CN108969397B

CN108969397B - Active polypeptide mask and preparation method thereof

Info

Publication number: CN108969397B
Application number: CN201811053262.9A
Authority: CN
Inventors: 宣婕
Original assignee: Barbados Aloe Biotechnology Research Guangzhou Institute
Current assignee: Barbados Aloe Biotechnology Research (Guangzhou) Institute
Priority date: 2018-09-10
Filing date: 2018-09-10
Publication date: 2021-04-30
Anticipated expiration: 2038-09-10
Also published as: CN112410394B; CN112410394A; CN108969397A

Abstract

The invention relates to an active polypeptide mask and a preparation method thereof, belonging to the technical field of cosmetics. The invention provides an active polypeptide mask which has good effects of resisting oxidation and keeping moisture, mainly sturgeon skin is used as an animal source, active polypeptide is obtained through secondary enzymolysis and membrane separation and purification, and the active polypeptide mask is applied to a mask cosmetic and shows good skin anti-aging effect.

Description

Active polypeptide mask and preparation method thereof

Technical Field

The invention relates to an active polypeptide mask and a preparation method thereof, belonging to the technical field of cosmetics.

Background

At present, anti-aging cosmetics account for nearly 40% of the market share in facial care, and with the development of modern social information and the improvement of the knowledge level of consumers, nowadays, young women also add anti-aging emulsions, creams, essences and the like to the daily care step, and anti-aging products have been expanded to a wider age group and product field. The concept of anti-aging products is constantly refreshed, and the main trend is natural and high-tech. The elasticity and source of elasticity of the skin are collagen, which accounts for 70% of the dermis, and the other components of the dermis are elastin, hyaluronic acid, and the like. Fibroblasts are responsible for the synthesis and decomposition of these components, and keep the skin young all the time. The proliferation rate of cells was measured after two days of culture by adding cosmetic peptides to the skin fibroblast culture medium, and it was found that fibroblasts proliferated and had a dependency on the peptide concentration after addition of cosmetic peptides. The antioxidant peptide can also activate the hyaluronic acid-producing ability of the skin.

In recent years, researchers have extracted a plurality of antioxidant peptides from dairy products, animal muscles, bones and skins, LeeD [1] and the like report that octapeptide (941.43 Da) separated from duck skin by-products has IC50 values of 32.6 mug/mL, 22.7 mug/mL, 55.1 mug/mL and 49.8 mug/mL for scavenging hydroxyl radical, DPPH radical, alkyl radical and superoxide anion radical, respectively, and has the effect of relieving liver cell damage caused by alcohol; li jiao [2] and the like are used for preparing antioxidant peptide from goose bone protein, and the clearance rate of superoxide anion free radical reaches 64.14%. In recent years, various major cosmetic companies have successively introduced polypeptide series products [3, 4 ]. The lankou skin-beautifying and firming series contains refined rice peptide, can consolidate the wave structure of a skin connecting layer, accurately lift the facial skin, and enable the skin to recover elasticity and cohesion. The SK-II firming and anti-wrinkle essence milk contains palm tetrapeptide-3, terminal collagen and other collagen repair factors, and can quickly fade fine lines and wrinkles. Venin Royale introduced an anti-aging skin care product Karin Herzog Vitamin H Face Cream containing 27 natural peptides, neuropeptides and neurotoxins. The Tau Collagen Mask is a facial cream containing high-concentration hydrolyzed Collagen, hyaluronic acid and squalene, and the product can improve the skin texture within 7-10 min.

However, there is still a need for a new animal-derived antioxidant peptide with low purity and further improved activity.

Reference documents:

[1] Lee S J, Kim Y S, Hwang J W, et al. Purification and characterization of a novel antioxidative peptide from duck skin by-products that protects liver against oxidative damage[J]. Food Research International, 2012, 49(1):285-295.

[2] the process for preparing the antioxidant peptide by enzymolysis of the goose bone protein is optimized by the technology of food industry science and technology, 2013, 34(20):194-198.

