WO2020020182A1

WO2020020182A1 - Functional plant salt, preparation method therefor and use thereof

Info

Publication number: WO2020020182A1
Application number: PCT/CN2019/097357
Authority: WO
Inventors: 张英; 陈亮; 周沫希; 严雅丽; 黄骆镰
Original assignee: 杭州尤美特科技有限公司
Priority date: 2018-07-23
Filing date: 2019-07-23
Publication date: 2020-01-30
Also published as: KR20210061998A; KR20210064187A; WO2020020183A1; CN112654259A

Abstract

Disclosed is a functional plant salt and a preparation method therefor, the method involving uniformly mixing different plant extract powders and table salt at a certain ratio, and then baking same at a high temperature of 800-1400°C in one batch or in several batches to form a functional plant salt having different colors, spatial structures, physical and chemical properties, flavors and uses.

Description

Functional plant salt and preparation method and application thereof

Technical field

The invention relates to the technical field of food and health food, in particular to a functional plant salt and a preparation method and use thereof, and more particularly to a non-bamboo plant salt and a preparation method and use thereof.

Background technique

Plant salt refers to a kind of balanced salt extracted from plant organisms, using pure physical processes and processes, conforming to low sodium salts and a variety of mineral trace element groups, and various element proportions meeting the requirements of the human body. , A new type of edible salt with a certain promoting effect on function regulation and metabolism and health.

The main characteristics of plant salt: ① Plants are the main source; ② Natural low sodium salt and natural balanced salt; ③ Rich in various organic nutrients and biologically active ingredients; ④ No chemical synthetic substances are added during processing and production; ⑤ A variety of diseases and related complications caused by the lack or imbalance of mineral element groups have certain adjuvant treatment and regulating effects. Such as sodium-sensitive hypertension, type 2 diabetes, hyperlipidemia, cardiovascular disease, tumors and immune dysfunction and other diseases and complications have a clear effect.

The concept of plant salt (Plant-Salt) was first proposed by Professor Pan Hanjie, Dean of the Hong Kong Institute of Preventive Medicine, and it has been continuously improved and developed.

Professor Pan Hanjie pointed out that the efficacy of plant salt is closely related to the selection of raw materials, the activity of cultivating soil and watering sources. The plant salt project has just begun in China and has a very bright future.

Professor Pan Hanjie emphasized that the biological activity of plant salts depends on the selection of plant species and the combination of varieties of raw materials, the number of types of inorganic salts they contain, the content and proportion of elements, and the biologically active ingredients related to plants; plant salts It is mainly aimed at people who need a low-sodium diet, and people who have a disordered or impaired function due to imbalance or lack of trace elements in the body.

Summary of the Invention

The technical problem to be solved by the present invention is to provide a functional plant salt and a method for preparing the functional plant salt.

In the present invention, the functional plant salt is a non-bamboo plant salt, which refers to a product prepared by using a non-bamboo extract as a plant-based raw material.

According to a first aspect of the present invention, a functional plant salt is provided. The functional plant salt is prepared by mixing one or more plant extract powders with fine salt in an amount of 1% to 40%. Uniform, roasted once or in multiples at a high temperature of 800-1400 ° C to obtain a functional plant salt.

In another preferred example, the plant extract is an extract of a substance selected from the group consisting of plum, pine, tea, lotus, chrysanthemum, pomegranate, begonia, edible fungus, algae.

In another preferred example, the plant extract is a plum extract and / or a pine extract.

In another preferred example, the plum extract is selected from the group consisting of plum blossom extract, plum fruit extract, plum leaf extract, plum branch extract, plum root extract, or a combination thereof; and / or

The pine extract is selected from the group consisting of pine needle extract, pine bark extract, pine pollen extract, or a combination thereof.

In another preferred example, the fine salt is selected from the group consisting of sea salt, lake salt, well salt, and mineral salt.

In another preferred example, the fine salt is crude sea salt.

In another preferred example, the functional plant salt is pine salt and / or plum salt.

In another preferred example, the plant extract further comprises a bamboo extract.

In another preferred example, the fine salt is common salt.

In another preferred example, the ΔL value of the functional plant salt is 28-60, preferably 30-55, and more preferably 32-50.

In another preferred example, the ΔL value of the functional plant salt is 40-60, preferably 42-55.

According to a second aspect of the present invention, there is provided a method for preparing a functional plant salt according to the first aspect of the present invention, comprising the steps of: adding one or more plant extract powders in an amount of 1% to 40% and Fine salt is mixed uniformly, and it is roasted once or in multiples at a high temperature of 800-1400 ° C to obtain a functional plant salt.

In another preferred example, the roasting is performed in a mechanized oven.

In another preferred example, the roasting is performed in an intermediate frequency melting furnace.

According to a third aspect of the present invention, there is provided a food or pharmaceutical composition comprising one or more functional plant salts according to the first aspect of the present invention.

According to a fourth aspect of the present invention, there is provided the use of the functional plant salt according to the first aspect of the present invention, for preparing a substance selected from the group consisting of a pharmaceutical auxiliary, a health food / drink, and a functional food / drink , Table seasoning salt, cooking salt, special purpose cosmetics or personal care products.

According to a fifth aspect of the present invention, there is provided a method for inhibiting transaminase activity, comprising the step of applying one or more inhibitory effective amounts of the functional plant salt according to the first aspect of the present invention to a desired patient.

In another preferred example, the aminotransferase is selected from the group consisting of aspartate aminotransferase (ALT) and glutamic acid aminotransferase (AST).

It should be understood that, within the scope of the present invention, the above technical features of the present invention and the technical features specifically described in the following (such as the embodiments) can be combined with each other to form a new or preferred technical solution. Due to space limitations, I will not repeat them here.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a photograph of the pine salt obtained in Example 4. FIG.

FIG. 2 is a photograph of bamboo salt obtained in Example 5. FIG.

FIG. 3 is a photograph of plum salt obtained in Example 6. FIG.

FIG. 4 is a photograph of the pine salt obtained in Example 7. FIG.

FIG. 5 is a photograph of bamboo salt obtained in Example 8. FIG.

FIG. 6 is a photograph of plum salt obtained in Example 9. FIG.

FIG. 7 is a photograph of plant salts obtained under different formulations and different process parameters.

Figure 8 is a micrograph of different salts.

Figure 9 is the SEM results of different salts.

Figure 10 is the TEM results of different salts.

Figure 11 is the XRD results of different salts.

Figure 12 shows the results of the electronic tongue test for different salts.

Figure 13 shows the results of electronic nose tests for different salts.

FIG. 14 is a morphological observation result of pathological sections of liver tissue of mice in each group.

Figure 15 shows the inhibitory effect of different concentrations of salt solution on tyrosinase (monophenolase) in vitro. ** indicates that compared with the original salt, there is a very significant difference in the experimental group (p <0.01), n = 3.

Figure 16 shows the inhibitory effect of different concentrations of salt solution on tyrosinase (diphenolase) in vitro. ** indicates that compared with the original salt, there is a very significant difference in the experimental group (p <0.01), n = 3.

Figure 17 is the effect of 0.5% mass fraction of each sample on the migration of B16 cells, a-normal; b-original salt; c-arbutin; d-pine salt; e-bamboo salt; f-plum salt.

Figure 18 shows the effect of 0.5% mass fraction of each sample on the B16 cell cycle, a-normal; b-raw salt; c-arbutin; d-pine salt; e-bamboo salt; f-plum salt.

FIG. 19 is a graph showing changes in body weight of experimental animals in 6.3.1.

Figure 20 shows the changes in blood pressure in experimental rats in 6.3.2.

detailed description

After a long and in-depth study, the inventors have adopted a mixture of non-bamboo non-bamboo extracts (such as plum extract and / or pine extract, etc.) and raw salt at a temperature greater than the melting point of the raw salt (such as 800-1400) ℃) high temperature treatment, a non-bamboo plant salt with excellent biological effect was unexpectedly prepared. The method for preparing the non-bamboo plant salt is simple and easy to popularize on a large scale. On this basis, the inventors have completed the present invention.

the term

In the present invention, the term "functional plant salt" is a non-bamboo plant salt, and refers to a product prepared by using a non-bamboo extract as a plant-based raw material. Preferably, the non-bamboo plant salt is pine salt and / or plum salt.

In the present invention, the term "without pre-baking" means that the raw material for preparing the non-bamboo plant salt is a direct mixture of non-bamboo extract and raw salt, and the mixture has not been subjected to one or more low temperatures (such as 800 ° C or lower) pre-baking treatment.

In the present invention, the term "plant extract" is a non-bamboo extract.

Non-bamboo extract

In the present invention, the term "non-bamboo extract" refers to an extract of a substance selected from the group consisting of various fruits, vegetables, edible flowers, Chinese herbal medicines, and edible plants, preferably a substance selected from the group Extracts: plum, pine, tea, lotus, chrysanthemum, pomegranate, begonia, edible fungi, algae, more preferably plum extract and / or pine extract.

The plum extract is selected from the group consisting of plum blossom extract, plum fruit extract, plum leaf extract, plum branch extract, plum root extract, plum kernel extract, or a combination thereof.

Non-bamboo plant salt and preparation method and application thereof

The invention discloses a class of functional plant salts, a preparation method and uses thereof, and relates to the fields of food, condiments, daily chemicals, and medicines, and the purpose is to provide a natural, safe, nutritious, and multiple biological health care effect. Plant salt. The core is to use intermediate frequency melting technology or resistance heating technology. Mix different types of plant extracts from different sources with edible salt in a certain mass ratio (0-40%) and put them into an intermediate frequency melting furnace or resistance furnace. The temperature is reduced to 800 to 1400 ° C. and melted, and then crystallized after cooling, so as to obtain plant salt series with different colors, different physical and chemical properties, different lattice structures, different flavors, and different uses. Its distinctive feature is that the salt solution changes from weak acidity to strong alkalinity, and the color changes from white to gray, light gray, pale pink, fuchsia, and bright blue and other colors, showing a clean and clear appearance with a touch of light The sulphur taste of the salt is smaller than that of the original salt, and the elemental composition is more abundant. Among them, the potassium content is increased by about 100 times, the calcium is about 7 times, and other beneficial elements are also significantly increased. The health benefits of functional plant salts include, but are not limited to: whitening, liver protection, stomach strengthening, detoxification, anti-inflammatory, anti-allergy, oral cleansing, prevention of hypertension, treatment of migraine, inhibition of intestinal canceration, and can be widely used in food, Beverages, condiments, health foods, medicines, daily chemicals, personal care products, etc. have a bright future. Since the melting point of the sodium chloride crystal lattice is 801 ° C, the temperature for completely melting the table salt is at least about 900 ° C, and the traditional furnace cannot generally meet this temperature requirement. Intermediate frequency smelting and resistance heating are two technologies that can efficiently convert electrical energy into thermal energy, which can quickly reach a melting temperature of 900-1700 ° C, have high production efficiency, and can realize mechanized, automated, large-scale, standardized and clean production. At the same time, functional plant salt series with different colors, stable performance, excellent quality, and standardizable quality can be obtained by controlling the type of plant extracts, the addition ratio, the smelting temperature, the holding time, and the heating and cooling rates.

