be considered a valuable source of many specialized metabolites with high antioxidant capacity and, thus, have a high production potential for a variety of naturally occurring functional foods and nutritional supplements that are important for promoting human health. Recommended for storage of green leaves hermetic plastic bag (10 days at a temperature of +6 to +8 °C). Future research should focus on exploring new types of packaging and other types of edible Allium.

Author Contributions

Conceptualization, M.I.I. and E.Y.; methodology, M.I.I.; validation, M.I.I., E.Y. and A.K.; writing—review and editing, M.I.I. and E.Y. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data is contained within the article.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Studied species of Allium for food purposes.
Figure 1. Studied species of Allium for food purposes.
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Table 1. Complex of species of the genus Allium L. of the food direction.
Table 1. Complex of species of the genus Allium L. of the food direction.
SubgenusSectionSpeciesLeaf Shape
CepaSchoenoprasum Dum.A. altyncolicum N. Friesenfistulate
CyathophoraCyathophora R.M. FritschA. chyatophorum Bureau & Franchlinear
RhizirideumRhizirideum G. Don ex KochA. nutans L.
AlliumMediasia F.O.Khass., Yengalycheva & N. FriesenA. turkestanicum Regel
Table 2. The structure of the crop of perennial food onions (plants 3 years old) in the phase of consumer ripeness in the conditions of the Moscow region.
Table 2. The structure of the crop of perennial food onions (plants 3 years old) in the phase of consumer ripeness in the conditions of the Moscow region.
IndicatorsA. nutansA. cyathophorumA. altyncolicumA. turkestanicumLSD (5%)
Plant height before cutting, cm40.050.674.637.4-
Number of monocarpic shoots, pieces/plant30679536-
Number of leaves, pcs.240469285180-
Sheet length, cm32.443.352.036.5-
Sheet width, cm1.51.20.51.3-
Productivity, g/plant9831235668820197
Yield, kg/m23.94.92.73.20.9
Source: compiled by the authors.
Table 3. Preservation of green leaves of representatives of the genus Allium, depending on the different packages and storage temperature.
Table 3. Preservation of green leaves of representatives of the genus Allium, depending on the different packages and storage temperature.
Temperature, Shelf LifeSpeciesType of PackagingMarketable Output, %Losses, %
Weight Loss, %Absolute Waste, %
+10 to +12 °C,
5 days
A. nutansPolymer box lined with plastic bag73.111.515.4
Hermetic plastic bag84.20.015.8
A. cyathophorumPolymer box lined with plastic bag69.610.320.1
Hermetic plastic bag80.40.019.6
A. altyncolicumPolymer box lined with plastic bag65.811.822.4
Hermetic plastic bag70.60.029.4
A. turkestanicumPolymer box lined with plastic bag59.711.528.8
Hermetic plastic bag69.10.030.9
MeanPolymer box lined with plastic bag67.111.321.7
Hermetic plastic bag76.10.023.9
LSD (5%)-2.9--
+6 to +8 °C,
10 days
A. nutansPolymer box lined with plastic bag83.29.37.5
Hermetic plastic bag92.90.07.1
A. cyathophorumPolymer box lined with plastic bag65.28.925.9
Hermetic plastic bag75.50.024.5
A. altyncolicumPolymer box lined with plastic bag72.010.217.8
Hermetic plastic bag84.90.015.1
A. turkestanicumPolymer box lined with plastic bag70.010.419.6
Hermetic plastic bag79.30.020.7
MeanPolymer box lined with plastic bag72.69.717.7
Hermetic plastic bag83.20.016.9
LSD (5%)-3.1--
Source: compiled by the authors.
Table 4. Biochemical composition of green leaves of Allium representatives, depending on the types of packaging, before and after storage for 10 days in a refrigerator at a temperature of +6 to + 8 °C.
Table 4. Biochemical composition of green leaves of Allium representatives, depending on the types of packaging, before and after storage for 10 days in a refrigerator at a temperature of +6 to + 8 °C.
SpeciesType of PackagingDry Matter, %Vitamin C, mg per 100 gSugar, %Nitrates, mg/kg
Mono-Di-Total
A. nutansBefore storage11.037.62.420.663.0888
Polymer box lined with plastic bag12.535.33.611.425.0377
Hermetic plastic bag11.042.02.570.913.4892
A. cyathophorumBefore storage9.930.82.291.373.6588
Polymer box lined with plastic bag10.120.24.470.474.9486
Hermetic plastic bag9.421.32.620.072.6991
A. altyncolicumBefore storage14.334.72.922.115.0389
Polymer box lined with plastic bag15.516.52.371.573.9978
Hermetic plastic bag15.137.12.951.964.9192
A. turkestanicumBefore storage11.235.02.131.523.6592
Polymer box lined with plastic bag12.415.73.930.654.5878
Hermetic plastic bag11.225.63.040.333.3791
MeanBefore storage11.634.52.441.423.8589
Polymer box lined with plastic bag12.621.93.601.034.6480
Hermetic plastic bag11.731.52.800,823,6192
Standard deviation2.049.050.720.660.835.84
Source: compiled by the authors.
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MDPI and ACS Style

Ivanova, M.I.; Yanchenko, E.; Kashleva, A. Influence of Different Packages and Storage Temperatures on the Quality of Edible Allium Species. Int. J. Plant Biol. 2023, 14, 512-519. https://doi.org/10.3390/ijpb14020040

AMA Style

Ivanova MI, Yanchenko E, Kashleva A. Influence of Different Packages and Storage Temperatures on the Quality of Edible Allium Species. International Journal of Plant Biology. 2023; 14(2):512-519. https://doi.org/10.3390/ijpb14020040

Chicago/Turabian Style

Ivanova, Maria I., Elena Yanchenko, and Anna Kashleva. 2023. "Influence of Different Packages and Storage Temperatures on the Quality of Edible Allium Species" International Journal of Plant Biology 14, no. 2: 512-519. https://doi.org/10.3390/ijpb14020040

APA Style

Ivanova, M. I., Yanchenko, E., & Kashleva, A. (2023). Influence of Different Packages and Storage Temperatures on the Quality of Edible Allium Species. International Journal of Plant Biology, 14(2), 512-519. https://doi.org/10.3390/ijpb14020040

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