Screening of glucosinolates degrading lactic acid bacteria and their utilization in rapeseed meal fermentation

Rapeseed meal is a promising food ingredient, but its utilization is limited by the presence of some potentially harmful ingredients, such as glucosinolates. Fermentation is a cost-effective method of detoxication but a food-grade starter culture with glucosinolates degradation capacity is required. In this study, 46 strains of lactic acid bacteria from traditional paocai brines were screened for their ability to glucosinolate degradation. The results showed that more than 50% of the strains significantly degraded glucosinolates. Two strains of Lactiplantibacillus(p7 and s7) with high capacity of glucosinolates degradation through producing enzymes were identified. Then,an optimized condition for rapeseed meal fermentation by p7 was established to degrade glucosinolates, which can achieve about 80% degradation. UPLC/Q-TOF-MS analysis showed that the degradation rate of individual glucosinolates was different and the degradation rate of gluconapin and progoitrin in rapeseed meal can reach more than 90%. Meanwhile, fermentation with p7 can improve safety of rapeseed meal by inhibiting the growth of Enterobacteriaceae and improve its nutritional properties by degrading phytic acid. The in vitro digestion experiments showed that the content of glucosinolates in rapeseed meal decreased significantly during gastric digestion. Meanwhile, fermentation with p7 can greatly improve the release of soluble protein and increase the contents of free essential amino acids, such as lysine(increased by 12 folds) and methionine(increased by 10 folds).

Application Effects of Amino Acid Powder,Fermented Rapeseed Meal and Fermented Cottonseed Meal in Feeds for Allogynogenetic Crucian Carp

[Objective] To investigate the effects of amino acid powder, fermented rapeseed meal and fermented cottonseed meal on the growth performance, amino acid absorption, body composition and liver function of allogynogentic crucian carp. [ Method] The allogynogentic crucian carps with the average initial weight of 17.3 g were divided into control group and six experimental groups randomly. The allogynogentic crucian carps in the control group and experimental groups were fed a basal diet and the basal diets supplemented by amino acid powder, fermented rapeseed meal and fermented cottonseed meal, respectively. The growth rate and specific growth rate of allogynogentic crucian carps, the content of amino acids in serum and feeds, the composition indicators of body, muscle and liver, as well as the activities of glutamic-pyruvic transaminase （GPT） and glutamic-oxaloacetic transaminase （GOT） in liver and serum were determined, respectively. [ Result] The growth rate and specific growth rate （SGR） of allogynogentic crucian carps in the 3% amino acid powder group and the 6% fermented cottonseed meal group were increased greatly （ P 〈 0.05）, and no significant difference was found between experimental group and control group. The serum lysine content of the 3% amino acid powder group and the 6% fermented cottonseed meal group was higher than that of the control group. In the experimental groups, the absorption of four essential amino acids was up to a peak at 4 h after feeding, which was consistent with the control group. The body composition and liver function of allogynogentic crucian carps had no significant difference between the experimental groups and the control group. [ Conclusion] The 3% amino acid powder, 6% fermented cottonseed meal and 6% fermented rapeseed meal can substitute fish meal, cottonseed meal and rapeseed meal to improve the clrowth performance, amino acid absorption of the allogynogentic crucian carps.

Optimization of Solid-State Fermentation with Lactobacillus brevis and Aspergillus oryzae for Trypsin Inhibitor Degradation in Soybean Meal

