Introduction
Micronutrient malnutrition, often known as hidden hunger, hinders growth, weakens the immune system, diminishes productivity, increases the risk of mortality, causes a number of pregnancy issues, including blindness and goitre, and lowers working capacity. The main causes of micronutrient deficiencies are a lack of dietary variety (i.e., monotonous diets), low mineral bioavailability, the prevalence of illness and disease, and higher physiological demands. Over two billion people are at danger of iron, vitamin A, or iodine deficiencies, according to the WHO (World Health Organization), with developing nations seeing the worst issues1.
Microgreens are juvinile vegetable greens picked/ collected after cotyledonary leaves are developed. Over the past ten years, microgreens have grown in popularity due to their fresh flavour and nutritional advantages. Southern California has been producing them since the 1990s.Since, in developed countries attraction towards healthy eating, gourmet cooking and indoor gardening has been increased and thereby microgreens have now attained recognition there. There is increased popularity of microgreens because of it has high nutritional sources2.
Microgreens can be defined as immature greens, tender and soft in texture, produced from the seeds of any plant or vegetable, having two totally developed cotyledon leaves, it can be harvested with a primitive pair of true leaves. The general height of the microgreens is 2.5-7.6 cm (1-3 inches), it is harvested only with the stem and attached cotyledons (seed leaves) and tiny, young true leaves without root. The harvesting time defers depending on the species from 7-14 days after germination 3.
According to research, microgreens have far higher levels of minerals, vitamins, and photochemicals than mature greens do, and they are also richer in both micronutrients and macronutrients4,5,6.Compared to matured green, scientist demonstrated that microgreens of broccoli (Brassica oleracea L. var. italica Plenck), radish (Raphanus sativus L.) and green curly kale (Brassica oleracea var. sabellica L.) contains higher levels of total antioxidant capacity, total carotenoids, total isothiocyanates, total anthocyanins , macro- (K, Ca, Mg) and oligo-elements (Fe, Zn) 7. Again compared to matured green, macro- and microminerals like iron (Fe), copper (Cu), and manganese (Mn), sulfur (S), zinc (Zn), potassium (K), calcium (Ca), nitrogen (N), phosphorus (P), sodium (Na) levels were much higher in celery (Apium graveolens L.) microgreen8.Scientists also demonstrated that minerals, total ascorbic acid, carotenoids, total chlorophylls, polyphenols, and antioxidant activity were much higher in the microgreen of four Apiaceae species[Pimpinella anisum L. (anise), Anthriscus cerefolium L. (chervil), Carum carvi L. (caraway), and Anethum graveolens L. (dill) ] compared to mature greens9. In comparison to mature greens, research also revealed that quinoa microgreens and sprouts were high in nutrients “(protein, amino acids)”, vital minerals, and omega-3 fatty acids10.
Mature black mustard and coriander greens are popular food of India, used in most of the households. It can be grown in Indian climate with minimum requirements and space. The focus of the present study was to estimate nutritional and functional characteristics of black mustard microgreens (Brassica nigra) and coriander microgreens (Corindrum sativum) at the different phases of their development (microgreen, baby green, mature green).
Materials and method
Growing of greens
The seeds used are black mustard (Brassica nigra) and coriander (Corindrum sativum) brought from local nursery of Kolkata. The greens were grown in plastic trays, seeds were sprinkled and it was kept covered till germination takes place. Trays were watered occasionally. The microgreens were harvested after it becomes 2.5−7.6 cm (1−3 inches.) in height and two fully developed cotyledon leaves. The baby greens were harvested after it becomes 10 cm in height and one or two pairs of true leaves were appeared. Mature greens were harvested after at 5-6 inches height or till when it develops mature leaves without cotyledon leaves11.
Sample preparation
Harvested leaves were shade dried for 7 days. The leaves were powdered and stored in zip lock packets at cool and dry place.
To make extract 5gm of dried sample was taken in conical flasks. 20 ml of ethanol was added to it. It was kept for 2 days with occasional stirring in a dark, cool place along. After 2 days, the extract was filtered into sterilized tubes. The extract was stored in refrigerator for further study. For microbiological methods, extracts were further diluted with water (1:1 ratio).