The invention creatively applies intermediate frequency melting technology or resistance heating technology, and after mixing table salt with different plant extracts, it is smelted at a high temperature of 800 to 1400 ° C to form different colors, different lattice structures, different physical and chemical indexes, Functional plant salt series with different flavors and uses.

Intermediate frequency smelting is a commonly used metal smelting method, that is, to convert AC power at 50Hz to intermediate frequency (300 ~ 1000Hz), rectify the three-phase power frequency AC to DC, and then convert DC to adjustable intermediate frequency current. Supply the intermediate frequency alternating current flowing through the capacitor and the induction coil to generate high-density magnetic lines of force in the induction coil, and quickly produce high temperature through a magnetically permeable container (such as a graphite silicon carbide crucible) to heat the material (i.e. salt and extraction Mixture of substances) to make it melt. Intermediate frequency melting technology can reach the required melting temperature in a short time, greatly improving production efficiency.

The resistance heating technology converts electrical energy into heat energy through a resistor body, thereby rapidly heating the material. The resistance furnaces currently in commercial use in China mainly use molybdenum rods, silicon rods or carbon rods as heating elements, and the maximum furnace temperature can reach 1700 ° C. Resistance heating technology can control heating time, temperature, heating rate, etc., so as to achieve precise control of process parameters and standardization of products.

Plant extracts, also known as phytochemicals (that is, plant secondary metabolites), refer to the use of different technical means to extract, isolate, and purify from various fruits, vegetables, flowers, Chinese herbal medicine, medicinal and edible plants, and new resource foods. Different precision formulations and even characteristic monomer compounds, such as extracts from plum, orchid, bamboo, chrysanthemum, pine, lotus, tea, pomegranate, begonia, edible fungi, algae and the like.

The raw material of the algae extract can be seaweed (such as kelp, wakame, sargassum, etc.), or algae cultivated in freshwater or seawater, such as cyanobacteria, green algae, chlorella, etc .; edible mushroom extracts include shiitake mushrooms , Mushrooms, enoki mushrooms, bamboo mushrooms, mushrooms, fungus, white fungus, monkey head, ganoderma, truffle, boletus, etc. and their processing residues (such as mushroom handles, etc.); microbial-derived extracts include various types of yeast Extracts (also known as yeast extract), such as beer yeast, baker's yeast, and the like.

The main technical features of the present invention are: after using intermediate frequency melting technology or resistance heating technology, plant extracts from different sources are mixed with table salt at a ratio of 0 to 40% (the extract powder will be evenly adsorbed on the surface of the table salt particles) , Under normal pressure, the temperature was raised to 800 ～ 1400 ℃, and then smelted. After cooling, it was recrystallized to obtain plant functional salt series with different colors, different lattice structures, different physical and chemical indexes, different flavors and different uses. According to the source of plant extracts and their effective components, addition ratios, melting parameters, etc., the new plant salt series has whitening, liver protection, stomach strengthening, detoxification, anti-inflammatory, anti-allergy, oral cleansing, and prevention of hypertension , Multiple functions such as treating migraine and inhibiting intestinal cancer, can be widely used in food, beverages, condiments, health foods, pharmaceuticals, daily chemicals, personal care products and other fields.

The approximate process and process parameters of the present invention are as follows:

Mix the plant extract powder with table salt at a mass ratio of 0 to 40% (preferably 5 to 25%);

Put the above mixture into the magnetically-conducting crucible and build it in the intermediate frequency melting furnace, and start to heat up, and the heating rate is 1 ～ 200 ℃ / min; 1 ～ 20 ℃ / min;

Rise to a temperature between 800 ～ 1400 ℃ under normal pressure for 0 ～ 6h;

Pour out the material and cool it naturally or in a controlled way;

After cooling and crystallization, crushing and sieving to obtain the product;

The heating temperature can be set in one or more intervals between 800 and 1400 ° C as required;

The above mixing-melting-recrystallization-cooling-pulverizing process can be performed one or more times. (1) The raw common salt (also called raw salt) according to the present invention may be sea salt, lake salt, well salt, mineral salt, and preferably crude sea salt (that is, sun salt). (2) According to the functional plant salt provided by the present invention, according to different sources of plant extract, addition ratio, melting temperature and other parameters, its health effect can be specifically expressed as non-bamboo functional plant salt (such as pine salt, plum, etc.) The health benefits of salt) include, but are not limited to, whitening, liver protection, and prevention of hypertension. Its applications include food, beverages, condiments, health foods, pharmaceuticals, household chemicals and personal care products. (3) In addition, the intermediate frequency smelting technology and the resistance heating technology of the present invention can also be directly used for processing table salt, that is, without adding any plant extract or other foreign substances in the manufacturing process, the raw salt is converted into a food with higher safety and appearance More crystal clear grilled salt.

The outstanding advantage of the present invention is that by using intermediate frequency melting technology or resistance heating technology, raw salts can be mixed with plant extracts (powder) of any source and ratio, and recrystallized after co-melting in a precisely set temperature interval, and once through Or it can be roasted several times to obtain salt with special biological effects, and it can realize large-scale industrial production of mechanization, automation, standardization and cleanliness. The invention creates non-bamboo series plant functional salt represented by pine salt and plum salt, which is a revolution to the table salt industry (especially the high-end salt market) and is of great significance to the health cause of all human beings .

To solve the above technical problems, the present invention proposes a method for preparing a functional plant salt, which includes the following steps:

One or more plant extract powders are mixed with fine salt uniformly at an added amount of 1% to 40%, and roasted at a high temperature of 800-1400 ° C once or in stages to obtain a functional plant salt.

As an improvement of the preparation method of the functional plant salt of the present invention:

When the plant extract powder is one type:

A plant extract powder is uniformly mixed with fine salt at an addition amount of 1% to 40%, and is roasted at a high temperature of 800-1400 ° C at one time to obtain a functional plant salt.

As a further improvement of the preparation method of the functional plant salt of the present invention:

When the plant extract powder is multiple (at least two):

After mixing a plurality of plant extract powders uniformly, a mixed powder is obtained;

The obtained mixed powder is uniformly mixed with fine salt at an addition amount of 1% to 40%, and is roasted at a high temperature of 800-1400 ° C at one time to obtain a functional plant salt.

When the plant extract powder is multiple (at least two):

S1. Mix a kind of plant extract powder with fine salt according to the addition amount of 1% to 40%, bake it at a high temperature of 800-1400 ° C and keep it for a while;

S2. Take out the product that was kept at 800-1400 ° C for a certain time in step S1, add another plant extract powder to it after crushing, and repeat steps S1 and S2 (Note: at this time, the original temperature or higher Continue to roast) until all the plant extract powder is roasted to obtain a functional plant salt.

In order to solve the above technical problems, the present invention also provides a functional plant salt prepared by using the above preparation method.

In order to solve the above technical problems, the present invention also proposes the use of a functional plant salt:

The functional plant salt is used in pharmaceutical auxiliaries, health foods / drinks, functional foods / drinks, table seasoning salt, cooking salt, special-purpose cosmetics or personal care products.

The functional plant salt according to the present invention is characterized in that, by using intermediate frequency melting technology or resistance heating (also known as ohmic heating) technology, plant extracts from different sources are mixed with table salt at a certain ratio, It is smelted at 800 ～ 1400 ℃ and recrystallized after cooling. The new healthy salt can be widely used in food, beverages, condiments, health foods, pharmaceuticals, daily chemicals, personal care products, etc. The non-bamboo plant functional salt represented by pine salt and plum salt, which is pioneered by the present invention, has the same biological effects as bamboo salt, and also has various functions such as preventing hypertension, whitening, and protecting the liver.

According to the different types, sources and effective ingredients of plant extracts, addition ratios, and roasting process parameters, plant functional salts with different colors, different lattice structures, different physical and chemical indexes, different flavors, and different uses can be obtained. Two series of bamboo salt and non-bamboo salt. The outstanding features and common characteristics of its products are: the salt solution changes from weakly acidic to strongly alkaline, and the color changes from white to gray, light gray, pale pink, fuchsia, and bright blue, showing a clean and clear appearance. , Accompanied by a slight sulphur smell; the unit cell size of the salt is smaller than the original salt, and the elemental composition of the salt is more abundant, in which the potassium content is increased by about 100 times, the calcium is about 7 times, and other beneficial elements are also significantly increased.

The intermediate frequency melting technology is to convert AC power of 50Hz to intermediate frequency (300 ~ 1000Hz), rectify the three-phase power frequency AC to DC, and then convert DC to adjustable intermediate frequency current. The intermediate frequency alternating current flowing in the induction coil generates high-density magnetic lines of force in the induction coil, and rapidly produces high temperature through a magnetically permeable container (such as a graphite silicon carbide crucible) to heat the material (that is, a mixture of salt and extract) Let it melt. The melting temperature can be reached quickly in a short time, which greatly improves the production efficiency.

The specific process and parameters are as follows:

Mix different plant extract powders with table salt at a mass ratio of 0 to 40% (preferably 5 to 25%);

Put the above mixture in a magnetically-induced crucible and place it in an intermediate-frequency melting furnace, and begin to raise the temperature, with a heating rate of 20 to 100 ° C / min;

Rise to a temperature range between 800 ～ 1400 ℃ under normal pressure, and keep it for 0 ～ 6h;

Pour out the melted material and cool it naturally or controlledly;

After cooling and crystallization, crushing and sieving to obtain the product;

The melting temperature can be set in one or more intervals between 800 and 1400 ° C;

The above mixing-melting-cooling-recrystallization-pulverizing process can be performed one or more times.

Resistance heating (also known as ohmic heating) technology converts electrical energy into thermal energy to rapidly heat materials. The ratio of resistance furnace to flame furnace has high thermal efficiency and easy temperature control. It is divided into direct heating and indirect heating. At present, most resistance furnaces use indirect heating, and the equipment is equipped with a resistance element that realizes electric-thermal conversion, called an electric heating body, which transfers heat energy to the material to be processed. Commonly used electric heating bodies are silicon carbide rods and molybdenum disilicide rods. The temperature of silicon carbon rods can reach 1400 ° C, and silicon molybdenum rods can reach 1700 ° C.