The aim of the present study was to optimize trypsin inhibitor degradation in soybean meal by solid-state fermentation （SSF） with Lactobacillus brevis and Aspergillus oryzae, and to determine the effect of SSF on phytic acid, crude protein, crude fat, and amino acid profile. Response surface methodology （RSM） with Box-Behnken design was used to optimize SSF. The optimal conditions derived from RSM for L. brevis fermentation were： pH=5. 1; inoculum size=10%; duration=72 h; substrate to water ratio=1.5. The minimum content of trypsin inhibitors was 6.4 mg g^-1 dry matter. The optimal conditions derived from RSM for A. oryzae fermentation were： substrate to water ratio= 0.8 1; inoculum size=4%; duration=120 h. The minimum content of trypsin inhibitors was 1.6 mg g^-1 dry matter. Both L. brevis and A. oryzae decreased trypsin inhibitors dramatically （57.1 and 89.2% respectively）. L. brevis fermentation did not affect phytic acid （0.4%） and crude fat （5.2%） considerably, whereas A. oryzae fermentation degraded phytic acid （34.8%） and crude fat （22.0%） contents to a certain extent. Crude protein content was increased after both fermentation （6.4 and 12.9% for L. brevis and A. oryzae respectively）. Urease activity was reduced greatly （83.3 and 58.3% for L. brevis and A. oryzae respectively）. In conclusion, SSF with A. oryzae and L. brevis reduced trypsin inhibitor content and modified major macronutrients in soybean meal.

The variation of two extracellular enzymes and soybean meal bitterness during solid-state fermentation of Bacillus subtilis

The debittering effect of extracellular enzymes from Bacillus subtilis ACCC 01746 was studied using soybean meal as a substrate for solid-state fermentation(SSF).Results showed that B.subtilis produces proteases and carboxypeptidase in the early stage of SSF(0–8 h).Proteases are dominant and can hydrolyze the soybean protein into long-chain peptides with mild bitterness.Carboxypeptidase production is dominant at 8–16 h SSF,at which point soybean protein is further hydrolyzed and bitterness is enhanced.The strain then produces additional carboxypeptidase after 16 h,and bitterness is reduced.We compared the amino acid composition of the hydrolysates from soybean protein isolates to that of the fermented liquid of SSF.In the hydrolysates from soybean protein isolates that exhibit strong bitterness,62.81%of amino acids are hydrophobic and occur in the form of peptides.In the fermented liquid from soybean meal,16.22%of amino acids are hydrophobic and are mainly present in the form of free amino acids.The bitterness of fermented soybean hydrolysate is reduced from 5 to 0 when fermented for 24 h,suggesting that B.subtilis can effectively reduce bitterness,possibly due to the carboxypeptidase.Enzyme analysis shows that B.subtilis excretes carboxypeptidase during growth.The amino acids phenylalanine,alanine,tyrosine,and leucine at the C-terminal of the soybean bitter peptides in hydrolysates are cleaved in the presence of carboxypeptidase,resulting in complete debitterness.

Effect of fermented rapeseed meal on growth performance,nutrient digestibility,and intestinal health in growing pigs

To explore the effects of fermented rapeseed meal(FRSM)on growth performance and intestinal health,a total of 30 growing pigs were randomly allotted to three treatments consisting of corn-soybean meal diet(CSD),rapeseed meal diet(RSD),and fermented rapeseed meal diet(FRSD).Results showed that compared with RSD,FRSD feeding increased the average daily gain and final body weight in pigs(P<0.01).Compared with RSD feeding,FRSD feeding elevated the apparent digestibility of crude protein,acid detergent fiber,and ether extract in pigs(P<0.01).Moreover,the FRSD group exhibited greater apparent ileal digestibility of His,Thr,Lys,and Ser than the RSD group(P<0.01).The digestible energy,metabolic energy,and nitrogen utilization were higher in the FRSD and CSD groups than in the RSD group(P<0.01).As compared to the RSD,FRSD feeding decreased the serum concentration of leptin but significantly increased the concentrations of immunoglobulin(Ig)A,IgG,ghrelin,and enzyme activities of amylase,lipase,and trypsin in the pancreas(P<0.05).Interestingly,the villus height,the ratio of villus height to crypt depth,and the activities of brush border enzymes(e.g.,maltase and sucrase)in the small intestine were higher in the CSD and FRSD groups than in the RSD group(P<0.05).As compared to the RSD,the FRSD feeding not only increased the expression level of the occludin in the small intestinal epithelium(P<0.05)but also elevated the expression levels of claudin-1,MUC1,and PepT1 genes in the duodenum,and elevated the expression levels of SGLT1 and CAT1 genes in the jejunum(P<0.05).Importantly,FRSD feeding significantly decreased the abundance of Escherichia coli,but increased the abundance of Lactobacillus and the content of butyrate in the cecum and colon(P<0.05).These results indicated that compared with rapeseed meal,fermented rapeseed meal exhibited a positive effect on improving the growth performance and intestinal health in growing pigs,and the results may also help develop novel protein sources for animal nutrition and the feed industry.

