高产植酸酶乳酸菌及其黑豆酸面团发酵低植酸营养面包研究

从自然发酵的黑豆中筛选出一株具有高植酸酶活性的乳酸菌L-19并将其作为发酵剂制作黑豆酸面团。通过响应面分析法对黑豆酸面团的发酵工艺进行优化,探究最佳发酵条件下目标菌株的生长及产酸特性,并分析体系中多肽的分子量分布及抗营养因子含量变化,同时以感官品评的方式对黑豆酸面团面包的烘焙特性进行评价。结果表明:乳酸菌L-19经鉴定为乳酸片球菌(Pediococcus acidilactici),其胞外酶与胞内酶活性分别为1.36,0.30 U/mL。通过响应面设计确定的最优发酵条件为面团得率(DY)300、发酵温度37℃、接种量8%,黑豆基质中,目标菌株生长良好、酸化能力适中。黑豆酸面团经发酵后,体系中的多种抗营养因子得到有效降解,其中植酸降解率高达62.70%。此外,黑豆蛋白水解后释放出多种肽,其中小分子肽占比达51.47%。与对照组相比,L-19黑豆酸面团面包表现出更高的整体可接受度。因此,乳酸片球菌L-19能够有效改善黑豆酸面团面包的营养及感官品质,具有较佳的应用潜力。     

不同发酵基质的酸面团对酵母面团体系面包烘焙及老化特性的影响

应用分离自我国传统酸面团的区域特色乳酸菌--旧金山乳杆菌分别发酵小麦粉和小麦麸皮基质制成（小麦/麦麸）酸面团,研究了两种不同发酵基质的酸面团及其添加量对酵母面团体系面包烘焙及老化特性的影响。结果表明：与小麦粉制作的空白组面包相比,小麦酸面团可以明显改善面包的比容和感官品质;添加未发酵麦麸制作的非酸面团麦麸面包品质低于空白组,但引入麦麸酸面团（10%、20%、30%）后面包比容和感官评定得分均高于相对应的非酸面团麦麸面包。小麦酸面团和麦麸酸面团以及小麦麸皮均可以改善面包的老化特性,在相同贮藏期内,酸面团面包和麦麸面包的硬度增加量、水分迁移量和老化焓值都低于空白组,并且添加麦麸酸面团的面包其硬度和老化焓值都低于相对应的非酸面团麦麸面包。     

高产植酸酶乳酸菌发酵对黑豆面包蛋白质品质及烘焙特性的影响

从实验室获得1 株高产植酸酶乳酸菌（L-19）并应用于黑豆酸面团面包,同时选用不产植酸酶的乳酸菌（K-12）作为对照。通过分析面包氨基酸组成和营养指标、蛋白质体外消化率、质构特性、超微结构和感官评定,研究其对黑豆酸面团面包蛋白质营养及烘焙学特性的影响。结果表明：添加乳酸菌黑豆酸面团后,面包蛋白营养和烘焙品质都得到了明显改善,其中L-19酸面团面包（L-19SDB）效果最显著。与黑豆面包（BB）相比,L-19SDB植酸含量下降60.68%,蛋白质体外消化率由64.70%升高至73.93%,总氨基酸含量提高73%。同时与其他3 组相比,L-19SDB有更好的氨基酸特征：其必需氨基酸与总氨基酸之比、必需氨基酸指数和生物价均为最高。面包烘焙品质方面,相比黑豆面包BB,L-19SDB和K-12SDB比容分别提高了31.45%和23.59%,硬度降低了68.79%和56.59%。通过ImageJ分析发现,L-19SDB芯囊组织更加均匀,感官评价总体可接受度最高（7.72 分）。     

乳酸菌发酵剂对杂粮面团及馒头品质的影响

为研究混合乳酸菌发酵对杂粮面团及馒头品质的影响,将黄豌豆粉、莜麦粉、谷朊粉及燕麦β-葡聚糖（oatmeal β-glucan,OBG）复配成杂粮粉基质,利用直投式混合乳酸菌发酵剂发酵面团制作馒头。探究乳酸菌在面团中的酸化能力,分析杂粮面团中OBG、抗性淀粉（resistant starch,RS）和游离氨基酸含量的变化以及面团的微观结构变化,并对发酵前后的杂粮馒头和小麦粉馒头进行品质及营养特性比较。结果表明,在发酵杂粮面团中乳酸菌酸化能力强,发酵24 h后乳酸和乙酸质量浓度分别达到24.85、8.98 mg/mL。与未发酵的杂粮面团相比,乳酸菌发酵杂粮面团中OBG含量下降32.56%,RS含量上升32.88%,游离氨基酸总量提升至1.46倍,氨基酸组成模式更优,部分蛋白质和纤维素发生降解,面筋网络结构更加紧密且连续。在营养方面,乳酸菌发酵前后的杂粮馒头膳食纤维质量分数均高于6%,蛋白质质量分数分别为40.35%和38.38%,属于高纤维高蛋白食品,显著优于小麦粉馒头。乳酸菌发酵杂粮馒头具有更高的体外蛋白消化率和比容,且乳酸菌发酵杂粮馒头感官评价总评分显著高于未发酵杂粮馒头,整体可接受度...     

