肉豆蔻精油微胶囊化及其稳定性研究

目的：肉豆蔻精油因刺激性气味及易挥发的特点限制了其在食品中的应用,为提高肉豆蔻精油的适用性,利用喷雾干燥技术制备肉豆蔻精油微胶囊。方法：以辛烯基琥珀酸淀粉酯/麦芽糊精（OSA/MD）为复合壁材制备微胶囊,采用气相色谱—质谱联用（GC MS）法测定了包埋前后肉豆蔻精油的成分组成及相对含量,并对微胶囊稳定性进行考察。结果：制备的肉豆蔻精油微胶囊包埋率和保留率分别达到99.28%和88.15%,且40℃时保持稳定。结论：以辛烯基琥珀酸淀粉酯/麦芽糊精（OSA/MD）为复合壁材,利用喷雾干燥技术制备肉豆蔻精油微胶囊包埋效果好,且稳定性得到明显提高。     

灵芝孢子油微胶囊制备技术

灵芝孢子油是从灵芝孢子粉中提取的具有一定药理活性的脂质成分。为提高灵芝孢子油稳定性,以大豆分离蛋白和麦芽糊精为壁材,采用喷雾干燥法和冷冻干燥法制备灵芝孢子油微胶囊。通过试验优化了制备工艺条件并比较了两者干燥方式制备微胶囊的理化性质。结果表明：最佳工艺为大豆分离蛋白和麦芽糊精质量比1:1、固形物含量20%、均质压力30MPa、壁材芯材质量比4:1。两种干燥方式微胶囊流动性、溶解性均较好,差异不显著。但两种微胶囊形态差异较大,喷雾干燥微胶囊整体呈球状、表面紧密无裂缝有凹陷,包埋率为90.84%;冷冻干燥微胶囊结构疏松呈片状,表面多孔。因此喷雾干燥法更适合包埋灵芝孢子油。     

微胶囊化蒜粉的工艺研究

蒜粉微胶囊化工艺可以保护蒜粉中的生物活性物质不被破坏.本文研究了不同的工艺条件对微胶囊化蒜粉的产率和效率的影响.结果表明最佳工艺条件为:蒜粉粒径范围30～100目,EC壁材溶液浓度3%,心材与壁材比4∶ 1,壁材与聚乙二醇(PEG)比4∶ 1,此时微胶囊化产率和效率分别达到95%和96.8%.     

响应面法优化火麻仁油微胶囊喷雾干燥工艺的研究

为了制备包埋率高、稳定性好的火麻仁油微胶囊,拓展其在食品领域的应用范围,以火麻仁油为芯材、单双脂肪酸甘油酯为乳化剂、酪蛋白酸钠为壁材、固体玉米糖浆为填充剂、柠檬酸钠为缓冲盐、抗坏血酸棕榈酸钠为抗氧化剂,通过喷雾干燥法制备60%载油率的火麻仁油微胶囊,以微胶囊包埋率为响应值,在单因素实验的基础上,以干物浓度、进风温度、出风温度为实验因素,采用Box-Behnken响应面分析法进行优化。随后通过扫描电镜观察火麻仁油微胶囊表面形态结构,以确定包埋效果。并利用油脂氧化分析仪检测火麻仁油微胶囊的氧化稳定性。研究确定微胶囊的最佳工艺条件为：干物浓度42%、进风温度168 ℃、出风温度74 ℃,在此条件下制备得到的火麻仁油微胶囊包埋率可达92.15%。通过扫描电镜观察到火麻仁油微胶囊表面圆滑无裂痕,表明火麻仁油微胶囊包埋效果比较理想。经油脂氧化分析仪测定,与对照组（火麻仁油）相比,试验组（火麻仁油微胶囊）的氧化诱导期时间较长,能够达到30 h以上,说明通过对火麻仁油进行微胶囊包埋可以较大程度地提高油脂的稳定性。研究结果为火麻仁油在食品工业领域的开发和应用提供了理论支持。     