Samples for the estimation of protein, crude fibre, and carbohydrates were combined with water (5gm in 20mL) and refrigerated overnight. It was filtered the following day and put into sterile tubes for estimate.
Determination of macronutrients
Carbohydrate was estimated by Anthrone method 12. Biuret method was used for protein estimation13. Crude fiber was estimated by AOAC, 2005 official method 14.
Beta carotene Estimation
Five gram of each sample were taken, crushed with the help of pestle and mortar in 10-15 ml of acetone and few crystals of anhydrous sodium sulphate were added. The solution was centrifuged at 3000 rpm for 3-4 minutes. The supernatant was transferred to a test tube, 10-15 ml of petroleum ether mixed thoroughly with it and kept undisturbed. From the separated two layers upper layer was collected in a test tube and the lower layer was discarded. Using petroleum ether as blank optical density was measured at 452 nm 15.
Vitamin C Estimation
Ascorbic acid was estimated by Acid base titration method16.
Determination of Ash & mineral content
To estimate ash content, weight of silicon crucible was measured and noted. 3 gm of test samples were weighed and kept on crucibles. The crucible was placed in muffle furnace at 600°C for 3 hours. Measured ash content was noted.
Obtained ash from different test samples were dissolved in 6 N HCL and heated on a hot water bath for 30 mins or till white fumes were formed. The ash mixture was then cooled and filtered and a clear liquid was obtained. These ash solutions were used for the estimation of Iron, Calcium and Phosphorus. Testing kit of iron, calcium, phosphorus manufactured by Tulip Diagnostics (P) Ltd., Gitanjali, Tulip Block, Goa – 403 202, India was used.
Qualitative analysis of phyto-chemicals
The extracts of were analyzed for the revelation of different phyto-nutrients using standard methodology. Seven chemical groups (phenols, alkaloids, anthroquinones, flavanoid, saponin, Triterpenes, tanins) were tested. Decolorized ethanolic extract was used to determine the phyto-chemicals 17.
Phenol Estimation
0.5 gm of the sample was grinded in motar and pestle in 80% ethanol (10 times volume of sample). The homogenate was centrifuged at 10000 rpm speed for 20 minutes. The supernatant was taken the sediment was re-extracted with 80% ethanol (five time volume) and supernatant was collected. It was ten evaporated till dried. And dissolved with known volume of distilled water. 0.2-2 ml of solution was taken in test tube and the volume was made 3 ml with water. 3 minutes after adding the Fc reagent, 2 ml of 20% Na2CO3 was added in each tube. Then the it was mixed and placed in boiling water bath for 1 min and at 650 nm wave length the absorbance was measured 17 .
DPPH Free Radical Scavenging Activity
The antioxidant potential of different greens were estimated by measuring their capability to decolorize methanol solution of DPPH 18. In brief, 0.2 mM DPPH methanol solution was added to the extracts and incubated for 30 min at 250C.The absorbance of the mixture was recorded against blank at 516 nm.
Antimicrobial Activity
The antimicrobial activity of the extract of different greens were estimated against two different categories of microbes: Gram positive bacterial strain (Bacillus subtilis) [MTCC No: 441], Gram negative bacterial strain (Escherichia coli) [MTCC No: 1696].
Colony counting the presence of different green extracts
For each test, five petri plates were used, of which one was used as ‘Control’ plate (only vehicle was used), while the remaning were used as ‘Test’ plates containing different amounts of extracts (100µl, 200µl, 300µl, 400µl) which is equivalent to 12.5 mg, 25 mg, 37.5 mg, 50 mg of greens respectively. The petri plates were inoculated (streak) with the mentioned bacterial strains and were kept at 37ºC. Microbial growths were observed after 24 hours19.
Statistical Analysis
The results of chemical analysis were expressed as mean ± standard deviation of triplicate analyses. The results were analyzed by using SPSS version 18 (IBM Corporation, SPSS Inc., Chicago, IL, USA). To generate tables Microsoft word and Excel were used.
Result and Discussion
Macronutrient estimation
Macronutrients are important in order to body growth, maintenance and tissue rapier 20. Carbohydrate, protein and crude fiber content of microgreen, baby green and mature greens were measured. It was seen that macronutrient content increases when plant is mature (Fig 1).