The specific process and parameters are as follows:

Put the above mixture into the corundum crucible and put it in the resistance furnace, and start to raise the temperature, the heating rate is 1 ～ 20 ℃ / min;

Pour out the material and cool it naturally or in a controlled way;

After cooling and crystallization, crushing and sieving to obtain the product;

The above mixing-melting-recrystallization-cooling-pulverizing process can be performed one or more times.

The plant extract, also known as a phytochemical, is a secondary metabolite of a plant. Contains a variety of fruits, vegetables, flowers, Chinese herbs, medicinal and edible plants, and plant-derived new resource foods, crude plant extracts, high-precision preparations and even monomer compounds such as bamboo, plum, pine, tea, lotus, chrysanthemum , Pomegranate, begonia, edible fungus, algae extract, etc. The same plant source can also be extracts from different parts of it, such as bamboo extracts including bamboo leaf extracts (such as bamboo leaf flavones, bamboo leaf polyphenols), bamboo rut extracts (such as ruta triterpenes, ruta polysaccharides), Bamboo pole extract, bamboo shoot extract (such as bamboo shoot sterol, bamboo shoot amino acid peptide), plum extracts include plum fruit extract, plum extract, plum leaf extract, plum branch extract, plum root extract, plum kernel extract, pine The extracts include pine needle extract, pine bark extract, and pine pollen extract.

According to the different types and sources of plant extracts, plant functional salts are divided into two series: bamboo and non-bamboo. It is classified as bamboo functional salt by using bamboo extract series. Non-bamboo functional salts are collectively referred to as non-bamboo functional salts. They include algae, mushrooms (edible fungi) and microbial-derived extracts (or extracts). Functional salt.

The common salt raw material (that is, raw salt) may be sea salt, lake salt, well salt, mineral salt, preferably crude sea salt (also known as sun-sea salt).

The health effects of the non-bamboo functional salts include, but are not limited to, preventing hypertension, whitening, and protecting the liver.

The application fields of the functional plant salt include: food, beverages, condiments, health foods, medicines, daily chemicals and personal care products.

The intermediate frequency melting technology or the resistance heating technology of the present invention can also directly process table salt (that is, without adding plant extracts or any other foreign substances), and convert it into roasted salt with higher food safety.

Compared with the prior art, the present invention has the following technical advantages:

The specific biological functions of the functional plant salt prepared by the present invention include: bacteriostatic, anti-inflammatory, anti-viral; protecting the liver and kidney, soothing the stomach, detoxifying and detoxifying, stopping bleeding and hemorrhoids; treating migraine, allergic rhinitis, Anti-inflammatory effect on human gingival fibroblasts, weight loss function, protecting oral health, inhibiting colon cancer, increasing anti-mutation and anti-cancer effects in vitro, anti-mutation activity of HepG2 human liver cancer cells and anti-cancer effects in vitro, preventing neuronal apoptosis Wait. In addition, it helps to improve the permeability of human epidermal cells and helps skin care factors in daily chemicals work better.

Specific uses of the functional plant salt prepared by the present invention include: pharmaceutical auxiliaries; health food / drinks; functional foods / drinks; table seasoning salt, cooking salt; special-purpose cosmetics, personal care products (skin cream, liquid foundation, soap , Facial mask, toothpaste, mouthwash, shampoo, bath salt, etc.); the form of the end product can be powder, capsule, tablet, granule, effervescent tablet, water, emulsion, spray, etc.

The present invention will be further described below with reference to specific embodiments. It should be understood that these examples are only used to illustrate the present invention and not to limit the scope of the present invention. The experimental methods without specific conditions in the following examples are usually performed according to the conventional conditions or the conditions recommended by the manufacturer. Unless stated otherwise, percentages and parts are by weight.

Unless otherwise defined, all professional and scientific terms used herein have the same meaning as those familiar to those skilled in the art. In addition, any methods and materials similar or equal to those described can be used in the method of the present invention. The preferred implementation methods and materials described herein are for demonstration purposes only.

General materials and equipment

Pine needle extract: brown powder, purchased from Shaanxi Qingya Biotechnology Co., Ltd .;

Bamboo Leaf Extract (Bamboo Leaf Flavonoids): brown powder, purchased from Zhejiang Shengshi Biotechnology Co., Ltd. (Anji);

Plum branch extract: yellow powder, provided by Hangzhou Youmeite Biotechnology Co., Ltd .;

Raw salt (sun-sea salt): from Weifang, Shandong, the measured NaCl content is 93.36%;

Medium frequency melting furnace: the heating element is a copper induction coil, and the crucible is a magnetically conductive graphite silicon carbide crucible;

Tube resistance furnace: The heating element is a silicon carbon rod.

Example 1. A method for preparing a functional plant salt, including the following steps:

1. Obtain plant extract powder:

The above-mentioned plant extracts include, but are not limited to, plant extracts of various fruits, vegetables, edible flowers, Chinese herbal medicine and medicinal food plants, as well as new sources of food derived from plants, such as bamboo, plum, pine, tea, lotus, Daisy, pomegranate, begonia, edible fungus, algae extract, etc.

The same plant source can also be extracts from different parts of it, such as bamboo extracts including bamboo leaf extracts (bamboo leaf flavones, bamboo leaf polyphenols), bamboo rut extracts, bamboo pole extracts, bamboo shoot extracts, and plum extracts including Plum blossom extract, plum fruit extract, plum leaf extract, plum branch extract, plum root extract, pine extracts include pine needle extract, pine bark extract, pine pollen extract, and the like.

2. Mix the plant extract powder in step 1 with the fine salt in an amount of 1% to 40% to obtain a mixture;

The obtained mixture is put into a special container, and is heated to 800-1400 ° C. in a medium-frequency melting furnace (or other mechanized oven) at a certain heating rate to obtain a functional plant salt.

The source of the fine salt may be sea salt, lake salt, well salt, mineral salt, and preferably crude sea salt.

The above% is a mass ratio.

Example 2: The plant extract powder in Example 1 was changed to at least two plant extract powders, that is, the at least two plant extract powders were mixed uniformly at any ratio to obtain a mixed powder; the mixed powder was 1% The added amount of -40% is mixed with fine salt (sieved) uniformly to obtain a mixture; the rest is equivalent to Example 1.

Embodiment 3. The plant extract powder in Example 1 is changed to at least two plant extract powders, and the specific steps are as follows:

1. Mix a plant extract powder with fine salt to obtain a mixture;

2. Put the obtained mixture into a special container, heat it in an intermediate frequency melting furnace (or other mechanized oven) to 800-1400 ℃ at a certain heating rate, and keep it for a certain time to obtain the product;

3. Take out the product that was kept at 800-1400 ℃ for a certain period of time in step 2 and add another plant extract powder to it after crushing, and repeat steps 1-3 (Note: at this time at the original temperature or higher Continue to roast) until all plant extract powder is roasted to obtain functional plant salt

Note: The total added amount of the plant extract powder used above is 1% to 40% (mass ratio).

In summary, the functional plant salt of the present invention can be roasted at one time after adding plant extracts, or it can be roasted in stages and added in stages.

During the high-temperature smelting process of the functional plant salt provided by the present invention, due to the infiltration of different mineral elements in different plant extracts, the elemental composition, NaCl crystal lattice, and crystal configuration have undergone significant changes. According to different addition ratios and roasting methods, different colors are displayed, such as gray, purple, pink, white, blue, turquoise, etc .; the pH value of the 5% saline solution is increased from 6-7 of the raw salt to 8-12; The total amount of NaCl decreases, and the content of other elements (especially a variety of trace elements) increases; the taste changes from a simple salty taste to a rich and rounded savory sweetness, usually with a bit of rotten egg.

For example, the "pine salt", "bamboo salt", and "plum salt" obtained after adding pine, bamboo, and plum extracts are different due to the origin of the extract, the chemical composition and the amount of addition, and the number of roasting times and process parameters The physical and chemical properties, appearance, color, and flavor of the obtained plant salt are significantly different, and the biological effects caused by them are also different.

The specific biological functions of functional plant salts include: bacteriostatic, anti-inflammatory, anti-viral; liver-protecting kidney, soothe the stomach, detoxify and detoxify alcohol, stop bleeding and relieve hemorrhoids; treat migraine, allergic rhinitis, and affect human gums Fibrocytes have anti-inflammatory effects, weight loss functions, protect oral health, inhibit colon canceration, increase anti-mutation and anti-cancer effects in vitro, anti-mutation activity of HepG2 human liver cancer cells and anti-cancer effects in vitro, and prevent neuronal apoptosis. In addition, it helps to improve the permeability of human epidermal cells and helps skin care factors in daily chemicals work better.

Specific uses of functional plant salts include: as pharmaceutical auxiliaries; health foods / drinks; functional foods / drinks; table seasoning salts, cooking salts; special-purpose cosmetics, and human care products (skin creams, liquid foundations, soaps, masks , Toothpaste, mouthwash, shampoo, bath salt, etc.); the form of the end product can be powder, capsule, tablet, granule, effervescent tablet, water, emulsion, spray and so on.

In summary, the present invention provides a method for preparing a functional plant salt. Different plant extracts and table salt are mixed uniformly at a certain ratio, and they are formed by roasting one or several times at a high temperature of 800-1400 ° C. Functional plant salts of different colors, different spatial structures, different physical and chemical properties, different flavors and different uses. The functional plant salt prepared by the invention not only has a health-care effect, but also helps to improve the permeability of human epidermal cells, and helps the skin care factors in daily chemicals to function better. It can be used in pharmaceutical auxiliaries, health foods / Beverages, functional foods / drinks, table salt, cooking salt, special purpose cosmetics or care products.

Example 4 Production of Plant Functional Salts—Pine Salt (Intermediate Frequency Smelting)

Weigh 6.0g of pine needle extract and 24.0g of raw salt, mix them and put them into a magnetic crucible, put them in an intermediate frequency melting furnace, and raise them to 1000 ℃ at a normal temperature of 100 ℃ / min, at 1000 ℃ After incubation for 1 hour, the temperature was taken out to cool down to obtain pink-purple pine salt (code: Plum Salt). Its color and appearance are shown in Figure 1.

Example 5. Production of botanical functional salt—new purple bamboo salt (medium frequency melting)

Weigh 10g of bamboo leaf extract and 40g of raw salt respectively, mix them well and put them in a magnetic crucible, put them in an intermediate frequency melting furnace, and raise the temperature to 900 ° C at a temperature of 100 ° C / min under normal pressure for 1.5h. Take out the natural cooling, pulverize after cooling to obtain a new type of purple bamboo salt, its color and appearance are shown in Figure 2.