[3] Reineckment, He clever, Dong Yin Mao, the skin aging mechanism and the research progress of cosmetics for delaying aging [ J ]. China journal of beauty and medicine, 2009, 18(8): 1208) 1212.

[4] Manso M A, Miguel M, Even J, et al. Effect of the long-term intake of an egg white hydrolysate on the oxidative status and blood lipid profile of spontaneously hypertensive rats[J]. Food Chemistry, 2008, 109(2):361-7.

Disclosure of Invention

The invention provides an active polypeptide mask which has good effects of resisting oxidation and keeping moisture, mainly sturgeon skin is used as an animal source, active polypeptide is obtained through secondary enzymolysis and membrane separation and purification, and the active polypeptide mask is applied to a mask cosmetic and shows good skin anti-aging effect.

First aspect of the invention:

the active polypeptide facial mask comprises a substrate and a facial mask solution coated on the substrate, wherein the facial mask solution comprises the following components in percentage by weight: 2-5% of sturgeon skin polypeptide, 0.1-0.3% of whitening component, 2-4% of thickening agent, 3-3.5% of emulsifier, 4-6% of water-soluble micromolecule, 0.02-0.04% of preservative, 0.005-0.01% of essence and 85-88% of deionized water.

In one embodiment, the preparation method of the sturgeon skin polypeptide comprises the following steps:

step 1, pretreatment: crushing sturgeon skin, soaking in NaCl solution to remove non-collagen protein, soaking the residue in mixed solution of isopropanol, ether and distilled water to remove fat, and filtering to obtain solid;

step 2, first enzymolysis: dispersing the solid obtained in the step 1 in water, adding HCl to adjust the pH value to 5.5-6.5, then carrying out enzymolysis by using bromelain, and then carrying out enzyme deactivation and pH value adjustment to be neutral to obtain a first enzymolysis product;

step 3, large-aperture ultrafiltration treatment: filtering the first enzymolysis product by using an ultrafiltration membrane to remove impurities;

and 4, concentrating the nanofiltration membrane: adding ZnCl into the ultrafiltration penetrating fluid obtained in the step 3₂Then a nanofiltration membrane with the molecular weight cutoff of 800Da is used for filtering and concentrating;

step 5, carrying out second enzymolysis: adding HCl into the nanofiltration membrane concentrated solution obtained in the step 4 to adjust the pH value to 5.5-6.5, then carrying out enzymolysis by using bromelain, and then carrying out enzyme deactivation and pH value adjustment to be neutral to obtain a second enzymolysis product; and then carrying out reduced pressure concentration and spray drying in sequence to obtain the sturgeon skin polypeptide.

In one embodiment, the concentration of the NaCl solution in step 1 is 5-15%; the weight ratio of the isopropanol to the ether to the distilled water is 2-4: 1-3: 6-10.

In one embodiment, the concentration of the solids in water in step 2 is 0.1-0.5wt%, the amount of enzyme added is 2000U/g substrate, the temperature of the enzymatic hydrolysis is 50-60 deg.C, and the time of enzymatic hydrolysis is 60-120 min.

In one embodiment, the ultrafiltration membrane in step 3 has a molecular weight cut-off of between 20 and 40 million Da.

In one embodiment, Zn in the ultrafiltrate permeate in step 4²⁺The concentration is 0.1-0.5mol/L, and the molecular weight cut-off of the nanofiltration membrane is 500-1000 Da.

In one embodiment, the enzyme amount in step 5 is 4000U/g substrate, the enzymolysis temperature is 45-55 ℃, and the enzymolysis time is 50-70 min.

In one embodiment, the whitening ingredient is selected from pomegranate peel extract.

In one embodiment, the thickening agent is selected from one or a mixture of pectin, sodium hyaluronate, guar gum, xanthan gum, acrylate, carboxymethyl cellulose, cellulose gum or ethyl cellulose.

In one embodiment, the emulsifier is selected from one or more of potassium cetyl phosphate, sodium stearoyl glutamate, sodium stearoyl-cocoyl glutamate.

