阅读说明：本技术 用于制备富含异硫氰酸酯和多酚的原料的方法 (Process for preparing a feedstock rich in isothiocyanates and polyphenols ) 是由 G·艾伯特 V·埃斯蒂加里维亚斯基尼 M·纳赖斯尼 A·帕蒂尼 C·皮图埃洛 C·波沃洛 于 2019-07-26 设计创作，主要内容包括：本发明涉及通过无土栽培从种子制备辣木属(辣木)芽苗的方法。本发明涉及从通过本发明方法从种子获得的辣木属(辣木)芽苗开始和/或从成年植物制备富含异硫氰酸酯和多酚的原料的方法,并且涉及通过所述方法获得的原料。(The present invention relates to a method for preparing moringa (moringa) sprouts from seeds by soilless culture. The present invention relates to a process for the preparation of a feedstock enriched in isothiocyanates and polyphenols starting from moringa (moringa) sprouts obtained from seeds by the process of the invention and/or from adult plants, and to the feedstock obtained by said process.)

1. A method for preparing moringa sprouts (moringa), comprising the steps of:

a) selecting Moringa seeds;

b) seed preparation: optionally peeling the seed; washing and disinfecting the seeds;

c) germinating;

d) growing under controlled soilless conditions;

e) the aerial parts as well as the residues of the seeds and roots are harvested.

2. The method according to claim 1, wherein the disinfection of step b) is performed by placing the seeds in a disinfectant solution selected from the group consisting of an aqueous solution of calcium hydroxide or sodium hypochlorite or an aqueous solution of a glycerol steep comprising citronella leaves.

3. The method as set forth in claim 2, wherein the disinfectant solution is an aqueous solution containing 30 to 60g/L of calcium hydroxide or an aqueous solution containing 0.045 to 0.55mL/L of sodium hypochlorite or an aqueous solution containing 100-300mL/L of glycerol macerate of citronella leaves.

4. A method according to any one of claims 1-3, wherein the disinfection of step b) is performed by placing the seeds in a disinfectant solution, if disinfected with an aqueous calcium hydroxide solution, for a time period in the range of 8-12 hours; or if sodium hypochlorite or an aqueous solution of a glycerol impregnate of citronella leaves is used for disinfection, for a period of time in the range of 20-30 minutes.

5. The method according to any one of claims 1-4, wherein in step c) the germination temperature ranges from 23 ℃ to 32 ℃, and preferably 26 ℃.

6. The method according to any one of claims 1-5, wherein in step c) the germination moisture range is 60% -90%, and preferably 75%.

7. The method according to any one of claims 1 to 6, wherein in step d) the growth temperature is in the range of 23 ℃ to 32 ℃ and preferably 28 ℃.

8. The method according to any one of claims 1 to 7, wherein in step d) the growth humidity is in the range of 60% to 90%, and preferably 75%.

9. Method for preparing a feedstock starting from a sprout, optionally with residues of seeds and roots and/or from a sprout harvested from an adult plant of moringa oleifera obtained by a method according to any one of claims 1 to 8, comprising the following steps:

f) washing the aerial parts obtained in step e) and optionally disinfecting the seeds and root residues obtained in step e), and/or II washing the aerial parts harvested from adult plants,

g) extracting the above-ground part by a spiral extractor to obtain solid and liquid;

h) homogenizing:

I. the solids and liquids obtained in step g), and optionally separate seed and root residues, to obtain one or two homogeneous purees; or:

combining the solids and liquids obtained in step g) and the seed and root residues to obtain a single homogeneous paste;

i) removing water from the mash obtained in step h) by drying or freeze-drying;

j) and (6) grinding.

10. The method according to claim 9, wherein the disinfecting of step f) is performed using a disinfectant solution selected from the group consisting of an aqueous solution of calcium hydroxide or sodium hypochlorite or an aqueous solution of a glycerol steep comprising citronella leaves.

11. The method as set forth in claim 10, wherein the disinfectant solution is an aqueous solution comprising 30-60g/L of calcium hydroxide or an aqueous solution comprising 0.045-0.55mL/L of sodium hypochlorite or an aqueous solution comprising 100-300mL/L of glycerol macerate of citronella leaves.

12. A method according to any one of claims 9-10, wherein the disinfection of step b) is performed by placing the seeds in a disinfectant solution for a time in the range of 8-12 hours if disinfection is performed using an aqueous solution of calcium hydroxide or for a time in the range of 20-30 minutes if disinfection is performed using an aqueous solution of sodium hypochlorite or a glycerol steep of citronella leaves.

