计算机模拟酶解制备驴乳清蛋白抗氧化肽的研究

本文选用驴乳清蛋白为原材料,以DPPH自由基清除率为指标,利用计算机模拟酶解驴乳清蛋白,筛选出能够产生抗氧化活性肽的最适蛋白水解酶,以pH、酶解温度、酶底比(质量比)为自变量,采用Design-Expert V8.0.6设计响应面试验,确定以α-胰凝乳蛋白酶酶解驴乳清蛋白制备抗氧化肽的最佳工艺条件。结果表明在底物浓度4%,酶解时间4 h的条件下,当温度达到39℃,pH 8,酶底比4%时得到的酶解肽抗氧化活性最强,10 mg/mL驴乳清蛋白酶解肽的DPPH自由基清除率最高可达46.23%。     

胃蛋白酶水解绿豆分离蛋白的工艺

选用胃蛋白酶对绿豆分离蛋白进行酶法水解,考察了原料预处理条件、pH、温度、底物浓度等对酶解的影响,结果表明：原料预处理最适条件为沸水浴中90℃处理20min,在37℃、pH1．8、底物质量分数7％、酶量6000U／g条件下酶解180min,水解度（DH％）为19．86％,达到了制备小肽的水解度要求。实验证明,经过水解,绿豆分离蛋白各功能特性得到很好的改善。     

丝素肽的制备及其抗氧化活性研究

本文以废蚕丝为原料,通过脱胶精炼、碱性蛋白酶Alcalase2.4降解后得到丝素肽溶液,并采用超氧自由基(O-·2)体系、羟基自由基(·OH)体系、二苯代苦味酰基自由基(DPPH·)体系考察了不同水解度丝素肽体外清除自由基的活性。结果表明,丝素蛋白溶液在底物浓度5%,加酶量([E]/[S])2%,反应温度60℃,p H值8.5时,通过控制反应时间可获得水解度为0~23.92%的丝素肽,在此范围内丝素肽清除自由基的能力随水解度的提高而不断增强,在水解度为23.92%时,丝素肽对超氧自由基(O-·2)的清除率达73.69%,对羟基自由基(·OH)的清除率为82.49%,对二苯代苦味酰基(DPPH·)的清除率为70.79%,抗氧化活性最好。     

响应面法优化黄绿蜜环菌子实体蛋白酶解条件

黄绿蜜环菌（Armillaria luteo—virens Sacc）子实体中蛋白含量很高,采用酶水解黄绿蜜环菌子实体蛋白的方法是生产具有生物学功能特性的活性肽的有效途径。实验采用酸性蛋白酶、中性蛋白酶和碱性蛋白酶水解黄绿蜜环菌子实体蛋白制备生物活性肽。实验中确定了酶解前处理条件,即最适宜的酶制剂为中性蛋白酶。酶解条件的优化采用中心组合响应面分析法：建立数学模型回归分析,模型评价,最后进行验证实验。结果表明：底物浓度为7．6％、加酶量为1．6％、酶解温度为52％、酶解时间为6．4h,此条件下蛋白水解度最高。     

双酶法酶解豌豆蛋白制备高抗氧化多肽的研究

以水解度及DPPH自由基清除能力为指标优选出1398中性蛋白酶和胰蛋白酶分步酶解豌豆分离蛋白,所得豌豆蛋白水解产物(pea protein hydrolysate,PPH)中相对分子量小于2 KDa的多肽占77.07％,对DPPH的半清除浓度(IC50)为3.01 mg/mL;PPH经Sephadex G-25凝胶层析和两次RESOURCETM 3RPC反相层析纯化获得高抗氧化活性峰,经反相层析鉴定为层析纯,当浓度在0.2 mg/mL时,对DPPH的清除率达到62.03％,与同浓度下的谷胱甘肽对DPPH的清除率相近(66.82％).     

花蚬酶解物清除羟自由基作用研究

探讨了不同蛋白酶酶解花蚬蛋白所得酶解物对Fenton体系产生的羟自由基(.OH)的清除效果,然后进行Sephadex G-25凝胶柱分离酶解产物中的抗氧化活性肽,并测定活性肽相对分子质量分布。结果表明:木瓜蛋白酶在50℃、酶解30 min、pH=7.5、酶质量分数0.15%、m(底物)∶m(水)=1∶2的水解条件下,酶解物对羟自由基的清除效果最佳,清除率为86.9%;胰蛋白酶在温度55℃、酶解时间85 min、pH=8.0、酶质量分数0.30%、m(底物)∶m(水)=1∶2的水解条件下,酶解物对羟自由基清除效果最佳,清除率为89.5%。木瓜蛋白酶酶解物在最大洗脱峰时,清除率为84.73%,在最大峰处酶解物中活性肽的相对分子质量为5.68×103;胰蛋白酶酶解物有两个洗脱峰,在最大洗脱峰处分离组分对羟自由基的清除率很低,在较小洗脱峰处,其清除率为88.49%,该峰处活性肽的相对分子质量为1.165×104。     