A fermented rapeseed meal additive:Effects on production performance,nutrient digestibility,colostrum immunoglobulin content and microbial flora in sows

This study was to assess the effect of fermented rapeseed meal(FRSM) in the diet of sows,taking into account the physiological period(pregnancy or lactation) and reproductive cycle(primiparous or multiparous sows),on production performance,nutrient digestibility,colostrum immunoglobulin content,and microbial flora in sows.The experimental material included 30 primiparous gilts and 30 multiparous sows after their second lactation.The animals in the control groups C_G(gilts) and Cs(sows)received a standard diet for pregnant or lactating sows,depending on the reproductive period.Experimental groups E_G and E_S comprised gilts and multiparous sows,respectively,receiving a diet with a 4%share of FRSM in place of soybean meal up to 100 d of gestation.In addition,from 100 d of gestation to7 d of lactation,the sows in experimental groups received a diet with a 9% share of FRSM,and then again a diet with a 4% share of FRSM until the end of lactation.The addition of 4% to 9% share of a FRSM component in feed significantly improves production parameters,mainly in primiparous gilts,leading to an increase in litter size and in litter weight at 28 d of age.It also helps to improve the digestibility of crude protein,fat,and crude fiber,and positively affects the gut microbiota of sows.Fermentation of rapeseed meal is an effective way to reduce anti-nutrients and to increase the level of lactic acid in the diet It also stimulates the immune system,which improves piglet health,reducing the severity of diarrhoea and mortality.

微生物固态发酵条件的优化及其对菜籽粕品质改善的研究

通过优化菜籽粕固态发酵工艺,并对发酵产物进行品质评价,为菜籽粕在水产养殖业的开发利用提供理论基础。本试验采用枯草芽孢杆菌(Bacillus subtilis)、酿酒酵母(Saccharomyces cerevisiae)和植物乳杆菌(Lactobacillus plantarum)对菜籽粕进行固态发酵,首先对不同混菌比例、外源纤维素酶添加量及植酸酶添加量进行优化,在优化条件下对菜籽粕进行固态发酵,然后以硫甙、单宁、植酸、粗蛋白质、酸溶蛋白、总酸含量和pH为指标,评价菜籽粕发酵前后的品质变化。结果显示:枯草芽孢杆菌、酿酒酵母和植物乳杆菌的最佳混菌比例为1∶1∶2、纤维素酶添加量为1.25%、植酸酶添加量为0.10%时,菜籽粕发酵的效果较好。在最优发酵条件下,发酵菜籽粕的硫甙、植酸及单宁含量分别为33μmol/g、44.49 mg/g和9.53 mg/g,降解率分别为41.92%、40.10%和59.31%。粗蛋白质和酸溶蛋白含量相较于发酵前分别增加了16.59%和41.85%。发酵菜籽粕的总酸含量增加了109.43%,且pH由6.53降至5.68。本研究为提高菜籽粕的饲用价值提供参考,有利于菜籽粕作为植物蛋白质源饲料应用于水产饲料行业中。