In one embodiment, the water-soluble small molecule is selected from one or more of glycerol, 1, 3-butanediol, propylene glycol.

In one embodiment, the preservative is one or more of methylparaben, ethylparaben, propylparaben, benzoic acid, and phenoxyethanol.

In one embodiment, the substrate is a nonwoven fabric.

Second aspect of the invention:

the preparation method of the active polypeptide mask comprises the following steps:

dispersing sturgeon skin polypeptide by using a part of deionized water, adding an emulsifier and water-soluble micromolecules, heating to 40-50 ℃, and uniformly stirring;

step b, continuously adding the thickening agent and the other part of deionized water, then adding the whitening component, heating to 55-60 ℃, and uniformly stirring;

c, adding a preservative and essence into the solution obtained in the step b, and uniformly stirring to obtain a mask liquid;

and d, coating the mask liquid on the substrate to obtain the mask liquid.

The third aspect of the present invention:

a sturgeon skin polypeptide is prepared by performing enzymolysis on sturgeon with bromelain.

The fourth aspect of the present invention:

the application of the sturgeon skin polypeptide in cosmetics.

The fifth aspect of the present invention:

the application of the sturgeon skin polypeptide in preparing a medicament for eliminating DPPH free radicals.

The sixth aspect of the present invention:

the application of the sturgeon skin polypeptide in preparing medicaments for eliminating hydroxyl free radicals.

Advantageous effects

According to the invention, through the steps of carrying out enzymolysis on the skin of the sturgeon twice and the like, the sturgeon polypeptide with strong oxidation resistance and high activity is obtained, and the sturgeon polypeptide can show a better skin care effect when being applied to the mask.

In the polypeptide preparation method, the purpose of primary enzymolysis is to carry out primary enzymolysis on the skin of the sturgeon, wherein part of protein with lower activity is not easy to decompose, and macromolecular protein and impurities can be removed in the subsequent ultrafiltration process, so that the activity of the polypeptide can be improved; the subsequent nanofiltration process is to concentrate the first enzymolysis product, and since the pH of the enzymolysis liquid is adjusted by adding HCl and NaOH in the enzymolysis process, the purity of the polypeptide product is not high, and NaCl remains in the polypeptide, therefore, Zn is added into the ultrafiltration permeating liquid²⁺On the one hand, because the nanofiltration membrane is a charged membrane, the charge balance Donnal effect exists on two sides of the membrane, and because the nanofiltration membrane has higher rejection rate to divalent ions, Zn²⁺Will remain with the polypeptide on the retentate side of the nanofiltration membrane, which will force more to remain charge balancedNa⁺The NaCl content in the polypeptide is reduced by permeating the nanofiltration membrane to the permeation side; on the other hand, due to the bromelain pair Zn²⁺Relatively sensitive, Zn²⁺The fish skin polypeptide is retained in nanofiltration trapped fluid, so that the enzymolysis of the fish skin polypeptide is further promoted in the subsequent secondary enzymolysis process, and the obtained polypeptide product has higher activity; still further, due to Zn²⁺Has obvious help to the bacteriostatic activity of the skin surface, Zn²⁺The retention of the polypeptide in the extract product can make the facial mask product capable of promoting the bacteriostatic activity of the skin surface. Therefore, in the steps, the primary screening of high-activity polypeptide and Zn by one-time enzymolysis and ultrafiltration is realized²⁺Promoting NaCl to permeate a nanofiltration membrane and Zn²⁺Retained in nanofiltration concentrated solution to promote secondary enzymolysis and Zn²⁺Promoting the integral synergistic effect of the facial mask on the skin antibacterial activity.