不同类型乳酸菌对全麦酸面团发酵特性的影响

选择3种类型共7种乳酸菌,研究全麦粉为发酵基质的酸面团的发酵特性。发酵类型为兼性异型发酵(FHe)的植物乳杆菌和专性异型发酵(OHe)的短乳杆菌在全麦酸面团中的增殖速度最快,二者具有明显的生长增殖优势,尤其是植物乳杆菌。相较于其它乳酸菌,FHe型的植物乳杆菌产酸能力最强,能快速降低全麦酸面团的pH值和不可溶膳食纤维含量,显著提高全麦酸面团水溶性阿拉伯木聚糖、水溶性膳食纤维和总酚含量。在开发以全麦粉为发酵基质的全面酸面团时,FHe型的植物乳杆菌具有明显的优势,有利于节约成本,更好地改善全麦酸面团以及全麦烘焙面包的品质。     

乳酸菌固态发酵过程中麦麸组分的动态变化

麦麸是小麦加工的主要副产物,营养丰富且产量大,采用乳酸菌处理麦麸可提高其附加值。为明确乳酸菌发酵对麦麸各组分的影响,作者采用植物乳杆菌、鼠李糖乳杆菌、戊糖片球菌和布氏乳杆菌分别对麦麸进行固态发酵,在48 h内每隔8 h取样,分析可溶性膳食纤维、粗蛋白质、淀粉、总酚、植酸等成分的质量分数及DPPH自由基清除能力的动态变化。结果表明,在麦麸基质中,4株乳酸菌在24 h内生长较为迅速;麦麸经乳酸菌发酵后可溶性膳食纤维质量分数显著提高,其中布氏乳杆菌发酵48 h后可溶性膳食纤维质量分数由4.72%增加至6.58%;随着发酵时间的增加,麦麸中淀粉质量分数逐渐降低,粗蛋白质量分数先增加后降低最后趋于稳定;植物乳杆菌在提高麦麸多酚质量分数方面有更好的效果,多酚质量分数由1.34 mg/g增加至3.86 mg/g,麦麸抗氧化活性显著增加;此外,乳酸菌发酵麦麸可显著降低其植酸质量分数。综合而言,植物乳杆菌和布氏乳杆菌在提高麦麸的营养特性方面具有较好的效果,可有效改善麦麸的综合利用价值。     

产乳化活性多糖乳酸菌的筛选及其发酵荞麦酸面团、面包的特性

本研究从不同来源的原料中分离得到18株具有产胞外多糖(EPS)能力的乳酸菌,通过对比发酵液及乳酸菌荞麦酸面团的乳化活性,获得一株产EPS且乳化活性较高的乳酸菌,并应用于荞麦酸面团的制作。采用动态流变测定、激光共聚焦观察、质构分析等手段,研究其对荞麦酸面团面包烘焙学特性的影响。结果表明:优选产乳化性多糖的乳酸菌YC'-22经鉴定为发酵乳杆菌(Lactobacillus fermentum strain HBUAS54017),且同源性为100%,EPS产量为1.63 g/L。通过添加乳酸菌荞麦酸面团,使面包面团的面筋网络结构得到强化。相比空白面包(CB),添加1.0%阿拉伯胶的荞麦面包(AGB)、荞麦酸面团面包(SDB)的比容分别增加了12.42%和14.08%,硬度分别降低了13.90%和22.87%;其中SDB面包整体可接受度最高,改善效果最明显。因此,产乳化性多糖的乳酸菌发酵的荞麦酸面团可以作为一种天然的面包功能配料。     

发酵麦麸对面包膳食纤维组成及烘焙特性的影响

采用马克斯克鲁维酵母发酵麦麸制得富含天然酶的功能配料,分析麦麸发酵过程中纤维素酶活力变化,比较制作的麦麸面包(B₁)、发酵麦麸面包(B₂)、木聚糖酶麦麸面包(B₃)和复合麦麸面包(B₄)的膳食纤维组成及烘焙特性的差异。结果表明:马克斯克鲁维酵母具有较强的胞外β-葡萄糖苷酶生产能力,其酶活为6.98 U/g;在48 h麦麸发酵过程中,外切葡聚糖酶和β-葡萄糖苷酶的酶活不断提高,其酶活分别增加至6.06和21.70 U/g,不溶性膳食纤维(IDF)也持续降解至38.30 g/100 g。面团搅拌、醒发过程中,还原糖含量不断增加,且添加发酵麦麸的面包效果最明显。相比未发酵麦麸面包,添加发酵麦麸的面包体积、弹性及持水力都显著提升(p<0.05),气孔结构更加细腻。制作的4种面包中总膳食纤维(TDF)和阿拉伯木聚糖(AX)含量没有显著差异,而添加发酵麦麸及木聚糖酶都能促进面包中IDF和AX溶解。     