Example 6 Preparation of Plant Functional Salt-Plum Salt (Medium Frequency Smelting)

Weigh 5.0g of plum branch extract and 25.0g of raw salt, mix well and put them into a magnetic crucible, put them in an intermediate frequency melting furnace, and raise it to 1300 ℃ at a normal temperature of 100 ℃ / min, at 1300 ℃ After holding for 1 hour, the temperature was taken out to cool down to obtain blue plum salt (recorded as Plum Salt). Its color and appearance are shown in Figure 3.

Example 7 Preparation of Plant Functional Salt—Pine Salt (Resistance Heating)

Weigh 4.0g of pine needle extract and 26.0g of raw salt, mix them and place them in a magnetic crucible, put them in a tube resistance furnace, and raise them to 1100 ℃ at a temperature of 100 ℃ / min under normal pressure. After incubating at ℃ for 2 hours, the temperature was taken out and the temperature was reduced to obtain a pink purple pine salt. The color and appearance are shown in FIG. 4.

Example 8. Production of botanical functional salt-new type of purple bamboo salt (resistance heating)

Weigh 15g of bamboo leaf extract and 35g of raw salt, mix them well, put them into a corundum crucible, put them in a tube furnace, raise the temperature to 950 ℃ at a temperature of 10 ℃ / min under normal pressure, and keep them for 2.5h. The natural temperature is lowered, and the shredded bamboo salt is obtained after cooling, and its color and appearance are shown in FIG. 5.

Example 9 Production of Plant Functional Salt-Plum Salt (Resistance Heating)

Weigh 8.0g of plum branch extract and 22.0g of raw salt respectively, mix them well, put them into a corundum crucible, put them in a tube resistance furnace, and raise it to 1250 ° C at a heating rate of 10 ° C / min under normal pressure, at 1250 ° C After holding for 1.5 hours, the temperature was taken out to cool down to obtain blue plum salt. The color and appearance are shown in Figure 6.

Performance test (In the experiment, pine, bamboo, and plum salt were the samples obtained in Examples 4, 5, and 6, respectively)

Experiment 1. Analysis of Physicochemical Properties of Plant Functional Salts and Their References

1.1 Color difference analysis

The type of plant extract, the addition ratio, the melting temperature, the holding time and even the heating rate will directly affect the color and appearance of the final product. Figure 7 shows raw salt added with 5 to 35% of different plant extracts, subjected to high temperature smelting at 800 to 1400 ° C for 1 to 2 hours under normal pressure, the pine salt obtained in Example 4, the bamboo salt obtained in Example 5, and Example 6 The appearance of the obtained plum salt can show different colors such as gray, light gray, pale pink, blue-violet and bright blue. At the same time, it can be seen in FIG. 7 that the roasted salt obtained by smelting the raw salt without adding any foreign substances at a high temperature of 800 to 900 ° C. for 1 to 2 hours has higher transparency and brighter color.

The color difference meter is a common photoelectric integrating color measuring instrument. It imitates the principle of color perception of the human eye. It uses a light receiver that can sense three colors of red, green, and blue. The standard light source inside the instrument is used to illuminate the measured object. The photocurrents experienced by each are amplified, and an integral measurement is performed over the entire visible light wavelength range to obtain the tristimulus value and chromaticity coordinates of the color of the transmitted or reflected object, thereby obtaining the signal of this color, and giving the signal by the system. Measure the color difference between samples.

The main indicators measured by the color difference meter include L *, a *, b *. among them,

L * represents the brightness of the sample, the larger the value, the brighter it is;

a * stands for red and green, "+" means red, and "-" means green.

b * represents a blue-yellow phase, "+" indicates a bias toward yellow, and "-" indicates a bias toward blue.

The ΔL value represents the difference between the sample value and the reference point; the Δa value represents the difference between the a * value of the sample and the reference point, which can better represent the red-green value of the sample.

In the present invention, the reference point refers to the value of the standard sample, and the present invention uses a standard white board as the standard sample.

Table 1 is a summary of the color difference analysis data of different plant functional salts. It can be seen that the ΔL values of raw salt and roasted salt are 84.18 ± 0.25 and 82.83 ± 3.47, showing that they are close to white; while the ΔL values of other plant functional salts are between 25-50, the darkest is the mangosteen salt, the brightest It's plum salt. The a * value and b * value of different samples are significantly different (p <0.05), which indicates that the color direction of them differs greatly, showing a completely different hue.

Table 1 Color value parameters of different plant functional salt samples

1.2 pH changes

The pH value of food has an important effect on maintaining the acid-base balance of the human body environment, so it is divided into acidic food and alkaline food. In modern society, the dietary structure of the general public is generally acidic, and over time, an acidic constitution will be formed, leading to a decline in immunity and a sub-healthy state. The pH values of different salt samples were measured at a concentration of 0.2 to 5% (w / v), as shown in Table 2.

The original salt solution with a concentration of 1% or less is weakly acidic (pH <7), and it rises significantly after baking; all the plant functional salt solutions show strong alkalinity (pH> 9) even at a concentration of 0.2%, which is in phase with the original salt. The difference is very significant (p <0.001). It is shown that after the original salt is fused with the plant extract, a large number of alkali metal elements have entered the lattice structure of NaCl or adhered to the surface.

Table 2 pH values of different plant functional salt samples

1.3 Changes in conductivity

The conductivity data of different samples at 0.2 to 5% concentration (w / v) were measured, as shown in Table 3. As can be seen from the table, at a salt solution concentration (<1.0%) that can be tolerated by the human body, there is no significant difference in electrical conductivity between the plant functional salt and the original salt.

Table 3 Conductivity values of different plant functional salt samples

1.4 Atomic Energy Spectrum Analysis

Atomic energy spectroscopy can not only scan and photograph the surface morphology of materials, but also detect various elements on the surface of materials and their relative contents. The plant functional salt prepared by the present invention and its reference sample (particles) are placed under an atomic energy spectrometer (Hitachi, Japan, SU-8010) to perform element qualitative, semi-quantitative, and quantitative analysis on the micro-area points, lines, and surfaces of the sample Analysis (detection limit: 0.5%), the results are shown in Table 4.

Table 4 Elemental composition of different samples obtained by atomic energy spectrum analysis (%)

1.5 Elemental composition analysis

Elemental testing was entrusted to Xi'an Guolian Quality Inspection Technology Co., Ltd. The results are shown in Table 5.

The main ingredient of salt is sodium chloride, and it also contains small amounts of other mineral elements. The more refined the salt, the higher the sodium chloride content, the less other nutrients, which is not good for human health.

Potassium can regulate intracellular osmotic pressure and body fluid acid-base balance, participate in the metabolism of sugar and protein in the cell, help maintain nerve health, normal heartbeat, prevent stroke, and assist normal muscle contraction. In the case of high blood pressure caused by ingestion of high sodium, potassium or potassium-rich foods have a hypotensive effect.

Magnesium is the main cation in human cells. It can affect the transport of potassium and calcium ions, regulate signal transmission, participate in energy metabolism, protein and nucleic acid synthesis, and activate and inhibit catalytic enzymes.

Phosphorus is one of the basic components of nucleic acids that make up genetic material. At the same time, phosphorus and calcium are important building materials for bones and teeth. Phosphorus can maintain the balance of ATP metabolism in the body, regulate the acid-base balance in the body, and participate in the metabolism of energy in the body.

Manganese is a coenzyme of SOD, and its deficiency can cause neurasthenia and affect intellectual development. At the same time, it will also lead to a decrease in insulin synthesis and secretion and affect glucose metabolism.

Molybdenum is an essential trace element for the human body. It is one of the basic components of xanthine oxidase and aldehyde oxidase in the liver and intestines of animals. It is also a component of heparin sulfase oxidase. Studies have shown that molybdenum also has a significant anti-caries effect, and has a strong inhibitory effect on the formation of urinary stones. Humans lacking molybdenum are prone to kidney stones.

Vanadium is an essential trace element in the human body. It is generally believed that it may help prevent cholesterol accumulation, lower blood sugar, lower blood pressure, prevent dental caries, and help make red blood cells.

Selenium is an essential trace element necessary for the human body. The Chinese Nutrition Association lists selenium as one of the 15 essential nutrients for the human body. It is generally believed that selenium is closely related to immunity, aging, and reproductive functions. Selenium deficiency is an important cause of Keshan disease.

Chromium is also an essential micronutrient, which plays an important role in all insulin regulating activities and is an important blood glucose regulator. At the same time, the lack of chromium is also related to the formation of myopia.

Silicon is mainly concentrated in bones, lungs, lymph nodes, pancreas, adrenal glands, nails, and hair. It is the highest in connective tissues such as aorta, trachea, tendons, bones, and skin, and has special significance for human bone health. However, due to industrial development and changes in lifestyle, the silicon element in modern human bodies is often extremely insufficient.

From the results of elemental testing of different salt samples, it can be seen that plant functional salt and original salt (and its roasted salt) have very significant differences. The potassium content of pine, bamboo, and plum salts has increased significantly, especially the potassium content of the new bamboo salt obtained in Examples 2 and 3 is more than 100 times that of the original salt, and it is 14.9% higher than that of Renshan bamboo salt produced by traditional processes; The salt (including the old and new samples) contained magnesium, iron, nickel, zinc, molybdenum, and vanadium significantly higher than the original salt and other plant salts. The selenium was also detected in the pine and plum salts obtained by the new technology. . Among all the samples, plum salt had much higher iodine (28mg / kg), boron (26.6mg / kg), phosphorus (424mg / kg), chromium (4mg / kg) and second only to bamboo salt than other samples. Manganese content (18mg / kg). The silicon content of plant salt is significantly higher than that of raw salt and roasted salt, and the bamboo salt of the new process is higher than the traditionally produced Renshan bamboo salt. At the same time, selenium was detected in pine and plum salts.

There is also a certain amount of sulfide in bamboo salt, with a typical stinky egg smell. Hydrogen sulfide has a variety of neuroprotective effects, which have been confirmed by a large number of experiments at home and abroad, mainly including anti-neuroinflammatory response, anti-oxidative stress injury and anti-hypoxic-ischemic nerve injury, which can increase the plasticity of nerve cells, thereby reducing the hippocampus Neuronal apoptosis.

In addition, it is particularly worth mentioning that after high temperature smelting above 800 ° C, the edible safety of the salt is greatly improved, and the content of heavy metals (lead, arsenic, and mercury) in the roasted salt is significantly reduced compared to the original salt. At the same time, other harmful components (such as organic plastic particles, etc.) in the raw salt are also completely removed.