菜籽粕混合发酵饲料替代豆粕对生长猪生长性能、养分表观消化率以及血清生化和抗氧化指标的影响

本试验旨在研究菜籽粕混合发酵饲料替代豆粕对生长猪生长性能、养分表观消化率以及血清生化和抗氧化指标的影响。试验选用70%菜籽粕、15%玉米皮和15%麸皮混合作为发酵原料,筛选菌种后选择添加酵母菌、罗伊氏乳杆菌(Lactobacillus reuteri)和中性蛋白酶进行发酵。优化发酵条件后将条件控制为含水量55%、发酵温度30℃、发酵时间60 h,干燥制得发酵饲料。在饲喂试验中,选取平均体重为(39.3±5.3)kg的“杜×长×大”三元杂交生长猪72头,随机分为3组,每组3个重复,每个重复8头猪(公母各占1/2)。对照组(CON组)饲喂基础饲粮,未发酵组(RMD组)饲喂用15%未发酵菜籽粕混合饲料替代基础饲粮中豆粕、玉米和麸皮的饲粮,发酵组(FRMD组)饲喂用15%菜籽粕混合发酵饲料替代基础饲粮中豆粕、玉米和麸皮的饲粮。试验期28 d。结果表明:1)混合发酵显著提高了菜籽粕混合饲料的粗蛋白质(CP)和三氯乙酸酸溶蛋白(TCA-N)含量(P<0.05),显著降低了硫代葡萄糖苷、植酸和单宁含量(P<0.05)。2)饲养试验结果表明,3组生长猪生长性能无显著差异(P>0.05);FRMD组总磷表观消化率要显著高于RMD组(P<0.05);与CON组相比,RMD组血清尿素氮(UN)含量有所提高(P>0.05),而FRMD组血清UN含量无显著差异(P>0.05);与RMD组相比,FRMD组血清谷胱甘肽过氧化物酶(GSH-Px)活性显著降低(P<0.05)。由此可见,混合发酵可提高菜籽粕的营养价值,并且菜籽粕在混合发酵后可部分替代生长猪饲粮中的豆粕。

发酵菜籽粕对黄颡鱼表观消化率、肝脏及肠道健康的影响

为探究发酵菜籽粕对黄颡鱼的饲料表观消化率、肝脏及肠道健康的影响,实验以黄颡鱼(Tachysurus fulvidraco)为研究对象,共设置3组饲料,分别为对照组(Control)、未发酵菜籽粕组(URSM)和发酵菜籽粕组(FRSM),养殖实验共持续7周。研究结果表明,FRSM组的增重率(WGR)显著高于USRM组(P<0.05),而饲料系数(FCR)和肝体比(HSI)显著低于URSM组(P<0.05)。与未发酵菜籽粕原料相比,黄颡鱼对发酵菜籽粕原料的干物质、粗蛋白、粗脂肪和能量的表观消化率均增加。肝脏组织结构结果表明,URSM组黄颡鱼肝细胞空泡化的相对面积显著高于对照组和FRSM组(P<0.05)。肠道组织结构及紧密连接相关基因试验结果表明,3组间的黄颡鱼肠道绒毛宽度无显著性差异(P>0.05),而FRSM组黄颡鱼的绒毛长度和肠道zo-1和zo-2的mRNA表达水平显著高于URSM组(P<0.05)。炎症因子相关基因测定结果表明,与URSM组相比,FRSM组黄颡鱼肝脏tnf-α、tnf-β和il-1β的mRNA表达水平显著下调,肠道tnf-α和il-6的mRNA表达水平显著下调,而肠道il-10和tgf-β的mRNA表达水平显著上调。与对照组相比,饲料添加未发酵菜籽粕显著增加了黄颡鱼肝脏和肠道的MDA含量(P<0.05),降低了总抗氧化能力(P<0.05),引发肝脏和肠道氧化应激。而饲料添加发酵菜籽粕减轻了菜籽粕导致的黄颡鱼肝脏和肠道氧化损伤。凋亡相关基因检测结果发现,与对照组相比,饲料添加未发酵菜籽上调了黄颡鱼肝脏和肠道促凋亡基因bax、p53、caspase3、caspase9和mdm2的表达水平,但是下调了bcl2的mRNA表达(P<0.05)。而饲料添加发酵菜籽粕明显改善了未发酵菜籽粕导致的促凋亡现象。研究表明,菜籽粕经发酵后添加至饲料中,可以减轻未发酵菜籽粕导致的黄颡鱼肝脏和肠道炎症反应、氧化损伤及细胞凋亡,从而改善黄颡鱼肝脏和肠道健康。研究为深入探讨发酵菜籽粕对鱼类肝脏和肠道健康的改善作用提供了理论依据,对于发酵菜籽粕在鱼类生产中的应用具有重要意义。