13. A feedstock obtained from moringa sprouts (moringa) according to the method of any one of claims 9 to 12.

Technical Field

The present invention relates to a method for preparing Moringa (Moringa oleifera) sprouts grown from seeds, and a method for preparing a raw material rich in Isothiocyanates (ITCs) and Polyphenols (PFs) obtained from seeds and/or sprouts harvested from adult plants.

Prior Art

It is known that companies working in the nutrition industry strive to use high quality raw materials, as indicated by the type of cultivation (organic) and the active substance content.

In recent years, the use of moringa in nutraceuticals and cosmetic formulations has increased, almost exclusively with respect to the use of leaves. From a nutritional point of view, moringa leaves are very interesting due to their content of proteins (about 27% w/w on dry matter), essential amino acids, vitamins (vitamin a, carotenoids and vitamin C with provitamin a potential), minerals (including sodium, potassium, phosphorus, calcium and iron) and PF with antioxidant effect. ITCs and their precursor glucosinolates (glucosinolates) are present in leaves, but in moderate amounts compared to other parts of the plant. The seed is the most abundant part of the plant glucosinolate, but is also the least PF-rich part.

Antioxidants can be classified as direct antioxidants or indirect antioxidants depending on their mechanism of action on free radicals. PF, which is a direct antioxidant, reacts directly with the reactive radical species. In contrast, it has recently been shown that ITCs (Tumer et al, 2015) have an indirect antioxidant effect, i.e. they contribute to the body's operation of protecting against oxidative damage, although they do not act directly on the active free radical species.

Typically, ITCs are derived from glycosylated precursors called glucosinolates through reactions mediated by myrosinase. Glucosinolates are typical compounds from plants of the Brassicaceae family (Brassicaceae), belonging to the Cappariales order (Capparales), including Moringa oleifera. Also known as sulfated glycosides or thioglycosides, they are a group of glycosides consisting of a sugar moiety bonded through a sulfur atom to an aglycone moiety derived from an amino acid such as methionine, phenylalanine, tyrosine and tryptophan. Glucosinolates are chemically stable and biologically inactive as long as they remain silently within the subcellular compartments of plant tissues. In contrast, due to tissue damage (caused by parasites or other factors that cause tissue tearing), the glycoside comes into contact with myrosinase, thereby activating an enzymatic hydrolysis process of glucosinolates, in which the β -thioglycosidic bonds are broken and unstable intermediates are formed, thereby forming nitrogen or sulfur-nitrogen containing molecules, such as nitriles, Thiocyanates (TC) and ITC. These degradation products are characterized by bitter and characteristic pungent tastes and are appreciated in, for example, sauces and dishes based on mustard, horseradish and green mustard (wasabi) products. In addition to characteristic organoleptic properties, which have been well known for a long time, ITCs have been the subject of numerous studies over the years which have demonstrated their anti-inflammatory, antimicrobial, anti-cancer and antioxidant properties.

Another method of converting glucosinolates to TC and ITC is related to the gut flora, where myrosinase, specific for certain microorganisms, can achieve the same reaction; however, the percentage conversion to isothiocyanate is uncertain. Therefore, for health purposes, it is preferred to take ITC directly as the active molecule rather than glucosinolates.

Scheme 1 shows the structures of glucosinolates and the corresponding isothiocyanates of moringa oleifera.

In particular, the major glucosinolate of the moringa genus is 4- (α -L-rhamnopyranosyloxy) -benzyl glucosinolate (glucomoringin or GM) (compound 1 in scheme 1), which is present in all parts of the plant at different concentrations (Bennet et al, 2003).

In addition, three acetyl isomers of GM (compounds 2, 3 and 4 in scheme 1) are present in certain parts of the plant. ITCs of glucomoringin (called glucomoringin isothiocyanate (GM-ITC, compound 5 in scheme 1) and glucomoringin acetylate isomer at the 4' position of rhamnose (compound 8 in scheme 1) have an indirect antioxidant activity comparable to sulforaphane, a characteristic ITC of broccoli.

Compounds 6 and 7 (scheme 1) are the other two of the three acetylated isomers of glucomoringin.

Scheme 1

Summary of The Invention

The present invention relates to a method for preparing moringa (moringa) sprouts from seeds, comprising the steps of:

a) selecting Moringa seeds;

b) preparing seeds: optionally peeling the seeds; washing and disinfecting the seeds;

c) germinating;

d) growing under controlled contamination-free conditions;

e) the aerial parts as well as the seed and root residues were harvested.