鲟源嗜水气单胞菌拮抗解淀粉芽孢杆菌微胶囊的制备工艺及其特性

【目的】优化鲟源嗜水气单胞菌拮抗解淀粉芽孢杆菌微胶囊的制备工艺,并观察其特性。【方法】以明胶为壁材,采用单因素法,考察了明胶浓度、进风温度、进料速度、空气流量等因素对解淀粉芽孢杆菌微胶囊有效含菌量的影响,并进一步通过正交试验设计优化制备解淀粉芽孢杆菌微胶囊的喷雾干燥工艺参数,观察其微胶囊颗粒形态以及对人工模拟胃液和肠液的耐受力。【结果】解淀粉芽孢杆菌微胶囊喷雾干燥的最佳制备工艺条件为:明胶浓度为3%,进风温度为155°C,进料速度为8 mL/min,空气流量为700 L/h,各因素对其喷雾干燥工艺的影响程度为:明胶浓度进料速度空气流量进风温度。此外,解淀粉芽孢杆菌微胶囊的颗粒呈球形,表面有凹陷,但没有孔和裂纹,颗粒粒径分布基本均匀,平均大小为9.22μm,对人工模拟胃液和肠液具有较好的耐受力,对鲟源嗜水气单胞菌具有良好的生长抑制效果。【结论】本研究结果为鲟源嗜水气单胞菌拮抗解淀粉芽孢杆菌微胶囊的工业化生产奠定了基础。     

静电喷雾法制备乳酸菌微胶囊的实验研究

目的为解决乳酸菌产品活菌数的不稳定性,对乳酸菌进行微胶囊化包埋。方法用海藻酸钠和明胶的混合体系作为壁材,对乳酸菌进行静电喷雾包埋处理,并让微胶囊化乳酸菌在模拟胃肠液的环境中进行耐酸性和肠溶性实验。结果混合体系的壁材与乳酸菌具有较好的生物相容性,优选得出当芯壁材为12时包埋率最高（96．3％）,微胶囊化乳酸菌在经人工胃液处理2h后,活菌数比未经微胶囊化的对照组高出2个数量级,且在经人工肠液处理40min后,乳酸菌几乎全部释放。结论静电喷雾法制备的乳酸菌微胶囊具有一定耐酸性和肠溶性。     

不同壁材微胶囊饲料对黄姑鱼稚鱼生长和消化酶活力的影响

研究采用湿法制粒流化床包衣工艺, 分别以明胶、乙基纤维素、玉米醇溶蛋白为壁材制备微胶囊饲料, 比较其对黄姑鱼稚鱼生长和消化酶活力的影响. 粒径(178-590) m的3种微胶囊饲料质量均大于50%. 扫描电镜观察微胶囊饲料的表面均有一层较为致密的包衣薄膜. 壁材明胶、乙基纤维素、玉米醇溶蛋白微胶囊饲料的包含率分别为95.4%、95.6%和95.8%; 脂类包埋率分别为72.6%、76.5%和64.3%; 氮保留率分别为53.5%、62.3%和54.6%. 将3种微胶囊饲料分别饲喂15日龄黄姑鱼稚鱼30d. 明胶组和玉米醇溶蛋白组稚鱼的体重、全长均显著高于乙基纤维素组(P0.05), 但成活率差异不显著(P0.05); 明胶组稚鱼的体重、全长和成活率均高于玉米醇溶蛋白组, 但差异均不显著(P0.05). 明胶组稚鱼的胰蛋白酶活力显著高于乙基纤维素组和玉米醇溶蛋白组(P0.05), 但淀粉酶和碱性磷酸酶活力的差异均不显著(P0.05). 与乙基纤维素、玉米醇溶蛋白相比, 明胶更适合作为黄姑鱼稚鱼微胶囊饲料壁材.       