鲟鱼鱼肠抗氧化肽的提取及抗氧化性

探讨酶法制备具有抗氧化活性的鲟鱼鱼肠抗氧化肽的方法,并进行体外抗氧化活性的测定。结果表明,比较4种蛋白酶酶解产物的抗氧化能力,确定胃蛋白酶为制备鲟鱼鱼肠抗氧化肽的最佳水解用酶;通过单因素试验和正交实验分析得出最适酶解工艺是:胃蛋白酶加酶量3 200 U/g,酶解时间1.5 h,料液比1∶20,温度35℃。其体外抗氧化能力随肽质量浓度增大而增大,在浓度为1.5 mg/mL时,鲟鱼鱼肠抗氧化肽清除DPPH·能力达到Vc的83.64%,对·OH清除率为78.06%,还原力大小约为Vc溶液的1/3。胃蛋白酶酶解鲟鱼鱼肠制备的抗氧化肽具有较好的抗氧化活性,其作为一种潜在的商业抗氧化剂具有良好的应用前景。     

木瓜蛋白酶水解马鹿茸血制备免疫活性肽的研究

选用木瓜蛋白酶对天山马鹿茸血进行水解制备免疫活性肽,确定了最佳水解工艺条件,并测定了三种不同水解度水解物的抗氧化活性和免疫活性。水解度(DH)为6.65%时的水解物具有最高DPPH.清除率,DH12.2%时的水解物具有最高OH.清除率。免疫活性体外检测实验显示,DH12.2%时的水解物促进细胞增值率随着浓度的增大而增大,呈现出良好的线性关系(P<0.05)。结果还显示,OH.清除率与免疫活性之间存在相关性,r=0.87(P<0.05).     

鹿茸血制备ACE抑制肽的酶解条件优化

以天山马鹿的鹿茸血为原料,通过体外检测方法检测不同酶及酶解条件下的产物的ACE抑制肽活性及抗氧化活性。结果表明,以A lcalase碱性蛋白酶水解,底物浓度6%、加酶量40μl/g蛋白、pH 8.0、温度55℃的条件下,酶解3 h,水解度为28.0%,酶解产物的血管紧张素转化酶(angiotensin converting enzym e,ACE)抑制活性可达93.55%,与抗氧化活性呈正相关关系。     

响应面法优化蚕豆蛋白酶解工艺条件的研究

考察了碱性蛋白酶、胰蛋白酶和中性蛋白酶对蚕豆蛋白的酶解效果,探讨了水解度（DH）与酶解产物抗氧化活性间的关系。通过单因素试验和响应面分析法,得到碱性蛋白酶酶解工艺的最佳条件。结果表明,温度50℃、pH8.0、酶底比8%、底物浓度3%条件下酶解3h,水解度0~22%内,碱性蛋白酶较胰蛋白酶和中性蛋白酶水解蚕豆蛋白效果好;DH与还原能力（R2=0.68~0.81）及ABTS清除能力（R2=0.98~0.99）具有较好的相关性,碱性蛋白酶酶解液较其他2个酶解液有较好的还原能力和ABTS清除能力;优化后的最佳酶解工艺参数为：酶底比8%,温度50℃、pH 7.6,对蚕豆蛋白还原能力的影响顺序为酶底比＞pH＞温度;在此条件下,蚕豆蛋白酶解液的还原能力理论值为0.174,验证试验测得还原能力为0.173,与理论值接近。     

响应面法优化米糠淀粉酶法水解工艺

以米糠为原料,对米糠淀粉酶法水解生产葡萄糖的液化工艺进行研究和优化,来提高葡萄糖收率。在单因素试验的基础上,用响应面法对液化工艺进行优化。结果表明,液化工艺的最佳条件为酶用量0.11%、醪浓度25%、pH=6.0、温度88℃,在此条件下得到的液化葡萄糖值(即DX值)平均值为6.54%。然后对此液化液进行糖化,最终得到的糖化液DX值为97.07%。     