高产β-葡萄糖苷酶的乳酸菌在葡萄汁酸面团面包中的应用

从4种酒曲中分离筛选乳酸菌,并通过七叶苷平板显色法结合酶活测定筛选出3株高产β-葡萄糖苷酶的菌株。通过16SrDNA基因鉴定其种属,研究了3株菌粗酶液的最适温度、pH,并对酶进行定位。应用高产β-葡萄糖苷酶的乳酸菌发酵葡萄汁酸面团制作面包,通过固相微萃取气相色谱质谱联用技术(GC—MS)分析了面包香气成分,并进行了感官评定。结果表明:酒曲中一共筛得124株乳酸菌,其中产β-葡萄糖苷酶的乳酸菌有28株,产酶能力最高的3株乳酸菌经鉴定为哈尔滨乳杆菌(Lactobacillus harbinensis,M12和M24)和戊糖片球菌(Pediococcus pentosaceus,J28)。用M12发酵葡萄汁酸面团制作面包(RSB),RSB中一共检测出52种风味物质,较普通酵母面包(CYB)的风味物质种类增加了52.9%,而风味物质总峰面积也提高了65.5%。经过感官评定,RSB的整体接受度优于普通酵母面包(CYB)及含未发酵葡萄汁的酵母面包(RYB)。     

麦麸细粉营养成分分析及在面包烘焙中的应用

采用喷雾调质、研磨和筛选分离出小麦麸皮中的麦麸细粉,分析其营养成分,并通过流变特性测试及烘焙应用试验,研究其对面粉营养成分及面团烘焙特性的影响。结果表明,分离所得麦麸细粉的蛋白质和膳食纤维含量高达15.8%和33.6%,且富含钾、钙、铁等多种矿物质。随着麦麸细粉在面包专用粉中添加比例的增加,面包专用粉的灰分和湿面筋含量呈递增趋势;面筋指数、糊化黏度逐渐降低,面团吸水率、弱化度逐渐增加;稳定时间、延展性呈减小趋势;面包的搅拌时间、发酵时间延长,比容和品质评分降低。添加10%麦麸细粉的面包烘焙性能和感官品质较好,且营养价值得到了显著改善。     

Utilization of African grains for sourdough bread making

Abstract: Acha and Iburu flours were singly subjected to sourdough fermentation with previously selected autochthonous starters. Sourdoughs were used (30%, wt/wt) as aroma carriers and acidifiers during short time fermentation with the addition of baker's yeast. Acha and Iburu sourdough breads were compared to wheat sourdough bread started with the same strains and to breads made with the same formula but using baker's yeast alone. During Acha and Iburu sourdough fermentations, starter lactic acid bacteria reached almost the same cell density found in wheat sourdoughs. Acidification was more intense. Iburu sourdough bread had the highest total titratable acidity, the lowest pH, and contained the highest levels of free amino acids and phytase activity. The values of in vitro protein digestibility did not differ between Acha sourdough and wheat sourdough breads, while Iburu sourdough bread showed a slightly lower value. Acha and Iburu sourdough breads showed lower specific volume and higher density with respect to wheat sourdough breads. Nevertheless, Acha and Iburu sourdough breads were preferred for hardness and resilience. As shown by sensory analysis, Acha and especially Iburu sourdough breads were appreciated for color, acid taste and flavor, and overall acceptability. Practical Application: This study was aimed at evaluating the technological and nutritional properties of the African cereals Acha and Iburu. Sourdough fermentation and the use of selected starters increased the nutritional and sensory qualities and the potential application for bakery industry.     