Drawings

FIG. 1 is a UV spectrum of a sturgeon skin polypeptide;

FIG. 2 is a liquid phase exclusion chromatogram of the polypeptide obtained in example 1;

FIG. 3 is a liquid phase exclusion chromatogram of the polypeptide obtained in control example 1;

FIG. 4 is a liquid phase exclusion chromatogram of the polypeptide obtained in control example 2;

FIG. 5 is a comparison of the clearance of DPPH free radicals by polypeptides;

FIG. 6 is a comparison of clearance of hydroxyl radicals by polypeptides;

Detailed Description

EXAMPLE 1 preparation of active Polypeptides

Pretreatment: cutting sturgeon skin, scraping fat, connective tissue and the like under the sturgeon skin, cutting the sturgeon skin into powder, soaking the sturgeon skin in 10wt% of NaCl solution to remove soluble non-collagen, filtering out residues, soaking the residues in isopropanol, ether and distilled water according to the weight ratio of 3: 2: and 8, removing fat from the mixed solution, filtering and drying to obtain the substrate.

Carrying out first enzymolysis: preparing a substrate into 0.2wt% of suspension in deionized water, adjusting the pH to about 6.0 by using dilute HCl, adding bromelain with the enzyme amount of 2000U/g of substrate, performing enzymolysis at 55 ℃ for 90min, then inactivating the enzyme at 100 ℃ for 10min, and adding NaOH to adjust the pH to be neutral to obtain a first enzymolysis product;

and (3) large-aperture ultrafiltration treatment: filtering the first enzymolysis product by adopting an ultrafiltration membrane with the molecular weight cutoff of 30 ten thousand Da, wherein the enzymolysis product penetrates through the ultrafiltration membrane, the protein with lower activity and macromolecular impurities are intercepted by the ultrafiltration membrane, and collecting a penetrating fluid;

and (3) nanofiltration membrane concentration treatment: ZnCl is added into the penetrating fluid of the ultrafiltration membrane₂Of Zn to²⁺The concentration is 0.1mol/L, then a nanofiltration membrane with the molecular weight cutoff of 800Da is adopted for filtering and concentration, the polysaccharide and NaCl in the enzymolysis liquid penetrate through the nanofiltration membrane, and the polypeptide is cut off by the nanofiltration membrane;

and (2) carrying out enzymolysis for the second time, adjusting the pH of the nanofiltration concentrated solution to about 6.5 by using dilute HCl, adding bromelain with the enzyme amount of 4000U/g of substrate, carrying out enzymolysis for 60min at the temperature of 50 ℃, adding NaOH to adjust the pH to be neutral, and carrying out reduced pressure concentration and spray drying on the product to obtain the active polypeptide.

EXAMPLE 2 preparation of active Polypeptides

Pretreatment: cutting sturgeon skin, scraping fat, connective tissue and the like under the sturgeon skin, cutting the sturgeon skin into powder, soaking the sturgeon skin in 12wt% NaCl solution to remove soluble non-collagen, filtering out residues, soaking the residues in isopropanol, ether and distilled water according to a weight ratio of 2: 3: 7, removing fat from the mixed solution, filtering and drying to obtain the substrate.

Carrying out first enzymolysis: preparing a substrate into 0.3wt% of suspension in deionized water, adjusting the pH to about 6.0 by using dilute HCl, adding bromelain with the enzyme amount of 2000U/g of substrate, performing enzymolysis at 50 ℃ for 85min, then inactivating the enzyme at 100 ℃ for 10min, and adding NaOH to adjust the pH to be neutral to obtain a first enzymolysis product;

and (3) large-aperture ultrafiltration treatment: filtering the first enzymolysis product by using an ultrafiltration membrane with the molecular weight cutoff of 20 ten thousand Da, wherein the enzymolysis product penetrates through the ultrafiltration membrane, the protein with lower activity and macromolecular impurities are intercepted by the ultrafiltration membrane, and collecting a penetrating fluid;

and (3) nanofiltration membrane concentration treatment: ZnCl is added into the penetrating fluid of the ultrafiltration membrane₂Of Zn to²⁺The concentration is 0.2mol/L, then a nanofiltration membrane with the molecular weight cutoff of 600Da is adopted for filtering and concentration, the polysaccharide and NaCl in the enzymatic hydrolysate penetrate through the nanofiltration membrane, and the polypeptide is cut off by the nanofiltration membrane;

and (2) carrying out enzymolysis for the second time, adjusting the pH of the nanofiltration concentrated solution to about 6.5 by using dilute HCl, adding bromelain with the enzyme amount of 4000U/g of substrate, carrying out enzymolysis for 65min at the temperature of 55 ℃, adding NaOH to adjust the pH to be neutral, and carrying out reduced pressure concentration and spray drying on the product to obtain the active polypeptide.