Vitamin C and Beta carotene Estimation
Vitamins are organic substances that the body needs in little amounts for normal development and function. All bodily tissues need vitamin C, commonly known as ascorbic acid, to grow, develop, and heal. It plays a role in a variety of bodily processes, such as the production of collagen, iron absorption, healthy immune system operation, and wound healing. Naturally many foods contain vitamin A, a fat-soluble vitamin21. Our heart, lungs, and other organs function normally with the aid of vitamin A. The human body transforms beta carotene, which is a precursor to vitamin A, into vitamin A. Beta carotene and vitamin C was estimated in both of the greens22. Result showed beta carotene and vitamin C concentration was much higher in microgreens compared to the baby green and mature green. Microgreens contains almost double amount of beta carotene and vitamin C compared to mature greens (Table 1). Research data also showed that beta carotene and vitamin C content is higher in microgreen of celery & four Apiaceae species and compared to mature green 8,9.
Ash and mineral estimation
Ash content was estimated for all the stages of greens. It was found that mustard and coriander microgreens have highest ash content compared to bay and mature green, which clearly denotes that microgreens are good source of minerals.
Minerals are considered as essential as our need for oxygen to sustain life. Though needed in small amount but the activity of minerals ranges from bone development to proper brain function4. Almost all living things require iron because it is involved in a range of metabolic activities, such as the transfer of oxygen, the production of DNA, and the movement of electrons. Anemia, iron overload, and possibly neurological illnesses are only a few of the diverse clinical symptoms of disorders of iron metabolism, which are among the most prevalent diseases affecting people today 23. In addition to performing a variety of biological tasks in the human body, calcium is a micronutrient that is crucial for maintaining human health and wellbeing.
The contraction of muscles, the development of healthy bones and teeth, the transmission of nerve impulses, the regulation of heartbeat, and the fluid balance within cells all depend heavily on calcium. The most important times to meet these needs are during periods of growth, such as pregnancy, breast-feeding and childhood,. Long-term calcium insufficiency can cause osteoporosis, a condition where the bone deteriorates and fractures are more likely. The right nutrients can be obtained from a balanced diet, which can also help prevent calcium shortage24.
Figure 1: Macronutrient content of mustard and coriander green at different phases of development (micro, baby & mature green). [Values are mean ± SD]. |
Table 1: Amount of beta-carotene and Vitamin C in mustard and coriander green at different phases of development (micro, baby & mature green).
Mustard greens | Coriander greens | |||||
Parameters(mg/100g) | Micro green | Baby green | Mature green | Micro green | Baby green | Mature green |
Beta- carotene | 4.0 ± 0.7* | 3.4 ± 0.3 | 2.4 ± 0.5 | 6.7 ±0.6# | 4.7 ± 0.5 | 3.6 ± 0.7 |
Ascorbic Acid(Vitamin C) | 47.2± 3.9* | 28.5± 3.5 | 20.5 ± 1.7 | 48.3 ± 3.7# | 31.5± 4.1 | 22.2 ± 1.7 |
[Values are mean ± SD. *P< 0.05 vs Mature mustard green, #P< 0.05 vs Mature coriander green]
A mineral called phosphorus is found in many foods naturally and can also be taken as a supplement. It has a number of functions in the body. It is a crucial component of cell membranes, bones, and teeth. It maintains a normal range of blood pH and aids in the activation of enzymes. As a component of DNA, RNA, and ATP, the body’s primary energy source, phosphorus also plays a role in maintaining appropriate nerve and muscle function, particularly that of the heart. It also serves as a building block for our genes25.
The iron, calcium and phosphorus content were evaluated in mustard and coriander greens. The result showed mustard and coriander microgreens have highest amount of these three minerals followed by baby greens and mature greens. Iron content was double in microgreens compared to mature greens. Coriander microgreens contains higher amount of iron than mustard microgreens. Calcium content was also highest in microgreens however, mustard microgreens contain higher amount of calcium than coriander microgreens. Microgreens showed highest phosphorus content compared to baby greens and mature greens. Phosphorus content of mustard microgreen was much higher than coriander microgreen. (Table 2).