具有益生功能芽孢杆菌的筛选鉴定及特性研究

本研究旨在筛选出产酶能力及抑菌性能优良的发酵菌株,为新型饲料资源的开发和抗生素替代品的研究提供参考。以蜡样芽胞杆菌菌株H14为出发菌株,分析其酶学特性和抑菌性能,通过单因素试验对发酵菜籽粕的饲料添加量与发酵时间进行优化。筛选鉴定出一株产纤维素酶、蛋白酶、淀粉酶、木聚糖酶的蜡样芽胞杆菌H14。产纤维素酶最适反应条件为60℃,pH 9,酶活11.51 U/mL,蛋白酶酶活73.68 U/mL,淀粉酶酶活5.96 U/mL,木聚糖酶酶活14.02 U/mL。对大肠杆菌和金黄色葡萄球菌最大抑菌直径分别为18.200±0.200 mm和17.567±0.493 mm。发酵菜籽粕产纤维素酶的最佳条件为菜籽粕添加量25%,发酵48 h,酶活为12.608 U/mL,对大肠杆菌和金黄色葡萄球菌的最佳抑菌效果分别为菜籽粕添加量25%,发酵48 h,抑菌直径为24.933±0.204 mm;菜籽粕添加量25%,发酵72 h,抑菌直径为27.400±0.529 mm,发酵产物含蔗糖、木糖、葡萄糖。综上所述,本研究成功筛选出一株具有良好产酶和抑菌特性的发酵菌株H14,其在发酵菜籽粕生产中表现出良好的应用潜力,为未来发酵饲料的研发提供了有价值的参考。

棉籽粕和菜籽粕内源抗营养因子脱除技术研究进展

我国非常规蛋白饲料资源丰富,主要包括棉籽粕和菜籽粕等。棉籽粕和菜籽粕的蛋白质含量高,但其中含有游离棉酚、硫代葡萄糖苷、植酸等多种抗营养因子,不仅会影响动物对营养物质的消化吸收,还可能引起营养代谢性疾病,限制了其在畜禽饲料中的广泛应用。抗营养因子的去除方法主要有物理法、化学法及生物法,其中生物法是利用微生物特定的代谢途径和代谢产物将抗营养因子分解。此方法不仅可有效降解和转化棉籽粕和菜籽粕中的抗营养因子,还可提高其消化率,改善适口性,提升饲用营养价值。文章主要综述了棉籽粕和菜籽粕中主要抗营养因子的毒理作用、脱除方法以及微生物发酵棉籽粕和菜籽粕在动物生产中的应用效果,以期为其在畜禽生产中的高效利用提供参考。

日粮中发酵菜籽粕替代豆粕对肉牛生长性能、表观消化率及屠宰性能的影响

文章旨在分析日粮中发酵菜籽粕(Fermented Rapeseed Meal,FRM)替代豆粕对肉牛生长性能、表观消化率及屠宰性能的影响。试验将60头健康状况良好,日龄和体重相近的西门塔尔肉牛随机分为3组,每组4个重复,每个重复5头。对照组根据肉牛营养需要(NRC)配制全混合日粮,蛋白饲料由50%豆粕+50%发酵菜籽粕,0%豆粕+100%发酵菜籽粕组成(等氮),并记为FRM50组、FRM100组。预饲期7?d,正试期90 d。结果表明:(1)对照组、FRM50组肉牛末重、平均日增重显著高于FRM100组(P <0.05),FRM50组肉牛料重比显著低于FRM100组(P <0.05)。(2)与FRM100组相比,对照组,FRM50组肉牛的粗蛋白质和粗脂肪消化率得到显著提高(P <0.05)。(3)对照组、FRM50组肉牛宰前活重显著高于FRM100组(P <0.05),FRM50组肉牛胴体重、净肉重显著高于FRM100组(P <0.05)。综上所述,等氮替代条件下,50%豆粕+50%发酵菜籽粕作为蛋白质的饲料能提高肉牛生长性能、表观消化率,改善肉牛屠宰性能。