EXAMPLE 3 preparation of active Polypeptides

Pretreatment: cutting sturgeon skin, scraping fat, connective tissue and the like under the sturgeon skin, cutting the sturgeon skin into powder, soaking the sturgeon skin in 8wt% of NaCl solution to remove soluble non-collagen, filtering out residues, and soaking the residues in isopropanol, ether and distilled water according to a weight ratio of 2: 3: 9, removing fat from the mixed solution, filtering and drying to obtain the substrate.

Carrying out first enzymolysis: preparing a substrate into 0.2wt% of suspension in deionized water, adjusting the pH to about 6.0 by using dilute HCl, adding bromelain with the enzyme amount of 2000U/g of substrate, carrying out enzymolysis for 75min at 50 ℃, then inactivating the enzyme for 10min at 100 ℃, adding NaOH to adjust the pH to be neutral, and obtaining a first enzymolysis product;

and (3) large-aperture ultrafiltration treatment: filtering the first enzymolysis product by using an ultrafiltration membrane with the molecular weight cutoff of 40 ten thousand Da, wherein the enzymolysis product penetrates through the ultrafiltration membrane, the protein with lower activity and macromolecular impurities are intercepted by the ultrafiltration membrane, and collecting a penetrating fluid;

and (3) nanofiltration membrane concentration treatment: ZnCl is added into the penetrating fluid of the ultrafiltration membrane₂Of Zn to²⁺The concentration is 0.1mol/L, then a nanofiltration membrane with the molecular weight cutoff of 1000Da is adopted for filtering and concentration, the polysaccharide and NaCl in the enzymatic hydrolysate penetrate through the nanofiltration membrane, and the polypeptide is cut off by the nanofiltration membrane;

and (2) carrying out enzymolysis for the second time, adjusting the pH of the nanofiltration concentrated solution to about 6.5 by using dilute HCl, adding bromelain with the enzyme amount of 4000U/g of substrate, carrying out enzymolysis for 55min at the temperature of 55 ℃, adding NaOH to adjust the pH to be neutral, and carrying out reduced pressure concentration and spray drying on the product to obtain the active polypeptide.

Comparative example 1 preparation of active polypeptide

The differences from example 1 are: no secondary enzymolysis treatment is carried out.

and (3) nanofiltration membrane concentration treatment: ZnCl is added into the penetrating fluid of the ultrafiltration membrane₂Of Zn to²⁺And (3) filtering and concentrating the solution with a nanofiltration membrane with the molecular weight cutoff of 800Da at the concentration of 0.1mol/L, allowing polysaccharide and NaCl in the enzymatic hydrolysate to penetrate through the nanofiltration membrane, and the polypeptide to be cutoff by the nanofiltration membrane, and concentrating the nanofiltration concentrate under reduced pressure and spray drying to obtain the active polypeptide.

Control example 2 preparation of active polypeptide

The differences from example 1 are: ZnCl is not added into the ultrafiltration penetrating fluid₂。

and (3) nanofiltration membrane concentration treatment: filtering and concentrating the penetrating fluid of the ultrafiltration membrane by adopting a nanofiltration membrane with the molecular weight cutoff of 800Da, wherein the polysaccharide and NaCl in the enzymolysis fluid penetrate through the nanofiltration membrane, and the polypeptide is intercepted by the nanofiltration membrane;

Example 4 preparation of facial mask

Preparing raw materials according to the weight ratio: 3.875% of sturgeon skin polypeptide prepared in example 1, 0.2% of pomegranate peel extract, 2.2% of guar gum, 3.2% of potassium cetyl phosphate, 4.5% of glycerol, 0.02% of methyl p-hydroxybenzoate, 0.005% of essence and 86% of deionized water.