Compared to matured green, scientist demonstrated that microgreens of broccoli (Brassica oleracea L. var. italica Plenck), radish (Raphanus sativus L.) and green curly kale (Brassica oleracea var. sabellica L.) contains higher levels of total antioxidant capacity, total carotenoids, total isothiocyanates, total anthocyanins , macro- (K, Ca, Mg) and oligo-elements (Fe, Zn) 7. Again compared to matured green, macro- and microminerals like iron (Fe), copper (Cu), and manganese (Mn), sulfur (S), zinc (Zn), potassium (K), calcium (Ca), nitrogen (N), phosphorus (P), sodium (Na) levels were much higher in celery (Apium graveolens L.) microgreen8.
Table 2: Amount of iron, calcium and phosphorus in mustard and coriander green at different phases of development (micro, baby & mature green).
Mustard greens | Coriander greens | |||||
Parameters | Micro green | Baby green | Mature green | Micro green | Baby green | Mature green |
Iron(mg/100g) | 6.48 ± 1.0* | 4.19 ± 0.9 | 3.23 ± 0.8 | 8.72 ±1.2 # | 6.63 ± 0.7 | 4.53 ± 0.8 |
Calcium(mg/100g) | 263.6± 6.5* | 246.5± 4.3 | 204.6 ± 5.2 | 192.9 ± 5.8# | 178.8± 4.2 | 166.7 ± 4.9 |
Phosphorus(mg/100g) | 103.5 ±6.5* | 78.5 ± 3.4 | 70 ± 3.9 | 91.3 ± 5.7# | 78.2 ± 4.2 | 68.1 ± 3.6 |
Ash (%) | 1.86 ±0.28* | 1.74 ±0.21 | 1.67 ±0.11 | 1.58 ±0.11# | 1.34 ±0.09 | 0.96 ±0.21 |
[Values are mean ± SD. *P< 0.05 vs Mature mustard green, #P< 0.05 vs Mature coriander green]
Qualitative analysis of Phyto-chemical
Phytonutrients, sometimes referred to as phytochemicals, are substances derived from plants that have a positive impact on health and may be used to treat and even prevent a variety of ailments. Due to their positive impacts on human health and significant health benefits for consumers, phytochemicals are of great interest and have significant antioxidant potential. Consuming whole grains, fruits, and vegetables on a regular basis may lower your chance of developing a number of diseases associated with oxidative stress, according to epidemiological research and animal studies26, 27. In the current study it was observed that microgreens contain higher amount phenol, alkaloids, saponins, triterpens and saponin compared to baby and mature greens (Table 3). Except anti-oxidant property, phytochemical like saponin, phenol possess anti-bacterial properties 28. Scientists also demonstrated that minerals, total ascorbic acid, carotenoids, total chlorophylls, polyphenols, and antioxidant activity were much higher in the microgreen of four Apiaceae species[Pimpinella anisum L. (anise), Anthriscus cerefolium L. (chervil), Carum carvi L. (caraway), and Anethum graveolens L. (dill) ] compared to mature greens9.
Table 3: Phytochemical content of mustard and coriander green at different phases of development (micro, baby and mature green).
Mustard greens | Coriander greens | |||||
Parameters | Micro green | Baby green | Mature green | Micro green | Baby green |
Mature green |
Phenol | +++ | ++ | + | +++ | ++ | + |
Alkaloids | + | + | + | + | + | + |
Flavonoids | + | + | + | + | + | + |
Saponins | +++ | ++ | ++ | +++ | ++ | ++ |
Triterpenes | ++ | + | + | ++ | + | + |
Tannins | – | – | – | – | – | – |
+++: Strong, ++: moderate, + : Low; −: Not Detected
Quantitative analysis of total phenolic compound
In recent decades, the chemical molecules called polyphenols, which are widely present in plants, have attracted increasing attention in the field of nutrition. A rising number of studies suggests that consuming polyphenols may be essential for maintaining good health through controlling metabolism, weight, chronic disease, and cell proliferation. Although there are over 8,000 polyphenols, their short- and long-term health consequences have not yet been adequately described 29. Numerous polyphenols have antioxidant and anti-inflammatory characteristics, according to research in animals, people, and epidemiology. These properties may help prevent or treat obesity, cancer, neurological illnesses, and cardiovascular disease30, 31. In qualitative analysis it was found microgreens are rich source of phenolic compound. Quantitative analysis also showed high concentration of phenol in microgreens compared to baby green and mature greens. For mustard greens phenol content was higher compare to coriander greens. In case of coriander greens not much difference were seen in between micro green or baby green but when compared with mature greens it was seen that microgreens contains three times more phenol compared to mature greens ( Fig 2). Many experimental data showed that microgreens are rich in phenol and phyto-chemical compared to mature green 4,7,9.