海洋环境来源的淀粉酶AmyP对生玉米 淀粉的降解特性

来自海洋宏基因组文库的 α-淀粉酶（AmyP）属于最新建立的糖苷水解酶亚家族GH13₃7。AmyP 是一个生淀粉降解酶,能有效降解玉米生淀粉。在最适反应条件 pH 7.5和 40 °C 下,生玉米淀粉的比活达到 39.6 ± 1.4 U/mg。酶解反应动力学显示 AmyP 可以非常快速的降解生玉米淀粉。对 1%的生玉米淀粉仅需要 30 min;4%和 8%的生玉米淀粉只需 3 h。DTT 可以显著提高 AmyP 对生玉米淀粉的降解活性,1% DTT 促使活性增加 1倍。根据电镜观察和产物分析,认为 AmyP 是以内腐蚀的模式降解生玉米淀粉颗粒,释放出葡萄糖、麦芽糖和麦芽三糖作为终产物。     

荔枝核淀粉特性研究

本文采用扫描电镜观察荔枝核淀粉颗粒呈椭圆或多边形。差示扫描量热仪分析荔枝核淀粉的热力学特性表明,其起始温度、峰温度、终止温度和吸热焓值分别为69．04℃、78．79℃、87．08℃和7．5J/g。X射线衍射分析表明荔枝核淀粉呈C型结晶。Brabender粘度分析表明荔枝核淀粉糊化温度为85．3℃,淀粉糊高温稳定。     

双歧杆菌NQ1501双层微胶囊制备及其特性研究

目的提高双歧杆菌NQ1501对环境的耐受性。方法采用流化床底喷工艺,以蔗糖、麦芽糊精、海藻糖和改性淀粉为内层壁材,聚丙烯酸树脂为外层壁材制备双歧杆菌NQ1501微胶囊,并对制得微囊进行评价。结果制得4种双歧杆菌NQ1501微胶囊均具有较好的耐酸和肠溶能力,25℃贮存6个月后对照菌粉存活率为4.8%,采用4种不同内壁材的微胶囊存活率分别为蔗糖28.6%,麦芽糊精45.7%,海藻糖38.9%,改性淀粉55.2%。结论采用该制备工艺制得双歧杆菌NQ1501微胶囊具备较好的耐酸性、肠溶性和常温保存稳定性。     

Process optimization for the synthesis of octenyl succinyl derivative of waxy corn and amaranth starches

Modification of starch by dicarboxylic acid anhydrides to starch esters, containing both hydrophilic and hydrophobic groups are known to improve its emulsification properties, and can also be used for encapsulation after hydrolysis. Reports on the effect of process conditions on the extent of modification of starches by using n-octenyl succinic anhydride (n-OSA) are not readily available. In the present study, the process of manufacturing of OSA starches from waxy corn and amaranth starch were studied with respect to the OSA/starch ratio, pH, temperature and time of the reaction. The effects of these parameters were evaluated on the basis of degree of substitution (DS). The concluding conditions for amaranth-OSA starches was a reaction time of 6 h at 3% OSA/starch ratio at 30 °C and pH 8.0 at 25% starch concentration. For waxy corn-OSA starch, all parameters were identical except for the reaction time of 24 h. The maximum DS achieved for both the starches was 0.02. Emulsification capacity and oil absorption capacity of the OSA-modified starches were more or less similar within the parameter chosen and also independent of starch type.     

The effect of process conditions on the alpha-amylolytic hydrolysis of amylopectin potato starch: An experimental design approach