发酵麸皮多糖酶辅助提取工艺优化及其生物活性研究

通过响应面法优化提取发酵麸皮多糖的工艺,并评价其体外益生和抗氧化活性。以发酵麸皮多糖的得率为响应值,采用纤维素酶酶解与水浴浸提相结合的方法提取发酵麸皮多糖,以纤维素酶添加量、料液比、水浴浸提温度、水浴浸提时间为试验因素建立数学模型,筛选最佳提取工艺条件。通过测定还原力、DPPH和·OH自由基的清除能力对比发酵和未发酵麸皮多糖的体外抗氧化活性,并通过测定嗜酸乳杆菌、植物乳杆菌、两歧双歧杆菌的生长对比发酵和未发酵麸皮多糖的体外益生活性。结果表明,发酵麸皮多糖最佳提取工艺为:料液比1∶16(w/v),酶添加量1 000 U/g,水浴浸提温度90℃,水浴浸提时间60 min,在此条件下发酵麸皮多糖的得率实测值为73. 35%。发酵麸皮多糖具有较强的DPPH和·OH自由基的清除能力,可促进嗜酸乳杆菌、植物乳杆菌和两歧双歧杆菌的生长。     

樟芝固态发酵产物抗氧化性分析

本文对樟芝谷物固态发酵产物抗氧化性能及活性成分进行了研究.在所选谷物中,樟芝青稞固态发酵产物的乙醇提取物总抗氧化性最好,较未发酵青稞提高了4.02倍.通过无水乙醇50℃水浴振荡提取80 min,其总抗氧化性达到了769.60 U/g.对其抗氧化性能分析发现,樟芝青稞固态发酵乙醇提取物为6 mg/L时,对DP P H自由基、羟基自由基以及超氧阴离子的去除率分别为91.9%、51.2%、61.3%,对铁离子的螯合能力为79.5%.相对于未发酵谷物,大米、小米、玉米以及青稞的樟芝发酵产物中总酚含量均有显著的提升,其中青稞乙醇提取和水提取物中总酚含量分别提高了2.36倍和4.23倍.通过HP LC分析可知,樟芝固态发酵产物含有丰富的活性化合物,包括马来酸衍生物(Antrodin)以及泛醌类衍生物(Antroquinonol),且各组分含量较为均衡;而樟芝液态发酵菌丝体乙醇提取物中主要活性成分为马来酸衍生物,不含有泛醌类化合物.     

Preparation and evaluation of antioxidant peptides from ethanol-soluble proteins hydrolysate of Sphyrna lewini muscle

To get high yield of ethanol-soluble proteins (EP) and the antioxidant peptides from Sphyrna lewini muscle, orthogonal experiments (L(9)(3)(4)) were applied to optimize the best extraction conditions and enzyme hydrolysis conditions. The yield of EP reached 5.903±0.053% under the optimum conditions of ethanol concentration 90%, solvent to material ratio 20:1, extraction temperature of 40°C and extraction time of 80min. The antioxidant SEPH (EP hydrolysate of S. lewini muscle) was prepared by using papain under the optimum conditions of enzymolysis time 2h, total enzyme dose 1.2%, enzymolysis temperature 50°C and pH 6, and its DPPH radical scavenging activity reached 21.76±0.42% at the concentration of 10mg/ml. Two peptides (F42-3 and F42-5) were isolated from SEPH by using ultrafiltration, anion-exchange chromatography, gel filtration chromatography and RP-HPLC. The structures of F42-3 and F42-5 were identified as Trp-Asp-Arg and Pro-Tyr-Phe-Asn-Lys with molecular weights of 475.50Da and 667.77Da, respectively. F42-3 and F42-5 exhibited good scavenging activity on hydroxyl radical (EC(50) 0.15mg/ml and 0.24mg/ml), ABTS radical (EC(50) 0.34mg/ml and 0.12mg/ml), and superoxide anion radical (EC(50) 0.09mg/ml and 0.11mg/ml), but moderate DPPH radical (EC(50) 3.63mg/ml and 4.11mg/ml). F42-3 and F42-5 were also effectively against lipid peroxidation in the model system and peroxyl free radical scavenging in β-carotene linoleic acid assay. Their high activities were due to the smaller size and the presence of antioxidative amino acids within the peptide sequences.     

Hydrolysis of rice bran oil using an immobilized lipase from Candida rugosa in isooctane

The kinetics of enzymatic hydrolysis of rice bran oil in isooctane by immobilized Candida rugosa lipase in a batch reactor showed competitive inhibition by isooctane with a dissociation constant, K1, of 0.92 M. Continuous hydrolysis of rice bran oil was performed in recycling, packed bed reactor with 4352 U of immobilized lipase; the optimum recycle ratio was 9 and the operational half-life was 360 h without isooctane but 288 h with 25% (v/v) isooctane in rice bran oil.     