DPPH free radical scavenging property
The body normally produces free radicals as a consequence of normal metabolism or when exposed to environmental pollutants like cigarette smoke and UV light. Free radicals are extremely reactive and unstable molecules. Free radicals can harm DNA, sometimes leading to mutations that can cause a number of diseases, such as cancer, inflammatory disease, and heart disease. By limiting the creation of radicals, scavenging them, or stimulating their breakdown, antioxidants reduce the risk of tissue damage caused by free radicals 32. Dietary antioxidants help disarm unstable molecules, lowering the chance of injury. In this present investigation, microgreens showed high anti-oxidant/ radical scavenging property compared to baby and mature green. Mustard microgreen shower higher radical scavenging property compared to coriander green. High concentration of phenol of the microgreen can be the most probable cause of the antioxidant property of these microgreens. (Table: 4) In this present investigation a strong co-relation was also observed between the antioxidant property and phenolic content of the greens (Mustard and coriander). The redox characteristics of phenolic compounds, which can be useful in quenching singlet and triplet oxygen or dissolving peroxides, are primarily responsible for the antioxidant action of these compounds.
Table 4: Anti oxidant property of mustard and coriander green at different phases of development (micro, baby & mature green).
DPPH Free Radical scavenging property [ mg TE/g] | ||
Mustard Green | Micro Green | 1.8 ± 0.6 * |
Baby Green | 1.5 ± 0.5 | |
Matured Green | 1.2 ± 0.5 | |
Coriander Green | Micro Green | 1.3 ± 0.6 # |
Baby Green | 1.0 ± 0.5 | |
Matured Green | 0.8 ± 0.4 |
[Values are mean ± SD. *P< 0.05 vs Mature mustard green, #P< 0.05 vs Mature coriander green]
Antimicrobial Activity
Mustard Greens & Coriander Greens showed anti-microbial property against two microbial strains: Bacillus subtilis (Gram positive bacterial strain) [MTCC No: 441], Escherichia coli [MTCC No: 1696] (Gram negative bacterial strain).Abundant growth ( but less than control) was observed in the plate treated with 25 mg, 50mg,75mg micro, baby and mature green, the plate with same doses of microgreen extract shows low growth as well as less colony count. But 100mg microgreen showed complete inhibition of the growth microorganisms, whereas baby green and mature green did not show complete inhibition. Hence it can be concluded that mustard microgreens showed strong anti-microbial activity against Bacillus subtilis &E. Coli compared to baby green and mature green (Table 5). Compared to mature greens red Spinach and kale microgreens also showed strong anti-microbial activity compared to mature greens 33.
In addition to their well-known antioxidant properties, several phenolic compounds may also have strong antibacterial properties. Phenols cause this anti-microbial activity by altering the permeability of cell membranes, altering various intracellular processes brought on by the phenolic compounds’ hydrogen bonding to enzymes, or altering the rigidity of the cell wall with integrity losses brought on by various interactions with the cell membrane34, 35. Contrarily, saponins severely injured bacteria by degrading their cell walls, causing the cytoplasmic membrane and membrane proteins to rupture, allowing cell contents to flow out and ultimately leading to cell death 35,36. Microgreens were shown to be abundant in phenol and saponin in this experiment, and they may be the most likely source of the anti-microbial activity.
Table 5: Colony count of Bacillus subtilis (A) and Escherichia coli (B). In presence or absence of mustard and coriander green (micro, baby & mature green).