Dispersing sturgeon skin polypeptide with a part of deionized water, adding potassium cetyl phosphate and glycerol, heating to 40-50 ℃, and uniformly stirring; continuously adding guar gum and the other part of deionized water, adding the whitening component, heating to 55-60 ℃, and uniformly stirring; b, adding methyl p-hydroxybenzoate and essence into the solution obtained in the step b, and uniformly stirring to obtain a mask solution; and coating the mask liquid on a substrate to obtain the mask liquid.

Ultraviolet absorption Spectroscopy

The sturgeon polypeptide obtained in example 1 was prepared into 0.5 mg/mL aqueous solution, 4.0mL was taken, and the sample was scanned within the range of 200 and 400 nm using an ultraviolet-visible spectrophotometer. The results are shown in FIG. 1. As can be seen from the figure, SPHs have a strong absorption peak at 220nm, which is a characteristic absorption peak of peptide bonds in proteins and polypeptides, and a weaker absorption peak near 270 nm, which is a characteristic absorption peak of aromatic amino acids.

Determination of polypeptide content

And (3) determining the content of the sturgeon skin polypeptide by adopting a biuret method. Two molecules of urea (NH) at high temperature₃CONH₃) One molecule of ammonia is removed by reaction to obtain biuret. Peptide bond-containing polypeptide with Cu in biuret reagent²⁺The reaction produces purple complex, which has strong absorption peak at 550nm and can be detected by spectrophotometer. The reaction is only related to the content of the polypeptide, and the color depth of the product is proportional to the content of the polypeptide.

Preparing a biuret reagent: weighing 1.5g of CuSO₄•5H₂O and 6.0gC₄O₆H₄KNa is dissolved in 500mL of deionized water, and after the KNa is fully dissolved, the KNa is transferred into a 1L volumetric flask, 300mL of 10% NaOH is added, the volume is constant, and the KNa is transferred into a brown flask for standby. Adding 1.0mL of 10% TCA into 1.0mL of polypeptide solution, shaking uniformly, standing for 10min, centrifuging at 4000r/min, taking 1.0mL of supernatant, mixing with 4.0mL of biuret reagent, carrying out water bath at 50 ℃ for 10min, and measuring the absorbance value at 550 nm. And drawing a standard curve by using 0-100 mg/mL bovine serum albumin, and using pure water as a reference. The polypeptide content of the sample solution was calculated with reference to the standard curve.

The polypeptide contents prepared in the above examples and comparative examples are as follows:

as can be seen from the table, the polypeptide prepared by the present invention has a higher content.

Relative molecular mass distribution

The relative molecular weight distribution of the sturgeon skin polypeptide is determined by adopting high performance liquid exclusion chromatography, and the test conditions are as follows: waters600 high performance liquid chromatograph, 2487 detector, 220nm wavelength, column temperature 30 ℃, flow rate 0.5mL/min, chromatographic column TSKgel 2000 SWXL, mobile phase trifluoroethanol: acetonitrile: water = 1: 450: 550.

wherein, the molecular weight distribution of the polypeptide of the embodiment 1, the comparison 1 and the comparison 2 is respectively shown in the figures 2-4, and the molecular weight distribution range is sequentially shown in the figures as follows:

as can be seen, the molecular weight of the polypeptide obtained after the second enzymolysis in example 1 is smaller, while the Zn is not added to the ultrafiltration permeate in the comparative example 1²⁺The activity of the protease in the secondary enzymolysis is not high, the molecular weight distribution range is larger than that of the embodiment 1, and the molecular weight of the polypeptide obtained in the comparative example 2 without the secondary enzymolysis is larger.