The present invention also relates to a method for preparing a feedstock from a sprout obtained by the above method and/or a sprout harvested from an adult plant of moringa oleifera, the method comprising the steps of:

f) washing the aerial parts of the sprouts obtained in step e) and optionally disinfecting the seed and root residues obtained in step e), and/or II washing the aerial parts of the sprouts harvested from adult plants,

g) extracting the aerial parts with a spiral extractor to obtain solid and liquid,

h) homogenizing:

I. the solids and liquids obtained in step g), and optionally separate seed and root residues, to obtain one or two homogeneous purees; or

Combining the solids and liquids obtained in step g) and the seed and root residues to obtain a single homogeneous paste;

i) removing water from the mash obtained in step h) by drying or freeze-drying,

j) grinding;

and the invention also relates to a feedstock obtainable by said method from moringa (moringa) sprouts.

Brief Description of Drawings

FIG. 1 shows a protocol for the preparation of Moringa (Moringa) sprouts from seeds and the feedstock available from the sprouts.

Figure 2 shows a structure comprising a germination tray, in front view.

Fig. 3 shows a sectional view, side view, of a structure comprising a germinating tray.

Detailed Description

The object of the present invention is a method for the preparation of moringa (moringa) seedlings starting from moringa seeds by soilless culture.

According to an embodiment of the present invention, the seedling is obtained by cultivating Moringa seed without using soil and nutrient solution.

Another object of the invention is a process for preparing a feedstock enriched in Isothiocyanates (ITCs) of known anti-inflammatory, antibacterial and anticancer properties and Polyphenols (PFs) mainly known to have an antioxidant effect, starting from moringa (moringa) sprouts grown from seeds by the process of the invention, and/or from sprouts harvested from moringa adult plants (for example directly harvested in the field by cutting the apical part of the shoot consisting of unfolded and young leaves).

Sprouts prepared according to the invention are capable of producing feedstock with high ITC and PF content, thanks to the two properties conferred by the molecular species.

The raw material, as such or after successive extraction steps, yields a more concentrated extract, used in the nutraceutical and cosmetology industries, in a form (solid or liquid) suitable for a particular field of application.

A method for preparing moringa (moringa) sprouts from seeds comprising the steps of:

a) selecting Moringa seeds;

b) preparing seeds: optionally peeling the seeds; washing and disinfecting the seeds;

c) germinating;

d) growing under controlled contamination-free conditions;

e) the aerial parts (sprouts) as well as the seed and root residues are harvested.

In step a), seeds may be selected by discarding broken, discolored, moldy or damaged seeds.

In the seed preparation step b), the seeds may optionally be dehulled manually or by means of a dehuller, after which the seeds (optionally dehulled) are washed, preferably overnight, by placing them in a water bath and then rinsing them; the seeds are then disinfected by placing them in a disinfectant solution, preferably an aqueous solution of calcium hydroxide or sodium hypochlorite, or an aqueous solution of the glycerol impregnate of the citronella leaves, more preferably an aqueous solution comprising 30-60g/L calcium hydroxide or an aqueous solution comprising 0.045-0.55mL/L sodium hypochlorite or an aqueous solution comprising 100-300mL/L of the glycerol impregnate of citronella leaves obtained by methods known in the art.

If an aqueous solution of calcium hydroxide is used for the disinfection, the disinfection time preferably ranges from 8 to 12 hours; or if the disinfection is carried out using an aqueous solution of sodium hypochlorite or an aqueous solution of glycerol-macerate of citronella leaves, the disinfection time ranges from 20 to 30 minutes.

After sterilization, the seeds may be rinsed, preferably 3 times, to remove excess disinfectant solution.

Then carrying out germination (step c)); the seeds may be placed in a capped container in a dark germination chamber and maintained under controlled temperature and humidity for a time required for sufficient germination, preferably 3-5 days, to obtain germinated seeds.

The germination temperature is preferably in the range of 23 ℃ to 32 ℃ and more preferably up to 26 ℃.

Germination moisture preferably ranges from 60% to 90%, and more preferably up to 75%.

In step d), germinating seeds are subjected to controlled soilless stripAnd (4) growing under the condition of a workpiece. For example, germinated seeds are transferred to perforated trays and placed in a greenhouse with controlled environmental conditions (e.g., temperature, humidity, and light). The temperature preferably ranges from 23 ℃ to 32 ℃ and more preferably up to 28 ℃. Watering the sprouts by spraying water; the humidity preferably ranges from 60% to 90%, and more preferably 75%. The intensity of the applied light is preferably in the range of 100-^-2s^-1。

The sprouts are then harvested by cutting over the seeds in order to separate the aerial parts from the parts comprising seeds and roots (step e)).