The hydrolysis of amylopectin potato starch with Bacillus licheniformis alpha-amylase (Maxamyl) was studied under industrially relevant conditions (i.e. high dry-weight concentrations). The following ranges of process conditions were chosen and investigated by means of an experimental design: pH [5.6-7.6]; calcium addition [0-120 microg/g]; temperature [63-97 degrees C]; dry-weight concentration [3-37% [w/w]]; enzyme dosage [27.6-372.4 microL/kg] and stirring [0-200 rpm]. The rate of hydrolysis was followed as a function of the theoretical dextrose equivalent. The highest rate (at a dextrose equivalent of 10) was observed at high temperature (90 degrees C) and low pH (6). At a higher pH (7.2), the maximum temperature of hydrolysis shifted to a lower value. Also, high levels of calcium resulted in a decrease of the maximum temperature of hydrolysis. The pH, temperature, and the amount of enzyme added showed interactive effects on the observed rate of hydrolysis. No product or substrate inhibition was observed. Stirring did not effect the rate of hydrolysis. The oligosaccharide composition after hydrolysis (at a certain dextrose equivalent) did depend on the reaction temperature. The level of maltopentaose [15-24% [w/w]], a major product of starch hydrolysis by B. licheniformis alpha-amylase, was influenced mostly by temperature.     

Development of waxy cassava with different Biological and physico-chemical characteristics of starches for industrial applications

The quality of cassava starch, an important trait in cassava breeding programs, determines its applications in various industries. For example, development of waxy (having a low level of amylose) cassava is in demand. Amylose is synthesized by granule-bound starch synthase I (GBSSI) in plants, and therefore, down-regulation of GBSSI expression in cassava might lead to reduced amylose content. We produced 63 transgenic cassava plant lines that express hair-pin dsRNAs homologous to the cassava GBSSI conserved region under the control of the vascular-specific promoter p54/1.0 from cassava (p54/1.0::GBSSI-RNAi) or cauliflower mosaic virus (CaMV) 35S (35S::GBSSI-RNAi). After the screening storage roots and starch granules from field-grown plants with iodine staining, the waxy phenotype was discovered: p54/1.0::GBSSI-RNAi line A8 and 35S::GBSSI-RNAi lines B9, B10, and B23. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that there was no detectable GBSSI protein in the starch granules of plants with the waxy phenotype. Further, the amylose content of transgenic starches was significantly reduced (<5%) compared with the level in starch granules from the wild-type (about 25%). The inner structure of the waxy starch granules differed from that of the untransformed ones, as revealed by transmission electron microscopy analysis as well as morphological changes in the iodine-starch complex. Endothermic enthalpy was reduced in waxy cassava starches, according to differential scanning calorimeter analysis. Except B9, all waxy starches displayed the A-type X-ray diffraction pattern. Amylogram patterns of the waxy cassava starches were analyzed using a rapid viscosity analyzer and found to have increased values for clarity, peak viscosity, gel breakdown, and swelling index. Setback, consistency, and solubility were notably reduced. Therefore, waxy cassava with novel starch in its storage roots was produced using the biotechnological approach, promoting its industrial utilization.     

Starch biosynthesis: sucrose as a substrate for the synthesis of a highly branched component found in 12 varieties of starches

D-[14C]glucose was incorporated into starch when 12 varieties of starch granules were incubated with [14C]sucrose. Digestion of the 14C-labeled starches with porcine pancreatic alpha amylase showed that a high percentage (16.1-84.1%) of the synthesized starch gave a relatively high molecular weight alpha-limit dextrin. Hydrolysis of the 12 varieties of starch granules by alpha amylase, without sucrose treatment, also gave an alpha-limit dextrin, ranging in amounts from 0.51% (w/w) for amylomaize-7 starch to 8.47% (w/w) for rice starch. These alpha-limit dextrins had relatively high molecular weights, 2.47 kDa for amylomaize-7 starch to 5.75 kDa for waxy maize starch, and a high degree of alpha-(1-->6) branching, ranging from 15.6% for rice starch to 41.1% for shoti starch. ADPGlc and UDPGlc did not synthesize a significant amount (1-2%) of the branched component, suggesting that sucrose is the probable substrate for the in vivo synthesis of the component and that sucrose is not first converted into a nucleotide-glucose diphosphate intermediate.     