草菇子实体多肽提取工艺及其抗氧化活性

为了优化草菇子实体多肽的提取工艺和探究其抗氧化活性,以草菇子实体为原料,采用酶解法提取草菇子实体多肽,通过单因素试验得出最佳的酶解工艺,并使用Box-Behnken设计试验组合。结果表明：草菇子实体提取多肽的最佳工艺为料液比1:52 (g/mL)、加酶量7 200 U/g、酶解温度43 ℃,此工艺条件下的多肽得率为67.76%。从1,1-二苯基-2-三硝基苯肼(DPPH)自由基清除能力、铁离子还原能力、超氧阴离子自由基清除能力和羟自由基清除能力4个方面研究其体外抗氧化能力,结果表明,草菇子实体多肽对DPPH自由基清除率为74.11%,超氧阴离子自由基和羟自由基清除率分别在69.64%和91.83%达到稳定,草菇子实体多肽还具有一定的还原力,说明草菇子实体多肽可以作为优质抗氧化肽的良好来源。该研究为草菇多肽的高效制备和抗氧化肽等高附加值产品的研发提供理论依据。     

灵芝液体发酵清除自由基活性产物发酵条件的优化

以红灵芝(Ganoderma.lucidum)为实验菌株,对其液体发酵活性产物清除自由基的发酵条件进行了研究。实验考察了培养基成分对灵芝液体发酵所产生的有效产物清除自由基能力的影响。结果表明,葡萄糖、酵母粉分别为灵芝发酵活性产物清除自由基效果较合适的碳源、氮源,最佳质量浓度分别为40 g.L-1和3 g.L-1,清除自由基的能力分别为55.7%、40.8%和66.5%、50.6%;铁离子对灵芝发酵产物清除超氧阴离子具有明显的效果,适宜质量分数为70×10-6;清除超氧阴离子的能力为54.6%,而硒离子对灵芝发酵产物抑制羟自由基有明显的促进作用,最适的质量分数为90×10-6清除羟自由基的能力为67.7%。油酸能促进灵芝发酵产物的清除超氧阴离子和羟自由基的能力,适宜的质量分数为0.1%,清除两种自由基的能力分别为:73.7%,53%。     

Physico-chemical,Sensory and Toxicity Characteristics of Dipeptidyl Peptidase-IV Inhibitory Peptides from Rice Bran-derived Globulin Using Computational Approaches

Rice processing industry released an enormous amount of the rice bran which is underutilized. Rice bran contains various proteins that can be used for the production of bioactive peptides. These bioactive peptides might be suitable ingredients for the development of functional food products. The objective of this study was to explore the potential of rice bran-derived globulin proteins as a suitable precursor of bioactive peptides with especially reference to dipeptidyl peptidase IV (DPP-IV) inhibitory peptides. The various computational approaches (BLAST, BIOPEP, PeptideRanker, PepDraw, Pepcalc, and ToxinPred) were used to predict the potential of the globulin proteins. Ficain protease majorly released the DPP-IV inhibitory peptides from rice bran-derived globulin proteins as compared with other proteases used in this study. Furthermore, primary structure, physico-chemical, sensory, and allergic characteristics of the theoretically release bioactive DPP-IV inhibitory peptides were also studied. The result of this study provides a theoretical basis for the development of rice bran globulin proteins as a suitable source for the generation of bio-functional ingredients for glycaemic management and further demonstrates the usefulness of computational approaches.     

Value-added subcritical water hydrolysate from rice bran and soybean meal

New value-added product was derived from agricultural by-products: rice bran and soybean meal by means of subcritical water (SW) hydrolysis. The effect of temperature (200-220 degrees C), reaction time (10-30 min), raw material-to-water weight ratio (1:5 and 2:5), was determined on the yields of protein, total amino acids, and reducing sugars in the soluble products. The suitable hydrolysis time was 30 min and the proper weight ratio of the raw material-to-water was 1:5. The reaction temperature suitable for the production of protein and amino acids was 220 degrees C for raw and deoiled rice bran, 210 degrees C for raw soybean meal, and 200 degrees C for deoiled soybean meal. The products were also found to have antioxidant activity as tested by ABTS(.)(+) scavenging assay. In addition, sensory evaluation of milk added with the hydrolysis product of deoiled rice bran indicated the potential use of the product as a nutritious drink.