发酵菜籽粕的营养价值测定及其对育肥猪生长性能的影响

本研究旨在通过消化代谢试验测定发酵菜籽粕(FRSM)和菜籽粕(RSM)的生长猪消化能和代谢能,同时通过T型瘘管手术进行生长猪的回肠末端氨基酸消化率测定,并测定FRSM和RSM对育肥猪生长性能的影响。试验1:采用全收粪法测定RSM和FRSM的生长猪消化能和代谢能。选取18头初始体重为(26.41±3.08)kg的“杜×长×大”三元杂交去势公猪,随机分成3组,每组6个重复,每个重复1头猪。对照组饲喂玉米基础饲粮,试验组以FRSM和RSM替代基础饲粮中25%的玉米。试验期为19 d,包括适应期7 d,预试期7 d,正试期5 d。试验2:采用无氮饲粮和半纯合饲粮法测定FRSM和RSM的氨基酸回肠末端消化率。选取18头初始体重为(22.47±1.74)kg的“杜×长×大”三元杂交去势公猪,随机分成3组,每组6个重复,每个重复1头猪。对照组饲喂无氮饲粮,试验组分别饲喂添加30%的FRSM和RSM的饲粮。试验期为14 d,包括恢复期7 d,预试期5 d,正试期2 d。试验3:选取20头初始体重为(68.43±2.63)kg的“杜×长×大”三元杂交猪,随机分成2组,每组10个重复,每个重复1头猪。2组分别饲喂含11.2%的RSM和FRSM的试验饲粮。试验期45 d。结果表明:1)在饲喂基础下,FRSM的消化能和代谢能分别为12.00和10.79 MJ/kg,RSM的消化能和代谢能分别为11.12和10.06 MJ/kg。FRSM和RSM的消化能和代谢能存在极显著差异(P<0.01)。2)FRSM的氨基酸表观回肠消化率(AID)和标准回肠消化率(SID)分别为55.62%~78.72%和62.71%~83.14%,其中FRSM的赖氨酸、苏氨酸、蛋氨酸、色氨酸和缬氨酸的SID分别为71.51%、71.45%、81.69%、76.79%和74.36%。RSM的氨基酸AID和SID分别为47.74%~77.11%和53.94%~79.98%,其中RSM的赖氨酸、苏氨酸、蛋氨酸、色氨酸和缬氨酸的SID分别为65.17%、63.65%、79.98%、67.47%和66.26%。3)与RSM组相比,FRSM组的平均日增重(ADG)显著提高(P<0.05),料重比(F/G)极显著降低(P<0.01)。综上所述,与RSM相比,FRSM具有较高的生长猪消化能、代谢能和氨基酸AID、SID,可以提高育肥猪ADG,降低F/G。

Application of Protein Feed Processed by Microbial Fermentation to Dairy Cow

Methionine （Met） and lysine （Lys） have been reported as the first two limiting amino acids （AA） for maximum milk yield and milk protein production. Supplying these AA may improve microbial protein synthesis and therefore improve milk production without adding excess N to the environment. This observation utilized fermented soybean meal （SBM）, cottonseed meal （CSM）, rapeseed meal （RSM） and corn by Bacillus subtilis 168 and Leuconostoc mesenteroides as core feedstuffs to produce special biological protein feed for dairy cow. The results showed that the milk production, milk protein percentage, milk fat percentage and milk DM percentage of test groups in trial period were significantly more than those of the control group （P〈0.01）, the results showed that adding fermenting protein feed in dairy cow diets could significantly improve milk yield, milk protein and milk fat content. The economic benefits of actual application were analyzed, the group of 0.5% was the best compared with the other groups.