Influence of in-situ synthesized exopolysaccharides on the quality of gluten-free sorghum sourdough bread

The majority of gluten-free breads on the market are of poor sensory and textural quality. Exopolysaccharides (EPS) formed from sucrose during sourdough fermentation can improve the technological properties of gluten-free breads and potentially replace hydrocolloids. In this study, the influence of in situ formed EPS on dough rheology and quality of gluten-free sorghum bread was investigated. Dextran forming Weissella cibaria MG1 was compared to reuteran producing Lactobacillus reuteri VIP and fructan forming L. reuteri Y2. EPS containing bread batters were prepared by adding 10% and 20% of sourdough. As control served batters and bread containing sourdoughs fermented without sucrose and batters and bread without sourdough addition. The amount of EPS formed in situ ranged from 0.6 to 8.0 g/kg sourdough. EPS formed during sourdough fermentation were responsible for the significant decrease in dough strength and elasticity, with in situ formed dextran exhibiting the strongest impact. Increased release of glucose and fructose from sucrose during fermentation enhanced CO? production of yeast. Organic acids in control sourdough breads induced hardening of the bread crumb. EPS formed during sourdough fermentation masked the effect of the organic acids and led to a softer crumb in the fresh and stored sorghum bread. Among EPS, dextran showed the best shelf life improvements. In addition to EPS, all three strains produced oligosaccharides during sorghum sourdough fermentation contributing to the nutritional benefits of gluten-free sorghum bread. Results of this study demonstrated that EPS formed during sourdough fermentation can be successfully applied in gluten-free sorghum flours to improve their bread-making potentials.     

Effect of adding fresh and freeze‐dried buckwheat sourdough on gluten‐free bread quality

This study demonstrates new possibilities in using freeze‐dried buckwheat sourdoughs in the processing of gluten‐free bread (GFB). Fresh and freeze‐dried (at temperatures of 20, 40 and 60 °C) sourdoughs were added in the amounts of 10, 20, 30 and 40% of the total flour content. Significant and beneficial changes in the quality of bread under the influence of different quantities of fresh and freeze‐dried sourdoughs additive were observed. Freeze‐dried buckwheat sourdoughs at the level of 20 and 30% gave the best baking results for GFB. pH of bread significantly changed, which had a positive effect on increasing its suitability for the storage. Buckwheat sourdough dried at 40 °C is the most highly recommended for GFB processing. Higher temperatures (60 °C) caused the least change in bread volume; however, a bitter aftertaste from burning was slightly detectable. Freeze‐dried buckwheat sourdoughs can be used directly in processing, thus eliminating the long fermentation of sourdough.     

Impact of ‘oxidizing’ and ‘reducing’ buckwheat sourdoughs on brown rice and buckwheat batter and bread

The influence of reducing and oxidizing buckwheat sourdoughs on the rheological, protein, and bread properties of buckwheat and brown rice flour was investigated. Batters and breads prepared with chemically acidified doughs, fresh pre-doughs, and fresh pre-doughs containing glutathione (3 mM) were used as controls. No significant differences were observed after the addition of reducing and oxidizing sourdoughs in all trials. Proteolysis was observed after proofing time in buckwheat and brown rice batters, respectively. Acidified doughs increased the elasticity and the gelatinization temperature of buckwheat batters. No notable microstructure changes were detected in brown rice batters. The extension of fermentation time in sourdough caused a slight decrease in bread volumes in all trials. Sourdoughs increased the bread volume and decreased the crumb hardness of buckwheat breads. In trials with brown rice flour, the addition of sourdough did not show relevant volume differences as compared to the controls, except big voids in sourdough bread crumb. Linear correlations between hardness, volume, and cells’ density were observed. However, no clear correlations among rheological parameters and bread characteristics could be detected. These results indicated that the applied strains were responsible for the leavening capacity of the yeast during the proofing time and for crumb structure in trials with buckwheat and brown rice flour. Applied sourdoughs were able to change the molecular, and bread properties of buckwheat and brown rice bread.     

Fundamental study on the effect of hydrostatic pressure treatment on the bread-making performance of oat flour

The use of sourdough in wheat and rye breads has been extensively studied; however, little is known about its potential effect when baking oat bread. Consequently, the impact of sourdough on oat bread quality was investigated. Two different sourdoughs were prepared from wholegrain oat flour without the addition of starter cultures, by continuous propagation at 28 (SD 28) or 37 °C (SD 37) until the composition of the lactic acid bacteria remained stable. The dominant LAB were identified by sequence analysis of the 16S rDNA isolated from pure cultures. LAB from SD 28 belonged to the species Leuconostoc argentinum, Pedicoccus pentosaceus and Weissella cibaria, while Lactobacillus coryniformis dominated SD 37. The isolated LAB were further used as starter cultures for the production of oat sourdoughs. Fundamental rheology revealed softening of the sourdoughs compared to non-acidified and chemically acidified controls, which could not be attributed to proteolytic activity. Incorporation of oat sourdough into an oat bread recipe resulted in significantly increased loaf-specific volume as well as improved texture, independent of addition level or sourdough type. Overall, the results of this study show that sourdoughs containing lactic acid bacteria isolated from oats have the potential to enhance oat bread quality.