Amino acid composition of sturgeon skin polypeptide

The amino acid composition of the sturgeon skin polypeptide obtained in example 1 was determined by high performance liquid chromatography after hydrolysis with hydrochloric acid and the hydroxylation rate of proline was calculated. The measurement conditions were: sopium Amino Acid Analysis chromatographic column, linear gradient elution, phase A of 0.2mol/L sodium citrate aqueous solution (pH3.00), phase B of 0.2mol/L sodium borate aqueous solution (pH9.80), eluent flow rate of 0.4mL/min, column temperature of 65 ℃. The amino acid composition is as follows:

determination of DPPH free radical (DPPH.) clearance

DPPH is a highly chemically active radical with a single electron, with a characteristic absorption peak of 517nm, and its alcoholic solution is very stable in deep purple. The antioxidant can undergo a pairing reaction with a single electron of dpph, which reduces its absorption at 517nm and lightens its color. Sucking 2.0mL of samples to be detected with different concentrations, adding 2.0mL of solution (anhydrous ethanol as solvent), mixing, reacting at 25 ℃ in a dark place for 1h, and measuring the absorbance Ai at 517 nm; the control group is 2.0mL of ethanol solution and 2.0mL of sample, and the absorbance is measured to be Aj; the blank was 2.0mL ethanol solution and 2.0mL LDPPH. solution, and the absorbance was measured as A0.

Dpph. clearance = (1- (a)_i-A_j)/A₀)×100%

The DPPH free radical clearance of the sturgeon polypeptides prepared in the above examples and comparative examples is as follows:

as can be seen from the above table, the sturgeon skin prepared by the method has a better DPPH free radical clearance rate, and in the comparative example 2, Zn is not adopted for bromelain in the secondary enzymolysis process²⁺The assistance results in poor enzymolysis effect and reduced polypeptide activity, while the control example 2 only adopts one enzymolysis to make the activity poor.

Determination of hydroxyl radical (. OH) clearance

Using Fe²⁺/H₂O₂The method is used for measuring the clearance rate of the hydroxyl free radical. phenanthroline-Fe²⁺Has strong absorption at 536nm, and can react with o-diazepine-Fe²⁺Oxidation to phenanthrene-Fe³⁺The absorption at 536nm is reduced. The antioxidant has effects of scavenging and neutralizing OH, and can inhibit the oxidation process. Adding 0.5mL of 1.0mmol/L o-diazaphenanthrene ethanol solution, 0.5mL of deionized water, 1.0mL of 0.15mol/L PBS (pH7.4), and 0.5mL of 0.75mmol/L FeSO₄And finally 0.5ml of 0.01% (v/v) H₂O₂Placing into a 37 deg.C water bath kettle, maintaining the temperature for 60min, reacting completely, and measuring absorbance A at 536nm_i(ii) a 0.5mL of deionized water was used in place of H₂O₂The above operation was repeated, and the absorbance was recorded as A₀(ii) a The procedure was repeated with 0.5mL of sample instead of deionized water and the absorbance was recorded as Aj.

OH clearance = (a)_j-A_i)/(A_o-A_i)×100%

The hydroxyl radical clearance of the sturgeon polypeptides prepared in the above examples and comparative examples is as follows:

as can be seen from the above table, the sturgeon skin prepared by the method has better clearance rate for hydroxyl free radicals, and in the comparative example 2, Zn is not adopted for bromelain in the secondary enzymolysis process²⁺The assistance results in poor enzymolysis effect and reduced polypeptide activity, while the control example 2 only adopts one enzymolysis to make the activity poor.

⁺ ²⁺Rejection rate of nanofiltration membrane on Na and Zn ions

Determination of Na in nanofiltration membrane feed and nanofiltration permeate using atomic emission spectrometer⁺And Zn²⁺And (3) calculating the rejection rate of the nanofiltration membrane to ions by adopting the following formula:

R=( C_f -C_p)/C_f×100%

in the formula, C_fIs the ion concentration in the nanofiltration membrane feed, ppm;

C_pthe ion concentration in the nanofiltration membrane penetrating fluid is ppm;

r is the retention,%.