A | Doses | 12.5 mg | 25 mg | 37.5 mg | 50 mg | Control |
MUSTARDGREEN (CFU/ml) | Micro Greens | 16.00×10ˆ5 | 12.30×10ˆ5 | 8.00×10ˆ5* | No growth detected | 31.25×10ˆ5 |
Baby Greens | 22.50×10ˆ5 | 22.00×10ˆ5 | 19.20×10ˆ | 12.60×10ˆ | ||
Mature Greens | 25.25×10ˆ5 | 23.25×10ˆ5 | 19.05×10ˆ | 14.25×10ˆ | ||
CORIENDRGREEN (CFU/ml) | Micro Greens | 12.5×10ˆ5 | 5.15×10ˆ5 | 2.6×10ˆ5 # | No growth detected | |
Baby Green | 21.50×10ˆ5 | 18.45×10ˆ5 | 15.00×10ˆ | 5.30×10ˆ5 | ||
Mature Greens | 25.00×10ˆ5 | 23.40×10ˆ5 | 17.75×10ˆ | 11.75×10ˆ | ||
B | Doses | 12.5 mg | 25 mg | 37.5 mg | 50 mg | Control |
MUSTARDGREEN (CFU/ml) | Micro Greens | 16.00×10ˆ5 | 12.30×10ˆ5 | 8.00×10ˆ5* | No growth detected | 31.25×10ˆ5 |
Baby Greens | 22.50×10ˆ5 | 22.00×10ˆ5 | 19.20×10ˆ | 12.60×10ˆ | ||
Mature Greens | 25.25×10ˆ5 | 23.25×10ˆ5 | 19.05×10ˆ | 14.25×10ˆ | ||
CORIENDRGREEN (CFU/ml) | Micro Greens | 12.5×10ˆ5 | 5.15×10ˆ5 | 2.6×10ˆ5 # | No growth detected | |
Baby Green | 21.50×10ˆ5 | 18.45×10ˆ5 | 15.00×10ˆ | 5.30×10ˆ5 | ||
Mature Greens | 25.00×10ˆ5 | 23.40×10ˆ5 | 17.75×10ˆ | 11.75×10ˆ |
[*P< 0.05 vs Mature mustard green, #P< 0.05 vs Mature coriander green]
Conclusion
Despite the use of methods to combat micronutrient deficiency, developing nations have made only modest progress. Supplementation and food fortification are the most traditional and often used methods of treating micronutrient deficiency. However, due of food insecurity, these measures may not be the most acceptable, accessible, or useful for rural and/or impoverished households, and they may not address the root cause of poor micronutrient status and inadequate dietary intake. In these situations, complementary initiatives are required to assist dietary adjustment that is culturally relevant and agriculture-based interventions.
Microgreens are renowned now for their high nutritional content, simple cultivation, and delicate flavor in a wide range of meals around the globe. People are using various kinds of microgreens in their diets in various nations throughout the world. Mustard (Brassica nigra) and coriander (Corindrum sativum) greens are very common in India and can grow in Indian climate. People of both urban and rural population can afford and grow these and can get the nutritional benefits.
In this present investigation, it was found that microgreens (mustard and coriander) are rich in vitamin C, beta-carotene and minerals (iron, calcium and phosphorus) compared to baby and mature greens. Microgreens also possess strong anti-oxidant and anti- microbial property compared to adult and baby greens. High concentration of polyphenols in the microgreens is the probable cause of the strong antioxidant and anti-microbial property of the microgreens. So, it can be concluded that microgreens (mustard and coriander) are not only rich in nutrients and phytochemical, they also possess strong ant-oxidant and anti-microbial property. Microgreens are a potential treatment for micronutrient deficiencies due to their high nutrient content, which also gives them an appealing look, tender and crispy texture, powerful flavor, and nice taste. Microgreens are a rich source of polyphenols that can help prevent numerous diseases, such as cancer, cardiovascular disease (CVD), and neurological illnesses. So, including microgreens in our diet on a regular basis helps prevent and treat numerous ailments as well as fight malnutrition. The urban and rural populations will benefit from education and training programmers regarding the nutritional advantages of microgreens as well as the growing, harvesting, and handling conditions of the microgreens.
Acknowledgement
This work is completely supported by J.D. Birla Institute, Kolkata, India.
Conflict of Interest
The authors declare no conflict of interests.
Funding Sources
There are no funding sources.
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