Differences in Free Volume Elements of the Carrier Matrix Affect the Stability of Microencapsulated Lipophilic Food Ingredients

Fish oil was encapsulated by spray-drying into different matrices based on n-octenylsuccinate-derivatised starch (nOSA starch) and carbohydrate blends varying in dextrose equivalent and molecular weight profile. Based on the development of the hydroperoxide and propanal content upon storage significant differences in the stability of the microencapsulated oil were observed. With 40 mmol/kg oil the hydroperoxide content after eight weeks of storage at 20 °C and 33% relative humidity was lowest in fish oil encapsulated in a matrix containing nOSA starch and maltose. In contrast, the lowest stability was observed in fish oil encapsulated in a matrix based on nOSA starch and maltodextrin with a dextrose equivalent of 18. Physical characteristics like viscosity of the feed emulsion and oil droplet size, which influence drying behaviour as well as particle characteristics like particle size, density or surface area did not differ and thus cannot explain the differences in the rate of autoxidation. Positron annihilation lifetime spectroscopy clearly showed distinct differences in the ortho-positronium lifetime, and thus in the size of free volume elements between the carrier matrices. It is suggested that as a consequence, the matrices differed in oxygen diffusivity, which must be considered to be a key determinant in autoxidation of fish oil encapsulated in glassy carbohydrate matrices.     

Pasting viscosity and in vitro digestibility of retrograded waxy and normal corn starch powders

Pasting viscosity and in vitro digestibility of oven-dried powders of waxy and normal corn starch gels (40% solids) retrograded under an isothermal (4 °C) or temperature cycled (4/30 °C) storage were investigated. Temperature cycling induced higher onset temperature for melting of amylopectin crystals than isothermal storage under a differential scanning calorimeter whereas little difference in crystalline type was observed under X-ray diffraction analysis. Temperature cycling caused higher pasting temperature and viscosity for the retrograded starches than isothermal storage. The retrograded waxy corn starch powders exhibited pasting behaviors similar to that of native waxy corn starch. However, the retrograded normal corn starch powders showed very much different pasting patterns with lower pasting viscosity but higher pasting temperature than native starch counterpart. The retrogradation increased slowly digestible starch content without changing resistant starch content, more effectively by the temperature cycling than the isothermal storage.     

不同类型玉米籽粒的营养品质及其与籽粒质地的关系

测定普通玉米、爆裂玉米、糯玉米和甜玉米4种类型玉米籽粒不同发育时期的直链淀粉、支链淀粉、总淀粉、可溶性糖和蛋白的含量,分析这些营养物质与角质率的关系。结果表明：灌浆期间4种类型玉米的直链淀粉、支链淀粉和总淀粉含量呈上升趋势,总蛋白含量呈下降趋势,可溶性糖含量变化规律不明显。爆裂玉米的直链淀粉含量始终最高（4．7％-23．1％）,甜玉米（1．4％-4．6％）和糯玉米（2．3％-4．9％）的始终较低;甜玉米的支链淀粉含量一直最低（15．7％-35．5％）,除授粉10d以外,糯玉米的支链淀粉含量一直最高（65．5％-69．8％）;甜玉米总淀粉含量始终最低（17．1％36.1％）、总蛋白含量（15．2％-26．9％）和授粉30d后的可溶性糖含量最高（14．2％-17．6％）。高蛋白含量可能是爆裂玉米和甜玉米角质率高的原因,糯玉米的角质率低可能与支链淀粉含量高和蛋白积累少有关。     

Extrusion processing of high amylose potato starch materials

Thermoplastic starch was prepared by mixing native high amylose potato starch and normal potato starch in a Buss co-kneading extruder at starch to glycerol ratios of 100:45 and 100:30. The materials were also conditioned to different moisture contents at different relative humidities at 23 °C. After the mixing, the compounds were extruded into sheets with a Brabender laboratory extruder. The thermoplastic high amylose materials exhibited a higher melt viscosity than the normal potato starch materials when conditioned at 53% relative humidity. Increasing the moisture content in HAP from 27% to 30% (by weight) lowered the melt viscosity to the same level as that of normal potato starch with a moisture content of 28%. In general, the high amylose materials were more difficult to extrude than the thermoplastic material based on normal starch. The main extrusion problems encountered with the high amylose starch were unstable flow, insufficient melt tenacity and clogging of the die. By increasing the moisture content, increasing the compression ratio of the screw and increasing the rotation rate of the screw, the problems were reduced or eliminated. However, only with a starch to glycerol ratio of 100:45 was an acceptable extrusion result obtained. Extruded sheets of such high amylose materials had a stress at break of about 5 MPa at room temperature and 53% relative humidity, whereas the corresponding value for normal potato (thermoplastic) starch was 3 MPa. The elongation at break was also higher in the case of the high amylose material. The results are discussed in terms of residual crystallinity of the starch materials.     