The retention rates of the nanofiltration process for ions in the above examples and comparative examples are as follows:

as can be seen from the table, the addition of Zn to the ultrafiltration permeate was used in the present invention²⁺Ions, effectively improve the Na pair of the nanofiltration membrane⁺The transmittance of (2).

Skin irritation test of face mask

New Zealand white rabbits are used, before acute skin irritation test, the hairs on two sides of the spine of the rabbits are cut off, and the hair removal ranges are about the same6cm²In the actual experiment, the mask prepared in example 4 was cut into 2.5X 2.5 cm²The squares are covered on the skin on the left side, then covered by two layers of gauze and a layer of cellophane, then fixed by using a non-irritant adhesive plaster and a bandage, the external application time is 4 hours, the skin on the right side is used as a control, after the test is finished, the skin is washed by warm water to remove residues, the reaction of the tested skin is observed for 1, 24 and 48 hours respectively, and the skin irritation reaction scoring is carried out by adopting the cosmetic hygiene code. The results are shown below:

as can be seen from the above table, the mask of the present invention is non-irritating to the skin.

Claims

1. The active polypeptide mask comprises a substrate and a mask liquid coated on the substrate, and is characterized in that the mask liquid consists of the following components in percentage by weight: 2-5% of sturgeon skin polypeptide, 0.1-0.3% of whitening component, 2-4% of thickening agent, 3-3.5% of emulsifier, 4-6% of water-soluble micromolecule, 0.02-0.04% of preservative, 0.005-0.01% of essence and 85-88% of deionized water;

the preparation method of the sturgeon skin polypeptide comprises the following steps:

and 4, concentrating the nanofiltration membrane: ZnCl is added into the ultrafiltration penetrating fluid obtained in the step 3₂Is reusedFiltering and concentrating by a nanofiltration membrane with the molecular weight cutoff of 500-;

step 5, carrying out second enzymolysis: adding HCl into the nanofiltration membrane concentrated solution obtained in the step 4 to adjust the pH value to 5.5-6.5, then carrying out enzymolysis by using bromelain, and then carrying out enzyme deactivation and pH value adjustment to be neutral to obtain a second enzymolysis product; then carrying out reduced pressure concentration and spray drying in sequence to obtain the sturgeon skin polypeptide;

the concentration of the NaCl solution in the step 1 is 5-15%; the weight ratio of the isopropanol to the ether to the distilled water is 2-4: 1-3: 6-10; in the step 2, the concentration of the solid in water is 0.1 to 0.5 weight percent, the enzyme adding amount is 2000U/g substrate, the enzymolysis temperature is 50 to 60 ℃, and the enzymolysis time is 60 to 120 min; the cut-off molecular weight of the ultrafiltration membrane in the step 3 is 20-40 ten thousand Da; in step 4, Zn in the ultrafiltrate²⁺The concentration is 0.1-0.5 mol/L; in the step 5, the enzyme adding amount is 4000U/g substrate, the enzymolysis temperature is 45-55 ℃, and the enzymolysis time is 50-70 min;

the whitening component is selected from pomegranate pericarp extract; the water-soluble micromolecules are selected from one or more of glycerol, 1, 3-butanediol and propylene glycol; the antiseptic is one of methyl p-hydroxybenzoate, ethyl p-hydroxybenzoate, propyl p-hydroxybenzoate, benzoic acid or phenoxyethanol.

2. The active polypeptide facial mask as claimed in claim 1, wherein the thickening agent is selected from one or more of pectin, sodium hyaluronate, guar gum, xanthan gum, acrylate, carboxymethyl cellulose, cellulose gum and ethyl cellulose.

3. The active polypeptide mask as claimed in claim 1, wherein the emulsifier is selected from one or more of potassium cetyl phosphate, sodium stearoyl glutamate, sodium stearoyl-cocoyl glutamate; the substrate is non-woven fabric.

4. The method for preparing the active polypeptide mask as claimed in claim 1, which comprises the following steps:

and d, coating the mask liquid on the substrate to obtain the mask liquid.