Table 5 Elemental analysis results of different samples

Note: The detection limit of phosphorus is 20mg / kg; the detection limit of molybdenum, antimony, selenium, tin, and total arsenic is 0.01mg / kg; the detection limit of cadmium and * germanium is 0.001mg / kg; the detection of radon The limit is 0.0001 mg / kg.

Experiment 2. Microstructure and Lattice Structure Analysis of Plant Functional Salts and Their References

2.1 Microscope image of sample appearance

A stereo microscope (Jiangnan Brand SE220) was used to capture the appearance of the sample of the plant functional salt particles obtained during the implementation under the conditions of 10 times the eyepiece and 5 times the objective lens, as shown in FIG. 8.

It can be seen from Figure 8 that the raw salt and roasted salt are basically white, the particle surface is relatively smooth, and the shape is regular. However, pine salt, bamboo salt, and plum salt show different colors, and the crystal arrangement differs greatly, giving them a more lustrous feel. The color of the new bamboo salt prepared by the present invention is similar to that of Renshan bamboo salt, but the former is more pure and looks crystal clear, while the latter has more impurities.

2.2 SEM observation results

The GeminiSEM 300 scanning electron microscope produced by Carl Zeiss Microscopy GmbH of Germany was used to perform morphological characterization of the plant functional salts of the examples. The different sample particles were respectively observed under an electron microscope, and FIG. 9 was obtained. The surface of raw salt and roasted salt is smooth without much attachment. However, the surface of the plant functional salt prepared by the present invention is in the shape of a sweet potato, and many small particulate materials are attached to the particle surface.

2.3 Observation results of transmission electron microscope

Different salt samples were suspended in anhydrous ethanol (5%, w / v), and the morphological characterization of the plant functional salt particles obtained in the examples was performed using a JEM-1230 transmission electron microscope (TEM) from JEOL, Japan. . The transmission electron micrographs of the plant functional salts represented by the pine salt, bamboo, and plum prepared in Examples 4, 5, and 6 are shown in Fig. 10. The shape of the original salt is relatively regular, showing a regular structure of sodium chloride cubes, but the plant functional salt is not specific. Regular, and some small particles are attached around.

2.4 X-ray diffraction analysis results

The pine salt obtained in Example 4, bamboo salt obtained in Example 5, plum salt obtained in Example 6 and its control sample were ground into powder (passed through a 100-mesh sieve), and an X-ray diffractometer (Bruker D8 Advance) produced by Bruker, Germany was used. Perform analysis. Since the crystal is composed of unit cells arranged regularly, these X-rays scattered by different atoms interfere with each other, resulting in strong X-ray diffraction in some special directions. The orientation and intensity of the diffraction line in spatial distribution are closely related to the crystal structure. The diffraction pattern produced by each crystal reflects the atomic distribution of the crystal. The sample can be analyzed for phase analysis, unit cell parameters, and diffraction line intensity analysis.

2.2.1 Crystal structure analysis

Phase analysis is the most commonly used aspect of X-ray diffraction in metals and is divided into qualitative and quantitative analysis. The former compares the lattice plane spacing and diffraction intensity measured on the material with the diffraction data of the standard phase to determine the phase present in the material. Accurate unit cell parameter data can reflect the slight differences in structure between different samples of a substance, or the small changes in the structure of a crystal caused by external physical and chemical factors. The unit cell parameters of several phases of the plant functional salt obtained in the examples are as follows:

Table 6 Sodium chloride content and lattice parameters in different samples

Table 7 Potassium chloride content and lattice parameters in different samples

Table 8 Salt crystal size

2.2.2 X-ray diffraction spectrum and simulated crystal structure diagram

The unit cell parameters of different salt samples were simulated by unit cell parameters. From Figure 11, it can be seen that the raw salt is more regular and cubic, while the ends of the pine salt are sharper, the bamboo salt is more round, and the plum salt has an octahedral cone shape. The crystal structure has changed a lot.

Experiment 3. Sensory performance test of plant functional salt and its reference

The electronic tongue is to simulate the human tongue to analyze, identify and judge the sample to be tested, and use multivariate statistical methods to process the obtained data, quickly reflect the overall quality information of the sample, and realize the identification and classification of the sample. It is a detection technology that uses the multi-sensor array as the basis to sense the overall characteristic response signal of the sample, and performs analog identification and quantitative qualitative analysis on the sample. It is mainly composed of taste sensor array, signal acquisition system and pattern recognition system.

Electronic nose, also known as odor scanner, is a novel instrument for rapid food detection developed in the 1990s. It uses specific sensors and pattern recognition systems to quickly provide overall information about the sample under test, indicating the underlying characteristics of the sample. It is an instrument composed of a selective array of electrochemical sensors and an appropriate identification method. It can identify simple and complex odors and can obtain results consistent with human sensory evaluation.

The discrimination index (DIcrimination index) is a measurement index used by the electronic tongue and electronic nose to determine the overall discrimination effect of the sample, and its value range is [-100, +100]. -100,0 indicates that it cannot distinguish the taste and smell of the sample; +100 indicates that it can effectively distinguish, and the closer the value is to 100, the better the discrimination effect.

3.1 Taste traits derived from electronic tongue

The plant functional salt obtained in the example was made into a 10% solution, and the difference in taste was detected with an electronic tongue (Smartongue, Isensogroup).

It can be seen from Figure 12 that the DI value of the electronic tongue reaches 99.57, indicating that there is a significant difference in taste of different plant functional salts, which can be clearly distinguished. The contribution rate of the main component 1 (PC1) is 78.26%, which is much larger than that of the main component 2 (PC2); the longer the distance on the abscissa, the greater the difference; the pine salt obtained in Example 4 / bamboo obtained in Example 5 The abscissa distance between the salt and the mangosteen salt is close, indicating that the taste of the two is close, and both are significantly different from the original salt and the plum salt obtained in Example 6.

3.2 Olfactory traits derived from electronic nose

The electronic nose collects the odor signals of different samples through 14 sensors, and then analyzes the data by software for principal component analysis. The plant functional salt obtained in the example is made into a 10% solution, and the electronic nose (iNose, Isensogroup) is used to detect the difference in taste. As shown in Figure 13: the two principal components that account for the most information in the sample are abscissa PC1 and ordinate PC2, respectively. The contribution rate of principal component 1 (PC1) is 99.80%, which is much larger than that of principal component 2. Therefore, the two sample data The farther the distance on the abscissa is, the larger the difference is. The abscissas between the plant functional salts in the figure are very close, indicating that the three plant salts obtained by the present invention are closer from the olfactory perspective. The odor of bamboo salt (renshan bamboo salt) prepared by the traditional method is close to that of the original salt. In addition, according to the results of atomic spectrum analysis in Table 4, sulfur is found on the surface of bamboo salt, so it can be explained that it has a slight taste of hydrogen sulfide, while sulfur of other salts has reached the detection limit.

Experiment 4.Animal test of plant function salt to protect liver

4.1 Animal grouping and experimental design

4.1.1 Experimental animals and groups

Forty-five 5-week-old SPF C57BL / 6 healthy male mice were randomly divided into 9 groups after one week of adaptive feeding. The experimental design and dosage configuration are shown in Table 9. Except for the normal control group (1 ^# ), which used conventional feed, the other 8 groups used salt-free basic feed. Administration phase, the oral dose results in mice according to the World Health Organization recommended daily salt intake of 5g per dose, and in standard animal equivalent conversion method, in addition to the group ^# 1, each sample was fed with 4% NaCl , Intragastric administration once a day for 21d. The breeding environment temperature is (22 ± 2) ° C, and the relative humidity is 50-70%.

Table 9 Animal test groups and doses

* In order to ensure comparability test data, the normal control group and the model group ^# 2 ^# 3 diets are pure NaCl salt

4.1.2 Acute liver injury modeling

After the last administration 1h, model control group and the experimental group ^(# 3 - ^# 9) mice were injected with 0.1% CCl ₄ in olive oil solution, CCl ₄ at a dose of 10mL / kg.BW, normal control group ^(# 1 ~ 2 ^# ) Give an equal volume of olive oil and fast overnight.

4.1.3 Sample collection and determination of biochemical indicators

Sixteen hours after the injection of the CCl ₄ olive oil solution, the mice were sacrificed by spinal dislocation, the eyeballs were immediately removed for blood extraction, and the mice were dissected to take the liver.

After the blood sample was centrifuged at 3500r / min for 10min, the upper serum was collected for determination of blood biochemical indicators. After taking out the complete liver, cut a portion of 0.4g of liver tissue, put it into a cryopreserved tube filled with PBS (pH = 7.4), and homogenize the rest of the liver tissue in a cryopreserved tube. Store in a -80 ° C refrigerator . The cut 0.4g liver homogenate was centrifuged in an ultra-low temperature centrifuge (4000r / min, 20min), and the supernatant was taken to determine the content of malondialdehyde (MDA), glutathione (GSH), and total Activities of superoxide dismutase (T-SOD) and glutathione peroxidase (GSH-Px) (Coomassie blue method).

4.1.4 Pathological observation of liver tissue

Liver tissue from the same part of each group of rats was taken, washed with cold saline, fixed with neutral formalin, 4 μm paraffin sections were made, and HE stained, and the morphological changes were observed under a microscope.

4.1.5 Experimental data processing

The experimental data were expressed as mean ± standard error (x ± s), and the data were tested for homogeneity of variance; the comparison of data between groups was performed by single factor analysis of variance. The Duncan test in the one-way analysis of variance (ANOVA) of SPSS19.0 statistical software was used to analyze the significance, P <0.05 was significant, and P <0.01 was extremely significant.

4.2 Results and analysis

4.2.1 Effects of plant functional salts on body weight of experimental mice

During the 21-day test period, the body weight of the mice in each experimental group increased with the feeding time, and the body weight did not show significant differences (P> 0.05). It was observed that the fur of the mice in each group was smooth and the clinical activities were normal. Good health status, indicating that intake of different salt samples had no effect on the clinical performance of mice. See Table 10 for the body weight of each group of experimental rats during the test cycle.

Table 10 Comparison of body weight of mice in each experimental group during the test period

Note: If the letters in the same column are completely different, there is a significant difference between the two (P <0.05);

4.2.2 Effects of plant functional salts on transaminase activity in serum of mice with chemical liver injury

As can be seen from Table 11, the serum glutamate aminotransferase (ALT) and aspartate aminotransferase (AST) activities of the model group (3 ^# ) mice were significantly higher than those of the normal control group (2 ^# and 1 ^# ) (P < 0.01), indicating successful modeling.