From the aerial parts (sprouts) thus obtained in step e) as well as the seed and root residues, the starting material can be prepared by a method according to the invention comprising the following steps. According to another embodiment, the feedstock can be prepared from sprouts harvested from adult plants of moringa oleifera, either alone or in combination with aerial parts (sprouts) grown from seeds by the methods of the present invention, as well as seed and root residues.

The method for preparing a feedstock starting from a sprout thus obtained by the above method, optionally with seed and root residues and/or with a sprout harvested from an adult plant of moringa oleifera, comprises the following steps:

f) washing the aerial parts of the sprouts obtained in step e) and optionally disinfecting the seeds and root residues obtained in step e), and/or II washing the aerial parts harvested from adult plants,

g) extracting the aerial parts with a spiral extractor to obtain solid and liquid,

h) homogenizing:

I. the solids and liquids obtained in step g), and optionally separate seed and root residues, to obtain one or two homogeneous purees; or:

combining the solids and liquids obtained in step g) and the seed and root residues to obtain a single homogeneous paste;

i) removing water by drying or freeze-drying;

j) and (6) grinding.

In step f), the aerial parts of the sprouts obtained from the seeds and/or harvested from the adult plants by the method of the invention are washed with water, while the separately harvested seeds and root residues are disinfected with a disinfectant solution, preferably an aqueous solution of calcium hydroxide or sodium hypochlorite, or more preferably an aqueous solution comprising 30-60g/L calcium hydroxide or an aqueous solution comprising 0.045-0.55mL/L sodium hypochlorite. Alternatively, the sterilization may be performed with an aqueous solution of a glycerol-macerate of citronella, preferably an aqueous solution containing 100 and 300mL/L of a glycerol-macerate of citronella leaves obtained by a method known in the art. Preferably, if the calcium hydroxide aqueous solution is used for sterilization, the sterilization time ranges from 8 to 12 hours; or if the disinfection is carried out using an aqueous solution of sodium hypochlorite or an aqueous solution of glycerol-macerate of citronella leaves, the disinfection time ranges from 20 to 30 minutes.

The seeds are then rinsed with water, preferably 3 times, to remove the disinfectant solution and obtain the biomass.

In step g), the aerial part is introduced into a screw-type cold-extracted juice extractor (speed: 60-75rpm) to separate the solid from the liquid product.

In step h) I, the biomass is subjected to a mechanical homogenization step. Homogenizing the solid and liquid products from step g) and the separate seed and root residues to obtain two separate homogeneous sludges (step h) I).

Optionally, co-homogenizing the solid and liquid products from step g) and the seed and root residues to obtain a homogeneous paste (step h) II).

Water is removed from the homogeneous slurry by drying at a temperature preferably in the range of 40 ℃ to 60 ℃, for example using a fan oven or freeze drying (step i)).

Finally, the dried or freeze-dried product obtained in step i) is milled, for example using a blade mill, to obtain the desired feedstock (step j)).

According to one embodiment, the method for preparing a feedstock starting from a sprout thus obtained by the above method, optionally with seed and root residues, comprises the following steps:

f) washing the aerial parts of the sprouts obtained in step e) and disinfecting the seeds and root residues obtained in step e),

g) extracting the aerial parts with a spiral extractor to obtain solid and liquid,

h) homogenizing:

I. the solids and liquids obtained in step g), and optionally separate seed and root residues, to obtain one or two homogeneous purees; or;

combining the solids and liquids obtained in step g) and the seed and root residues to obtain a single homogeneous paste;

i) removing water by drying or freeze-drying;

j) and (6) grinding.

According to another embodiment, the method for preparing a feedstock from sprouts harvested from adult plants of moringa oleifera and sprouts obtained from seeds by the above method, optionally with seed and root residues, comprises the following steps:

f) washing the aerial parts obtained from the sprouts harvested from the adult plants of Moringa oleifera and the sprouts obtained in step e), and optionally disinfecting the seeds and root residues obtained in step e),

g) extracting the aerial parts with a spiral extractor to obtain solid and liquid,

h) homogenizing:

I. the solids and liquids obtained in step g), and optionally separate seed and root residues, to obtain one or two homogeneous purees; or:

combining the solids and liquids obtained in step g) and the seed and root residues to obtain a single homogeneous paste;

i) removing water by drying or freeze-drying;

j) and (6) grinding.

