Dual-function starch-based composite nanoparticles as well as preparation method and application thereof

What is claimed is: 1. A preparation method of dual-function starch-based composite nanoparticles, comprising: hydrolyzing starch to form starch hydrolyzate, thereby obtaining linear dextrin; grading the linear dextrin by using an alcohol-alcohol gradient precipitation method to obtain linear dextrin having homogeneous molecular weight distribution; oxidizing the linear dextrin by adopting a TEMPO/NaClO/NaBr oxidation system to obtain oxidized dextrin; performing complex reaction on a first mixed system containing oxidized dextrin and curcumin to form an oxidized dextrin-curcumin complex; and forming an oxidized dextrin-curcumin/chitosan hydrochloride composite nanoparticles from the oxidized dextrin-curcumin complex and chitosan hydrochloride through electrostatic complexing action, so as to obtain the dual-function starch-based composite nanoparticles, and the dual-function starch-based composite nanoparticles are preferably of a sphere shape and has a particle size of 285.3 nm˜848.6 nm. 2. The preparation method according to claim 1 , comprising: hydrolyzing starch by using α-amylase and pullulanase and grading via alcohol-alcohol gradient precipitation to obtain linear dextrin having homogeneous molecular weight distribution; preferably, the preparation method specifically comprising: heating and gelatinizing corn starch, firstly adding α-amylase in an acetate solution environment, hydrolyzing for 1˜2 h at 50˜60° C., then heating to 100˜110° C. to carry out enzyme deactivation for 10˜20 min, then cooling to 50˜60° C., adding pullulanase to carry out de-branching treatment for 3˜4 h, finally, carrying out enzyme deactivation on the obtained starch hydrolyzate, and then carrying out centrifugation, rotary evaporation and vacuum freeze drying to obtain linear dextrin, wherein preferably, the corn starch particularly comprises any one of high straight-chain corn starch, common corn starch and waxy corn starch or a combination of more than two thereof; particularly preferably, the addition amount of α-amylase in each gram of the corn starch is 2 U˜6 U of enzyme unit, and the addition amount of pullulanase is 20 U˜50 U of enzyme unit; particularly preferably, the hydrolysis degree of the starch hydrolyzate is 18.2˜25.3%; preferably, the preparation method comprising: slowly adding ethanol into linear dextrin dispersion liquid under the condition of continuous stirring so that the final concentration of ethanol is 10%˜60%, and then storing for 24˜28 h at 4˜6° C., and centrifuging to obtain linear dextrin having homogeneous molecular weight distribution, wherein preferably, the polymerization degree of the linear dextrin is 20˜68; preferably, the molecular weight of the linear dextrin is 3.35˜10.9 KDa. 3. The preparation method according to claim 1 , specifically comprising: providing a mixed solution containing TEMPO, NaBr and water; mixing the mixed solution with the linear dextrin, adjusting the pH value of the second mixed system to 10˜10.75, then adding NaClO and keeping the pH value of the second mixed system unchanged, wherein the obtained oxidized dextrin is precipitated when the oxidization degree of the linear dextrin is 30˜90%; preferably, the molar ratio of the glucose unit to TEMPO in the linear dextrin is 1:(0.01˜0.02); preferably, the molar ratio of the glucose unit to NaBr in the linear dextrin is 1:(0.1˜0.3); preferably, the oxidization position of the oxidized dextrin is the C6 site of hydroxyl of dextrin; preferably, the mass ratio of the linear dextrin to NaClO is (25˜70):100; preferably, the oxidization degree of the oxidized dextrin is 30%˜90%. 4. The preparation method according to claim 1 , specifically comprising: providing ethanol solution containing curcumin; providing water dispersion liquid containing the oxidized dextrin, heating for 30˜45 min at 90˜100° C., and then cooling to 65˜80° C.; uniformly mixing the ethanol solution containing curcumin with the water dispersion liquid containing the oxidized dextrin to form the first mixed system, carrying out complex reaction for 2˜4 h at 65˜80° C., and then posttreating to obtain an oxidized dextrin-curcumin complex; preferably, the concentration of curcumin in the ethanol solution containing curcumin is 4˜6 mg/mL; preferably, the concentration of the oxidized dextrin in the water dispersion liquid containing the oxidized dextrin is 8˜12 mg/mL; preferably the load capacity of curcumin in the oxidized dextrin-curcumin complex is 12 μg/mg˜35 μg/mg, and the complexing rate is 8%˜25%. 5. The preparation method according to claim 1 , specifically comprising: uniformly mixing the oxidized dextrin-curcumin complex with chitosan hydrochloride for 30˜45 min in a mass ratio of (1:5)˜(5:1) in a reaction system of 20˜25° C. and pH of 4˜4.5, and forming an oxidized dextrin-curcumin/chitosan hydrochloride composite nanoparticles through electrostatic complexing action. 6. A preparation method of a double-emulsion gel, comprising: preparing a dual-function starch-based composite nanoparticles by using the method according to claim 1 ; uniformly mixing chloride, gelatin or ethanol or glucose with water to form a first aqueous phase solution, and uniformly mixing the first aqueous phase solution with an oil phase component to form primary emulsion; uniformly mixing a second aqueous phase solution containing the dual-function starch-based composite nanoparticles with the primary emulsion by using high pressure homogenization and microfluidization technologies to obtain double emulsion containing gel polysaccharide; and carrying out water bath treatment on the double emulsion containing the gel polysaccharide, adding Ca 2+ , and cooling to obtain double-emulsion gel. 7. The preparation method according to claim 6 , comprising: shearing the mixed solution of the primary emulsion and the second aqueous phase solution by using the high pressure homogenization technology to form crude double emulsion, then further homogenizing the crude double emulsion for 3˜5 times under 103.4˜121 MPa by using the high-pressure microfluidization technology to obtain the double emulsion, wherein preferably, the volume ratio of the primary emulsion to the second aqueous phase solution is (1:9)˜(5:5); preferably, the concentration of the dual-function starch-based composite nanoparticles in the second aqueous phase solution is 0.5˜3 wt %; preferably, gel polysaccharide in the double emulsion containing gel polysaccharide is any one of gellan gum, konjac glucomannan, sodium alginate and pectin or a combination of more than two thereof; particularly preferably, the concentration of the gel polysaccharide in the double emulsion containing the gel polysaccharide is 2˜8 wt %; and/or, the chloride comprises any one of sodium chloride, potassium chloride and magnesium chloride or a combination of more than two thereof; and/or, the volume ratio of the oil phase component to the first aqueous phase solution is (2:8)˜(5:5); and/or, the preparation method comprises: dissolving polyglycerol Ricinus communis alcohol ester or soybean lecithin into an oil phase solvent and heating and stirring at 55˜60° C. for 10-20 min to prepare the oil phase component wherein preferably, the oil phase solvent comprises algae oil; preferably, the quality volume ratio of the polyglycerol Ricinus communis alcohol ester or soybean lecithin to the oil phase solvent is (3˜6):100. 8. The double-emulsion gel prepared by using the method according to claim 6 , wherein preferably, the size of the droplet in the double-emulsion gel is 25.96˜73.33 μm; preferably, the double-emulsion gel has viscoelasticity, self-supporting characteristics and a dense three-dimensional network structure.