It can be seen from Table 11 that the three plant functional salts all showed varying degrees of reducing serum transaminase activity, while the original salt had almost no effect. Compared with the model group, the effect of three plant functional salts on inhibiting the increase of ALT activity was extremely significant (P <0.01); in inhibiting the increase of AST activity, pine salt (P <0.01) was higher than the other two samples (P <0.01) 0.05) is more significant; the inhibitory effect of pine salt on serum liver aminotransferase in mice with acute liver injury induced by CCl _{4 is} better than that of bamboo salt and plum salt. It shows that bamboo salt, pine salt and plum salt have certain liver and liver protection effects. However, the positive drug control group (bifendate) had the strongest effect of inhibiting ALT activity, but had no effect on AST. The commercially available Renshan Zizhu salt, like the original salt, did not show an inhibitory effect on serum aminotransferase activity in mice with acute chemical liver injury.

Table 11 Comparison of transaminase activities in serum of mice in each experimental group

Compared with the model control group (3 ^# ) and the NaCl control group (2 ^# ), ^# means P <0.01;

Compared with the model control group (3 ^# ) in each experimental group (4 ^# ~ 9 ^# ), * means P <0.01.

4.2.3 Effects of plant functional salts on oxidative stress indicators in mice with chemical liver injury

When experimental animals are attacked by chemical toxicants, an important characteristic of acute liver injury is an increase in MDA content, a decrease in GSH levels, and a decrease in SOD activity, etc., accompanied by the peroxidation of liver tissue membrane lipids and a strong oxidative stress response.

The data in Table 12 show that the two groups (2 ^# and 3 ^# ) who also consumed salt-free feed and fed 4% pure NaCl at the same time made significant changes in oxidative stress indicators after modeling with CCl ₄ . In particular, the changes in GSH and MDA levels were extremely significant (P <0.01), indicating that the livers of animals were indeed damaged after CCl ₄ administration.

It can be known from Table 12 that all three kinds of plant functional salts can increase the GSH content of the damaged liver to a certain extent. Among them, the plum salt shows a very significant increase; and all of them can reduce the MDA content of the damaged liver. It was plum salt (P <0.01), followed by Renshan Zizhu salt and pine salt (P <0.01); the bifendate group also showed effects of increasing GSH and reducing MDA content, but the effects were not as good as those of plum salt. In terms of enhancing the endogenous antioxidant enzyme activity of the damaged liver, all three plant functional salts showed a certain effect, among which bamboo salt also showed a significant effect on T-SOD activity (P <0.05).

Table 12 Comparison of anti-oxidant activity in liver tissue of mice in each experimental group

4.2.4 Histopathological observation of liver damage and repair in experimental animals

Figure 14 is the effect of plant functional salts on the histopathology of the liver of experimental mice (× 400). ^# 1 and ^# 2 are mouse normal liver tissue, showing hepatic cords arranged in rows, clear cell borders, normal karyotype, no abnormalities; hepatic cords derangement 3 ^# NaCl model group karyotype change significantly, There is a large amount of cell infiltration in the central vein; hepatocyte cords in the 4 ^# biphenyldiester group are clearer, the karyotype is normal, and a small amount of vacuolar degeneration, indicating that bifendate drip pills have a therapeutic effect on acute liver injury; 5 ^# The arrangement of hepatocyte cords in Renshan Zizhu salt group was clear, the karyotype was normal, there was a small amount of vacuolar degeneration and watery degeneration; the hepatocyte cords of the ^# 6 original salt control group were irregularly arranged, the karyotype changed significantly, and a large number in the central vein Cell infiltration; hepatocyte cord arrangement in the 7 ^# bamboo salt test group was clear, cell boundaries were clear, the karyotype was normal, and there was a small amount of vacuole degeneration; hepatocyte cord in the 8 ^# plum salt test group was clearly arranged, and the karyotype was normal, with a small amount Vacuolar degeneration; The hepatocytes of the 9 ^# pine salt test group were arranged more clearly, the nuclei were normal, there was a small amount of vacuolar degeneration, and there was a little cell infiltration in the central vein. According to the morphological examination results of liver tissue pathological sections, it can be seen that bamboo salt, pine salt, and plum salt have certain protective effects on acute liver injury in mice induced by CCl ₄ .

4.3 Conclusion

China is the world's largest liver disease country. It is predicted that by 2020, the number of chronic liver patients will reach 450 million. The national condition of high incidence of liver disease is largely related to food sources, drinking water, dietary habits, and dining styles. The edible salt of Chinese residents mainly comes from sea salt. The sun-sea salt (original salt) is the concentrate of seawater. All pollutants in the ocean may remain in it, bringing certain food safety risks. The results of this study show that the levels of GSH in the liver of experimental rats that ingested the raw salt were significantly lower than those in the same dose of pure NaCl, suggesting that there may indeed be some harmful factors in the liver that caused oxidative stress in the liver. The final results show that the traditional ingredients of the bamboo salt roasted by the traditional method are limited in the effective components absorbed from the bamboo tube, and their liver-protective effects are not as good as the pine, bamboo, and plum salts provided by the present invention.

Experiment 5. Study on the whitening effect of plant functional salt

5.1 Materials, reagents and instruments

Mouse B16 melanoma cells, Shanghai Institute of Cell Biology, Chinese Academy of Sciences; RPMI-1640 medium, Gibco, USA; fetal bovine serum, ThermoFisher, USA; trypsin, penicillin-streptomycin solution, phosphate buffered saline (PBS), AR, Hangzhou Keyi Biotechnology Co., Ltd .; L-DOPA, tyrosine, tyrosinase (25KU, ≥500u / mg), AR, Beijing Solibao Technology Co., Ltd .; Tetramethyl coupling Azazole blue (MTT, 5g / L mass fraction of staining solution), Beijing Regen Biotechnology Co., Ltd .; TritonX-100, -arbutin, dimethyl sulfoxide (DMSO), AR, Shanghai Aladdin Reagent Co., Ltd. .

Eon microplate reader, BioTek, USA; LDZX-50KBS vertical autoclave, Shanghai Shen'an Medical Equipment Factory; CP-ST50A carbon dioxide incubator, Changsha Changjin Technology Co., Ltd .; SW-CJ-F ultra-clean bench , Shanghai Boxun Industrial Co., Ltd .; CKX41 inverted microscope, Japan OLYMPUS Optical Industry Co., Ltd .; BDFACSCaLIBUR flow cytometer, American BD company.

5.2 Experimental methods

5.2.1 Determination of tyrosinase inhibition in vitro

Tyrosine was used as a substrate for tyrosinase monophenolase activity measurement, L-DOPA was used as a substrate for tyrosinase diphenolase activity measurement, and tyrosinase activity measurement was performed with reference to the method of Huang et al. First, the raw salt, roasted salt, pine salt, bamboo salt, and plum salt were prepared into a salt solution of 0.2%, 1%, 5%, and 10% by mass with PBS solution, and the sample solutions of different concentrations and 0.1mol were accurately sucked in order according to the table. / L pH6.8 PBS solution and 1.0mmol / L tyrosine or L-DOPA, mix thoroughly and put in a 25 ° C water bath and incubate for 10min, then add the corresponding 870u / mg tyrosinase solution for 10min The absorbance of each reaction solution at 475 nm was then measured. The suppression rate is calculated as follows:

Tyrosinase monophenolase / diphenolase inhibition rate /% = [1- (A3-A4) / (A1-A2)] × 100

Table 13 Composition of reaction solution in in vitro tyrosinase activity measurement (mL)

5.2.2 Determination of B16 cell proliferation rate

MTT method was used to determine the proliferation rate of B16 cells. The original salt was used as a negative control, and arbutin and Korean bamboo salt were used as positive controls. The B16 cells in the logarithmic growth phase were selected and inserted into a 96-well plate. After the adherence, the original culture medium was discarded, and the prepared raw salt, pine salt, bamboo salt, containing 0.25%, 0.50%, 0.75%, and 1% by mass were added. The culture medium of plum salt, -arbutin and Korean bamboo salt was cultured at 37 ° C and 5% CO ₂ for 48 hours. Take out 4h before the measurement, add 20 μL of MTT (5mg / mL) solution to each well, put it in a CO ₂ incubator and incubate for 4 h at 37 ° C, 5% CO ₂ environment, then discard the medium and MTT, and put it in each well Add 150 μL of DMSO to dissolve the remaining MTT-formamidine crystals, shake for 10 min, and use the cells cultured without samples as a control and PBS as a blank. The absorbance of each well at 570 nm was measured with a microplate reader. The cell proliferation rate is calculated as follows:

Cell proliferation rate /% = (OD _{570 (experiment)} -OD _{570 (blank)} ) / (OD _{570 (control)} -OD _{570 (blank)} ) × 100

5.2.3 Determination of tyrosinase activity in B16 cells

Dopa oxidation method was used to determine the tyrosinase activity in B16 cells. B16 cells were inserted into a 96-well plate, the original medium was discarded after being adhered, and a medium containing each sample was added to culture for 48 h. The culture solution of each group of cells that has reached the action time is decanted, washed twice with PBS buffer, and 50 μL of a 1% by mass Triton-X100 aqueous solution is added to each well, and then quickly stored in a -80 ° C refrigerator for 30 minutes and removed. After thawing at 37 ° C, the cells were completely ruptured. 10 μL of L-DOPA solution (10g / L) was added to each well. Cells cultured without samples were used as a control, PBS was used as a blank, and the reaction was performed at 37 ° C for 2 hours. The OD value of each well at 475 nm was measured. Calculate intracellular tyrosinase activity as follows:

Intracellular tyrosinase activity /% = (OD _{475 (experiment)} -OD _{475 (blank)} ) / (OD _{475 (control)} -OD _{475 (blank)} ) / cell proliferation rate × 100

5.2.4 B16 cell migration assay

Select B16 cells in logarithmic growth phase, adjust the cell concentration to 4 × 10 ⁵ cells / mL, add 2 mL to a 6-well plate, and when the cells cover about 60% at the bottom, discard the original medium and take 10 μL pipette tips Draw a straight line at the bottom of each well (one operation), gently wash off the slipped cells with PBS, and then continue to culture for 48 h with 0.5% mass fraction of the original salt, pine salt, bamboo salt, plum salt, and arbutin. The growth state and migration of the cells were observed under a microscope, and cells cultured without samples were used as controls.