Comparison of Immobilized and Free Amyloglucosidase Process in Glucose SyrupsProduction from White Sorghum Starch

Optimum conditions for glucose syrups production from white sorghum were studied through sequential liquefaction and saccharification processes. In the liquefaction process, a maximum dextrose equivalent (DE) of 10.98 % was achieved using 30 % (w/v) of starch and Termamyl ɑ-amylase from Bacillus licheniformis. Saccharification was performed by free and immobilized amyloglucosidase from Rhizopus mold at 1 % (w/v). DE values of 88.32 % and 79.95 % were obtained from 30 % (w/v) of starch with, respectively, free and immobilized enzyme. The immobilized Amyloglucosidase in calcium alginate beads showed reusable capacity for up to 6 cycles with 46 % of the original activity retained. The kinetic behaviour of immobilized and free enzyme gives K_m value of 22.13 and 16.55 mg mL⁻¹ and V_max of 0.69 and 1.61 mg mL⁻¹ min⁻¹, respectively. The hydrolysis yield using immobilized amyloglucosidase were lower than that of the free one. However, it is relevant to reuse enzyme without losing activity in order to trim down the overall costs of enzymatic bioprocesses as starch transformation into required products in industrial manufacturing. Hydrolysis of sorghum starch using immobilized amyloglucosidase represents a promising alternative towards the development of the glucose syrups production process and its utilization in various industries.     

Damaged starch characterisation by ultracentrifugation

The relative molecular size distributions of a selection of starches (waxy maize, pea and maize) that had received differing amounts of damage from ball milling (as quantified by susceptibility to alpha-amylase) were compared using analytical ultracentrifugation. Starch samples were solubilised in 90% dimethyl sulfoxide, and relative size distributions were determined in terms of the apparent distribution of sedimentation coefficients g*(s) versus s(20,w). For comparison purposes, the sedimentation coefficients were normalised to standard conditions of density and viscosity of water at 20 degrees C, and measurements were made with a standard starch loading concentration of 8 mg/mL. The modal molecular size of the native unmilled alpha-glucans were found to be approximately 50S, 51S and 79S for the waxy maize, pea and maize amylopectin molecules, respectively, whilst the pea and maize amylose modal molecular sizes were approximately 14S and approximately 12S, respectively. As the amount of damaged starch increased, the amylopectin molecules were eventually fragmented, and several components appeared, with the smallest fractions approaching the sedimentation coefficient values of amylose. For the waxy maize starch, the 50S material (amylopectin) was gradually converted to 14S, and the degradation process included the appearance of 24S material. For the pea starch, the situation was more complicated than the waxy maize due to the presence of amylose. As the amylopectin molecules (51S) were depolymerised by damage within this starch, low-molecular-weight fragments added to the proportion of the amylose fraction (14S)--although tending towards the high-molecular-weight region of this fraction. As normal maize starch was progressively damaged, a greater number of fragments appeared to be generated compared to the other two starches. Here, the 79S amylopectin peak (native starch) was gradually converted into 61 and 46S material and eventually to 11S material with a molecular size comparable to amylose. Amylose did not appear to be degraded, implying that all the damage was focused on the amylopectin fraction in all three cases. Specific differences in the damage profiles for the pea and maize starches may reflect the effect of lipid-complexed amylose in the maize starch.