According to another embodiment, the method for preparing a feedstock starting from a sprout harvested from an adult plant of moringa oleifera comprises the following steps:

f) washing aerial parts obtained from sprouts harvested from adult plants of moringa oleifera,

g) extracting the aerial parts with a spiral extractor to obtain solid and liquid,

h) homogenizing:

I. the solid and liquid obtained in step g),

i) removing water by drying or freeze-drying;

j) and (6) grinding.

Another object of the present invention is a material obtained from Moringa sprouts by the above method.

The following examples further illustrate the invention.

Examples

Example 1-preparation of two different freeze-dried products derived from aerial parts obtained from unpeeled seeds and from seed and root residues

Seeds were visually selected and broken, discolored, moldy or damaged seeds were discarded (step a)).

The seeds were then soaked in a water bath for 8 hours. The seeds were then rinsed 3 times and then sterilized in a disinfectant solution containing 0.45mL/L sodium hypochlorite for 30 minutes. After disinfection, the seeds were rinsed 3 times to remove excess disinfectant solution (step b)).

Germination (step c)) is then carried out by placing the seeds in a capped container in a dark germination chamber at a temperature of 26 ℃ and a humidity of 80% for 5 days until the seeds germinate.

In step d), the germinated seeds were transferred to a perforated tray measuring 45cm x 30cm (1200 seeds/tray) and placed in a greenhouse with an average temperature of 29 ℃ and a humidity of 80%. Growth continued for 15 days. The sprouts are then harvested by cutting over the seeds (step e)) in order to separate the aerial parts from the parts comprising seeds and roots. The fresh weight of the aerial parts produced in each tray was 1.7 times the dry weight of the seeds to be germinated, while the fresh weight of the seeds and roots remaining after the treatment was 3.6 times the dry weight of the seeds to be germinated.

The aerial parts of the sprouts were washed with water, then the seeds and root residues were sterilized in a disinfectant solution containing 0.45mL/L of sodium hypochlorite for 30 minutes (step f)), and then rinsed with water to remove the disinfectant solution and obtain biomass.

The aerial parts of the sprouts were subjected to a mechanical extraction step (step g)) using a screw extractor operating under cold conditions (room temperature) and low speed (60 rpm). The juice obtained weighed 0.81 times the weight of the biomass processed, while the solids weighed 0.12 times the weight of the biomass.

The solid and liquid products obtained from the aerial parts are then combined and mixed in a submerged mixer to obtain a homogeneous mash. The same procedure (step h) I.) was performed on the seed and root residues.

The two sludges obtained were separately freeze-dried to remove water, to obtain a stable, storable material (step i)). The freeze-dried product derived from the aerial parts was 0.08 times the weight of the biomass subjected to freeze-drying, while the freeze-dried product derived from the seed and root residues was 0.21 times the weight of the biomass subjected to freeze-drying. The freeze-dried product is removed from the freeze-dryer tray and then ground with a leaf mill to obtain a powder (step j)), which is suitably packaged. The resulting powder constitutes the raw material obtained from the Moringa sprouts forming the object of the present invention.

Example 2 preparation of a lyophilized product derived from aerial parts and seed and root residues obtained from dehulled seeds

Seeds were visually selected and broken, discolored, moldy or damaged seeds were discarded (step a)).

Peeling the seeds by a peeling machine, and then soaking the seeds in a water bath for 8 hours; the seeds were then rinsed 3 times and then sterilized in a disinfectant solution containing 0.45mL/L sodium hypochlorite for 30 minutes. After disinfection, the seeds were rinsed 3 times to remove excess disinfectant solution (step b)).

Germination (step c)) is then carried out by placing the seeds in a capped container in a dark germination chamber at a temperature of 26 ℃ and a humidity of 80% for 5 days until the seeds germinate.

In step d), the germinated seeds were transferred to a perforated tray measuring 45cm x 30cm (3000 seeds/tray) and placed in a greenhouse with an average temperature of 29 ℃ and a humidity of 80%. Growth continued for 15 days. The sprouts are then harvested by cutting over the seeds (step e)) in order to separate the aerial parts from the parts comprising seeds and roots. The fresh weight of the aerial parts produced in each tray was 2.0 times the dry weight of the seeds to be germinated, while the fresh weight of the seeds and roots remaining after the treatment was 3.2 times the dry weight of the seeds to be germinated.