5.2.5 Determination of B16 cell cycle

After the B16 cells were adhered in a 6-well plate, a medium containing 0.5% of each sample was added for culture, and three groups of each group were set up in parallel and a blank control group was cultured for 48 hours. After the incubation, the cells were collected, washed with PBS, and the supernatant was removed. 500 µL of a cold 70% ethanol solution was added and fixed overnight, and then the remaining ethanol was centrifuged and aspirated. Add 100 μL of RnaseA solution to the cell pellet, resuspend the cells, incubate at 37 ° C for 30 minutes, add 400 μL PI staining solution and mix well, incubate at 4 ° C in the dark for 30 minutes, and transfer to a flow tube for detection on the machine.

5.2.6 Experimental data processing

The experimental data were processed with Origin9, and the calculation results were expressed as mean ± standard deviation (Mean ± SD). The significance test was performed using Duncan in SPSS 21 one-way analysis of variance (ANOVA).

5.3 Analysis of results

5.3.1 Inhibitory activity of plant salts on tyrosinase in vitro

When tyrosine is used as a substrate, tyrosinase can catalyze it into dopa and further produce melanin. This process mainly exerts tyrosinase monophenolase activity. The inhibitory effect of various salt solutions on tyrosinase monophenolase activity is shown in FIG. 15. As can be seen from FIG. 15, the original salt showed no significant inhibitory effect on tyrosinase in the concentration range of 0.2 to 10.0%. Roasted salt had the greatest effect on tyrosinase at a concentration of 5.0%, but the inhibition rate was not higher than 10%. Pine salt and bamboo salt have a significant effect on tyrosinase activity and show a concentration-effect relationship. When the mass fraction is 0.2 to 5.0%, as the salt concentration increases, the greater the inhibition rate of tyrosinase, 5.0% The inhibition rate reached above 94%, and the inhibition rate remained basically unchanged at 10.0%. Compared with pine salt and bamboo salt, plum salt has a lower tyrosinase inhibition rate at low concentrations (0.2%, 1%), and the inhibition rate increases rapidly when the concentration is greater than 5.0%. The inhibition rate of tyrosinase was 73.2%, and the effect was slightly worse than that of pine salt and bamboo salt solutions of the same concentration.

When dopa is used as a substrate, tyrosinase can catalyze it into dopaquinone and further produce melanin. This process mainly uses tyrosinase diphenolase activity. The inhibition rate of tyrosinase diphenolase by various salt solutions is shown in FIG. 16. It can be seen from the figure that compared with the inhibition rate of tyrosinase monophenolase, the inhibition rate of tyrosinase diphenolase by the original salt and roasted salt is obviously enhanced, and there is a certain concentration-effect relationship, but the maximum inhibition rate does not exceed 30 %. The tyrosinase diphenolase inhibition of pine salt and bamboo salt is similar to that of monophenolase. The high concentration (5.0%, 10.0%) of the plum salt solution has a diphenolase inhibition rate that is the same as that of pine salt and bamboo salt. The solution has little difference, and the inhibition rate can reach 92.0% at 5%. Compared with the original salt, plant salt has more potassium, iron, magnesium, calcium and other metal elements, which may have a certain effect on the protein structure of tyrosinase, thereby inhibiting its activity.

5.3.2 Effects of plant functional salts on B16 cell proliferation

Table 14 Proliferation rate of B16 cells under the action of each sample

Note: Different letters indicate significant differences at the same concentration (p <0.05), n = 6.

Melanin is produced by melanocytes. Generally speaking, inhibiting melanocyte proliferation can reduce melanin production. The proliferation rate of mouse B16 melanocytes in different concentrations of samples is shown in Table 14. It can be known from Table 14 that various salt solutions with a concentration of 0.25% or more can inhibit the growth of B16 cells, and with the increase of the salt concentration, the cell proliferation rate decreases. At 0.75%, the cell proliferation rates of the salt groups are not significantly different. 1% saline solution will seriously affect the cell growth, and the proliferation rate is less than 10%. In low concentrations (0.25%, 0.5%), the proliferation rate of B16 cells in pine salt, bamboo salt, plum salt, and Korean bamboo salt is not lower than that of the original salt. Therefore, compared with the original salt, plant salt has no effect on B16 cells. Obvious extra cytotoxicity, and the cell proliferation rate in 0.5% pine salt, bamboo salt, and plum salt is much greater than the original salt, indicating that these plant salts have a certain protective effect on B16 cells in the NaCl environment. The cell proliferation rate and concentration of the arbutin group in the positive control group had little relationship with each other, about 70%.

5.3.3 Effect of plant salt on tyrosinase activity in B16 cells

Tyrosinase is a key rate-limiting enzyme for melanin synthesis in B16 cells. Its enzyme activity is an important factor affecting melanin production and an important indicator for measuring the whitening efficacy of functional factors. It can be known from Table 15 that each sample has a certain effect on the tyrosinase activity of B16 cells, and the intracellular tyrosinase activity is significantly reduced, and there is a certain concentration-effect relationship. Compared with the original salt, pine salt, bamboo salt, and Korean bamboo salt have higher tyrosinase activity in each group of cells, indicating that these plant salts have less inhibitory effect on tyrosinase in B16 cells than the original salt. The tyrosinase activity of the cells was lower than that of the original salt at the concentration, indicating that plum salt can significantly reduce the tyrosinase activity of B16 cells, and the effect is better than the test substances in each group. The tyrosinase activity of cells in the positive control arbutin group was higher than that in the salt sample group of the same concentration.

Table 15 Tyrosinase activity of B16 cells under the effect of each sample

5.3.4 Effect of plant salt on B16 cell migration

An important feature of tumor cells is that they can spread and metastasize during proliferation, and their ability to spread can be judged by their degree of migration. As can be seen from FIG. 17, the B16 cells in the normal group (a) basically healed after 48 h of culture, indicating that their migration ability is very strong. When the mass fraction of the test substance was 0.5%, B16 cells treated with the original salt (b) entered only part of the cells in the underlined area, indicating that the original salt had a certain inhibitory effect on cell migration. In the cells treated with pine salt (d), bamboo salt (e), and plum salt (f), there was almost no entry of cells in the underlined area, indicating that these three plant salts can significantly inhibit B16 cell metastasis, and the effect is stronger than the original salt. Arbutin (c) also has a certain inhibitory effect on the mobility of B16 cells, but its effect is not as good as that of plant salts.

5.3.5 Effect of plant salt on B16 cell cycle

The cell cycle refers to the process from the end of cell division to the end of the next cell division. It is divided into four stages, G0 / G1 (pre-DNA synthesis), S (DNA replication), and G2 (DNA replication completed). To the beginning of mitosis), M phase (beginning to the end of cell division). The DNA content of cells in different cycles is different. Using the fluorescent dye PI to stain the cell DNA and detecting the fluorescence intensity in a flow cytometer, you can study the distribution of cells in different cycle stages and understand the cell proliferation. It can be seen from Table 16 that the distribution of cells in the original salt, arbutin group and normal group was not significantly different in the G0 / G1 and S phases, while the distribution ratios of the S and G2 / M phases in the pine salt, bamboo salt, and plum salt groups increased significantly. G0 / G1 phase is less distributed. The sum of the S phase and G2 / M represents the proportion of cells in the process of DNA replication and mitosis, which can indicate the cell's proliferation ability. The results show that the pine salt and bamboo salt groups have better cell proliferation ability, followed by the plum salt group, and the rest of the groups. There were no significant changes in proliferation ability. MTT results show that each test substance has a certain inhibitory effect on the proliferation of the B16 cell population, and cell cycle studies have found that the viability of surviving cells is better. It is speculated that the treatment of the test substance may cause some cell death and be resistant to some The cells have the effect of promoting proliferation.

Table 16 Effect of 0.5% mass fraction of each sample on B16 cell cycle

Note: Different letters indicate significant differences under the same cell cycle (p <0.05), n = 3.

5.4 Conclusion

As three representative plant functional salts, the pine, bamboo, and plum salts provided by the present invention exhibit concentration-dependent inhibition on monophenolase activity and diphenolase activity of tyrosinase in vitro. When the sample concentration is At 10%, the inhibition rates of tyrosinase monophenolase reached 97.8%, 94.2%, and 73.3%, respectively; at a concentration of 5%, the inhibition rates of diphenolase reached 99.9%, 93.0%, and 92.0%, respectively. Plant functional salt has a certain inhibitory effect on B16 cell proliferation, but it has no obvious cytotoxicity compared to the original salt. Plum salt can significantly reduce tyrosinase activity in B16 cells, and B16 cell tyrosinase activity in 0.75% plum salt medium is only 6.07%. At the same time, plant functional salts can significantly inhibit the lateral migration of B16 cells, but do not inhibit their proliferation by affecting the cell cycle. Plant functional salts, as inorganic inhibitors of tyrosinase in vitro and in vivo, have good inhibitory effects, and can be considered as fruit and vegetable fresheners and whitening functional components of the human body.

Experiment 6. Animal experimental study of plant functional salt to prevent hypertension

6.1 Source and grouping of experimental animals

Experimental animals: male rats SD rats, 13-14 weeks old, weighing about 200g. After one week of adaptive feeding, they were randomly divided into 8 groups, namely the control group fed with normal salt, the control group fed with normal saline without salt, the high salt model group, the experimental group (functional salt of pine, bamboo, and plum plants), and the positive control group Felodipine sustained-release tablets), 4 rats in each group, and the experimental design and dosage configuration are shown in Table 17. During the experiment, the animals were raised in a single cage at a temperature of 25 ° C and a humidity of 30%. Clinical manifestations were observed weekly. During the administration period, the rats' daily high salt intake was 4000mg / kg (equivalent to 8% dietary salt). On the premise of free drinking pure water, the samples and control samples were configured to the corresponding concentration. The solution was orally administered to rats daily with 2 mL / 100 g of bamboo saline, pine saline, and plum saline. Except for the normal control group (1 ^# ), which used conventional feed, the other 8 groups used salt-free basic feed.

Table 17 Animal test groups and doses

* In order to ensure the comparability of the test data, a free diet containing 0.3% common salt (group 1 ^# ) and a control group (group 2 ^# ) fed with an equivalent amount of raw saline solution while ingesting salt-free feed were compared. Effects of salt ingestion and salt ingestion on rats.

** References to the amount of high-salt feed group added 8% salt in the feed was converted to the gavage concentration.

6.2 Test situation

Blood pressure and weight were measured every 4 days, and the test lasted 27 days. After the last gastric lavage, fasting and water were not allowed, placed in a metabolic cage for 24 hours and urine was collected. After the end, anesthetic was injected intraperitoneally, and the rats were sacrificed after blood was drawn from the heart.