The above-ground parts of the sprouts were washed with water while the seeds and root residues were sterilized in a disinfectant solution containing 0.45mL/L of sodium hypochlorite for 30 minutes to sterilize the seeds and root residues (step f)), and then washed with water to eliminate the disinfectant solution and obtain biomass.

The aerial parts of the sprouts were subjected to a mechanical extraction step (step g)) using a screw extractor operating at cold (room temperature) and low speed (60 rpm). The weight of the juice obtained was 0.81 times the weight of the biomass, while the weight of the solids was 0.12 times the weight of the biomass.

The solid and liquid products obtained from the aerial parts and the seed and root residues are then combined and mixed in a submerged mixer to obtain a homogeneous paste (step h) II).

The obtained sludge is freeze-dried to remove water to obtain a stable, storable mass (step i)). The freeze-dried product, which was 0.10 times the weight of the biomass subjected to freeze-drying, was taken out of the freeze-dryer tray and then ground with a blade mill to obtain a powder (step j)), which was appropriately packaged. The resulting powder constitutes the raw material obtained from the Moringa sprouts forming the object of the present invention.

Example 3-preparation of isothiocyanate and polyphenol rich feedstock from Moringa oleifera sprouts grown in a controlled environment

As reported in the detailed description above, moringa sprouts were grown in a greenhouse with controlled environmental parameters (e.g., temperature, humidity, and light).

In particular, the greenhouse has a length of 18m, a width of 4m and a maximum height of 4 m. Two structures in the greenhouse were used to house seed germination trays (fig. 1 and 2), having a length of 16m, a width of 0.7m and a height of 1.8m, and divided into 3 shelves, each having a height of 0.6 m. Each tray was 0.45m long and 0.30m wide. Each structure contained 192 trays, giving a total capacity of 384 trays for the greenhouse.

Seeds are selected by discarding broken, discolored, moldy and/or damaged seeds. 360g of such seeds were placed in a water bath overnight in advance, rinsed, and then sterilized with an aqueous solution containing 0.45mL/L of sodium hypochlorite for 30 minutes, and then placed in each tray. Alternatively, 500g of peeled seeds may be used per tray, which seeds are placed in a water bath overnight, rinsed and then sterilized with an aqueous solution containing 0.45mL/L sodium hypochlorite for 30 minutes.

The preparation period required 5 days of seed germination and 15 days of sprout growth for a total of 20 days, i.e., 16 preparation periods per year. Half of the trays in the greenhouse are filled with unpeeled seeds and the rest are peeled seeds. At the end of each production cycle, sprouts are harvested by cutting over the seeds to separate the aerial parts from the parts containing the seeds and roots. The aerial parts of the sprouts were washed with water while the seeds and root residues were placed in a disinfectant solution containing 0.45mL/L sodium hypochlorite for 30 minutes to disinfect them, followed by rinsing.

1800Kg of aerial parts and 3900Kg of seed and root residue were obtained each year from unpeeled seeds. The aerial parts of the sprouts were subjected to a mechanical extraction step using a screw extractor (60rpm) to obtain a juice and a solid residue, which were combined and mixed to obtain a homogeneous puree. The same procedure was performed for seed and root residue. The two purees obtained were then freeze dried, with 150Kg of freeze dried product being produced annually from the aerial parts and 800Kg of freeze dried product being produced annually from the seed and root residues.

3000Kg of aerial parts and 4900Kg of seed and root residue were obtained from dehulled seeds each year. The aerial parts of the sprouts were subjected to a mechanical extraction step using a screw extractor (60rpm) to obtain a juice and a solid residue, which were combined and mixed with the seed and root residue to obtain a homogeneous puree. The slurry was freeze-dried to obtain 790Kg of freeze-dried product annually.

Reference to the literature

Tumer，T.B.，Rojas-Silva，P.，Poulev，A.，Raskin，I.，&Waterman C.(2015).Direct and Indirect antioxidant activity of Polyphenol-and Isothiocyanate-Enriched Fractions from Moringa oleifera.J.Agric.Food.Chem.，63，1505-1513.

Bennett，N.R.，Mellon，F.A.，Foidl，N.，Pratt，J.H.，Dupont，M.S.，Perkins，L.，&Kroon，P.A.(2003).Profiling Glucosinolates and Phenolics in Vegetative and Reproductive Tissues of the Multi-Purpose Trees Moringa oleifera L.(Horseradish Tree)and Moringa stenopetala L.J.Agric.Food Chem.，51，3546-3553.