6.3 Test results

6.3.1 Changes in body weight of experimental rats

There was no significant difference in body weight between animals in each group within 24 days of the experiment, and no significant effect on body weight was observed after gavage or high salt intake.

Table 18 Weight Change Table

Compared with the conventional raw salt (group 2) given by oral administration (group 1), ^Δ indicates p <0.05, ^ΔΔ indicates p <0.01;

In the high salt test group (group 3), compared with the normal salt group (group 2), ^# means p <0.05, ^## means p <0.01;

Compared with the high-salt test group (group 3), each of the high-salt test groups (groups 4 to 8) ^* indicates p <0.05, and ^** indicates p <0.01.

6.3.2 Changes in systolic blood pressure in experimental rats

At the 20th day of high-dose salt gavage, the high-salt test group 3 and the conventional raw salt group 2 had a significant difference, indicating that oral high-dose salt can lead to hypertension, and the experimental modeling was successful. From the experimental group, by the 24th day, the functional salt groups of the pine, bamboo, and plum plants obtained in the examples all had significant differences from the original salt groups, indicating that ingestion of the plant functional salts prepared in this example had the effect of preventing hypertension. It is worth noting that plum salt has the most obvious antihypertensive effect in plant salt, and there is no significant difference with low salt intake. It may be due to the special physicochemical structure and element content of plum salt.

Table 19 Changes in blood pressure in rats

Compared with the conventional raw salt (group 2) given by oral administration (group 1), ^△ indicates p <0.05, ^△△ indicates p <0.01;

6.3.3 24h urine volume change in experimental rats

There was no significant difference between the conventional feed and the conventional raw salt group, indicating that feeding had no significant effect on urine output. Urine output in the high-salt group was significantly higher than that in the normal salt group due to the increase in drinking water caused by ingestion of high-concentration saline. However, in the plant functional salt, the urine volume of bamboo salt was significantly higher than other groups, and a significant difference was formed with the original salt group, indicating that bamboo salt has a significant diuretic effect. It is worth noting that the urine volume of the bamboo salt group is higher than that of the positive control. Felodipine is a selective calcium antagonist that mainly inhibits the influx of extracellular calcium from small arterial smooth muscle, and has urinary sodium excretion and diuretic effects. The results show that the diuretic effect of bamboo salt is particularly significant.

Table 20 Rat urine output values

6.3.4 Analysis results of serum biochemical parameters of experimental rats

(1) Liver function

Alanine aminotransferase (ALT), an enzyme involved in the metabolism of human proteins, is an important indicator of the degree of liver disease. ALT can accelerate the conversion of protein amino acids in the body, and it is the most abundant in liver cells. When tissues and organs are diseased, the ALT in them will be released into the blood, which will increase the serum ALT content. Compared with normal rats, ALT in the serum of the high-salt group was significantly increased, indicating that the liver was damaged.

Aspartate aminotransferase (AST) helps to understand the degree of damage to myocardium, liver and kidney tissue. AST exists in various tissues of the human body, with the heart muscle being the most abundant, followed by the liver. When necrosis of the heart and liver cells occurs, m-AST is released from the mitochondria, which increases the AST in the serum. The AST in the serum of rats in the high-salt group was significantly increased, indicating that the liver was affected to some extent after ingesting high concentrations of salt.

Alkaline phosphatase (ALP) is widely distributed in human liver, bones, intestines, kidneys and placenta. It is excreted by the liver to the gallbladder. It is mainly used for the diagnosis and differential diagnosis of bone, hepatobiliary system diseases. Bone, liver and gallbladder diseases are closely related. There was no significant difference in ALP content between the groups, which indicated that the effect of high-salt diet on ALP in one month was not obvious.

Table 21 liver function indicators

(2) Renal function

Urea nitrogen (BUN) is a nitrogen-containing compound other than protein in the plasma. It is filtered from the glomerulus and excreted. When renal insufficiency is decompensated, BUN will increase. It is used clinically as an index for judging glomerular filtration function; creatinine (CRea) is a metabolic product of muscle tissue in the body, which is mainly excreted by glomerular filtration. When renal insufficiency, creatinine will accumulate in the body It becomes a harmful toxin to the human body; when all the uric acid in the blood is filtered from the glomeruli, abnormal urine processing by the kidneys will increase the blood uric acid (UA) content. It can be seen from the table that there is no significant difference between the indicators in each group within one month, and it may be that the high salt diet time is too short.

Table 22 renal function indicators

(3) Myocardial function

Skeletal muscle, cardiac muscle, and smooth muscle are rich in creatine kinase (CK), which are mainly present in the cytoplasm and mitochondria, and are an important kinase that is directly related to intracellular energy movement, muscle contraction, and ATP regeneration. The measurement of creatine kinase activity can be used for the diagnosis of skeletal muscle disease and myocardial disease. Pathological increase: myocardial infarction, viral myocarditis, dermatomyositis, muscular dystrophy, pericarditis, accidental rupture of cerebral blood vessels, etc. It can be seen from the table that high salt concentration has a significant effect on CK content, and a high salt diet for more than a month may have a certain effect on myocardial function. However, it is worth noting that the CK content of pine salt is significantly lower than that of the high salt group, indicating that pine salt has the potential to prevent myocardial damage.

Lactate dehydrogenase (LDH) is found in almost all tissues and is most abundant in heart, skeletal muscle, and kidney, and can be used for the diagnosis of myocardial disease. Increased lactate dehydrogenase: mainly seen in myocardial infarction, hepatitis, malignant tumors, pulmonary infarction, leukemia, hemolytic anemia, kidney disease, progressive muscle atrophy, etc. The contents of CK and LDH in the high-salt diet were lower than those in the normal salt diet group, which further explained that the high-salt diet had damage to myocardial function.

Table 23 Myocardial function indicators

(4) Serum ion content

The results of one month's experiment showed that there was not much difference in the concentration of each ion in the serum.

Table 24 Serum ion content

6.3.5 Analysis results of urine parameters of experimental rats

(1) Total excretion

Urinary creatinine (CRea) is mainly from the blood. After filtering through the glomerulus, it is eliminated with the urine. The renal tubules are basically not absorbed and excreted rarely. Urine creatinine content changes when kidney problems occur. Normal urine contains a small amount of small molecule protein (U-TP). When protein in the urine increases, proteinuria is formed. Proteinuria is a common manifestation of kidney disease, and proteinuria can also occur in systemic diseases. Urinary microalbumin (U-ALB) is one of the important plasma proteins. Under normal circumstances, albumin has a large molecular weight and cannot cross the glomerular basement membrane. Damage to the glomerular basement membrane during disease results in a change in permeability, leading to the excretion of albumin into the urine, causing the urine albumin concentration to continue to increase. It can be seen from the table that the one-month high-salt diet has significant differences in U-TP and U-ALB contents in SD rats, indicating that renal function is impaired, but there is no significant change in serum kidney indexes and CRea content in urine This indicates that the effect of a high-salt diet for one month is not strong. If a long-term high-salt diet will cause kidney damage. It is worth noting that the U-TP level of pine salt is significantly lower than that of the high salt group, which is equivalent to the positive control, indicating that pine salt also has the effect of protecting renal function.

Table 25 Urine biochemical indicators

(2) excretion of urine calcium, phosphate, magnesium, sodium, potassium and potassium

In addition to the increase in Na and Cl ion content, the K, Ca, and P contents increased significantly in the high-salt group, and the P element in bamboo salt was more pronounced. In the analysis of plant salt elements, neither the original salt nor the P element of a roasted salt was detected, while the salt of Songzhumei was 71.8, 45.3, and 424 mg / kg, respectively. From the physical and chemical indicators of plant functional salt, it can be seen that its element content is significantly more than that of raw salt and roasted salt, but its urine excretion is not significantly different, indicating that the rich elements in plant functional salt are absorbed by the body.

Table 26 Urine ion excretion

6.4 Conclusion

There is no significant difference between ordinary salt and roasted salt in the prevention of hypertension in SD rats, which indicates that roasted salt without added plant extract prepared by the present invention has no special biological effect.

After a month of high-salt diet, the systolic blood pressure of male SD rats significantly increased after taking raw salt, and showed obvious liver, kidney, and myocardial function damage; while the blood pressure of experimental animals ingesting the plant functional salt of the present invention was significantly lower than the original salt , Indicating that it has the potential to replace ordinary edible salt and prevent hypertension.

All documents mentioned in the present invention are incorporated by reference in this application, as if each document was individually incorporated by reference. In addition, it should be understood that after reading the above-mentioned teaching content of the present invention, those skilled in the art can make various changes or modifications to the present invention, and these equivalent forms also fall within the scope defined by the claims attached to this application.

Claims

A functional plant salt, characterized in that the functional plant salt is prepared as follows: one or more plant extract powders are mixed uniformly with fine salt at an addition amount of 1% to 40%, at 800- Roasted once or in multiples at a high temperature of 1400 ° C to obtain functional plant salts.
The functional plant salt according to claim 1, wherein the plant extract is an extract of a substance selected from the group consisting of plum, pine, tea, lotus, chrysanthemum, pomegranate, begonia, edible fungus, algae .
The functional plant salt according to claim 1, wherein the plant extract is a plum extract and / or a pine extract.
The functional plant salt according to claim 3, wherein the plum extract is selected from the group consisting of plum blossom extract, plum fruit extract, plum leaf extract, plum branch extract, plum root extract, or A combination thereof; and / or

The pine extract is selected from the group consisting of pine needle extract, pine bark extract, pine pollen extract, or a combination thereof.
The functional plant salt according to claim 1, wherein the fine salt is selected from the group consisting of sea salt, lake salt, well salt, and mineral salt.
The functional plant salt according to claim 1, wherein the fine salt is a crude sea salt.
The functional plant salt according to claim 1, wherein the functional plant salt is pine salt and / or plum salt.
The functional plant salt according to claim 1, wherein the plant extract further comprises a bamboo extract.
A method for preparing a functional plant salt according to claim 1, comprising the step of: mixing one or more plant extract powders with fine salt at an addition amount of 1% to 40%, uniformly at Roasted once or in multiple times at a high temperature of -1400 ° C to obtain functional plant salts.
The method according to claim 9, wherein said roasting is performed in a mechanized oven.
The method according to claim 9, wherein said roasting is performed in an intermediate frequency melting furnace.
A food or pharmaceutical composition, comprising one or more functional plant salts according to claim 1.
The use of the functional plant salt according to claim 1, characterized in that it is used to prepare a substance selected from the group consisting of a pharmaceutical auxiliary, a health food / drink, a functional food / drink, a table seasoning salt, and a cooking salt , Special-purpose cosmetics or personal care products.