粕类资源在饲料豆粕减量替代中的应用

我国饲料原料短缺问题日益突出,急需进行豆粕减量替代,大力拓展开发能够有效替代豆粕的饲料蛋白资源。我国农副产品中的多种粕类资源均可作为优良的豆粕替代原料,直接或经物化、生物等预处理后用于动物生产。本文综述了菜籽粕、棉籽粕、棕榈粕以及花生粕等其他杂粕的饲用营养价值,在动物生产中的应用现状及存在问题,以期为粕类资源的饲料化开发及在豆粕减量替代中的应用提供参考。

发酵菜籽粕的营养价值与抗营养因子及其在动物生产中的应用

随着畜牧业的快速发展,饲料原料的短缺日益明显,其中蛋白质饲料原料的短缺尤为突出。菜籽粕(rapeseed meal,RSM)的主要营养物质为蛋白质,是低价蛋白质饲料原料的主要来源之一。发酵菜籽粕(fermented rapeseed meal,FRSM)营养价值更高,具有平衡饲料中氨基酸水平、降低饲料成本、保障动物健康等作用。作者首先比较了RSM与FRSM的营养成分差异,发现FRSM的硫代葡萄糖苷、单宁、植酸等抗营养因子水平较RSM显著降低,而粗脂肪、粗蛋白质及各氨基酸水平却有提高;其次,简述了RSM的抗营养因子及其处理方法,发现通过采用发酵方式处理RSM是当前去除饲料中抗营养因子的有效方式之一;最后,总结了FRSM在猪、家禽、反刍动物以及肉兔、红鲷鱼等动物上的研究进展,并对其未来发展进行了展望,以期为FRSM在动物饲粮中的实际应用提供参考。

菜粕和豆粕混合生产氨基酸水溶肥的发酵工艺优化

氨基酸水溶肥具有全水溶、高活性和营养丰富等优势,可提高农作物的产量和品质,并且能平衡土壤酸碱度,改良土壤性状,是一种新型的功能性肥料。以菜粕和豆粕的混合物作为原料,利用实验室保藏的植物乳杆菌G71、商品化酵母菌和枯草芽孢杆菌进行发酵,采用正交试验、Plackett-Burman试验和爬坡试验设计以及Box-Behnken Design等方法优化发酵条件生产氨基酸水溶肥。结果表明:最优发酵条件为发酵时间217.68 h,起始pH 9.12,料水比1∶7.008,接种量3%,翻料间隔24 h;经验证,游离氨基酸产量可达到76.8 g·kg^(-1)。因此,通过混菌发酵方式能够有效地提高菜粕和豆粕农业废弃物发酵液中氨基酸含量,提升资源利用率,对发展生态高值农业具有重要意义。

混菌固态发酵菜籽粕提高可溶性蛋白的研究

为提高菜籽粕中的可溶性蛋白(soluble protein,SP),该试验通过植物乳杆菌(Lactobacillus plantarum)、枯草芽孢杆菌(Bacillus subtilis)与米曲霉(Aspergillus oryzae)混菌固态发酵的方法对其进行研究。结果表明,通过试验和响应面优化分析得出菜籽粕发酵最优工艺条件为料液比1∶1.01(g∶mL),接种量7.95%(质量分数),L.plantarum、B.subtilis与A.oryzae接种比例2∶2∶1(体积比),发酵温度34.02℃,共发酵93.86 h。发酵的菜籽粕相对于未发酵菜籽粕,多肽含量提高105.65%(P<0.01),SP含量提高22.335%(P<0.05);SDS-PAGE中14 kDa以下的亚基先降解;傅里叶红外光谱显示,蛋白二级结构中α-螺旋大部分转变为β-折叠、无规则卷曲、β-转角;氯化钯法测硫苷,其降解率达到(85.06±1.63)%(P<0.05);菌落平板计数显示,微生物的总数增长,在72 h时达到最大值。因此,混菌固态发酵的方式中各菌协同发酵,可有效提高SP、多肽含量,降解硫苷,使蛋白结构发生改变。

酶菌协同发酵改善菜籽饼粕营养价值的研究

本试验旨在探究酶菌协同发酵菜籽饼粕对抗营养因子的降解作用以及养分含量的改善作用,为菜籽饼粕在家禽饲粮中的应用提供数据与理论参考。试验采用正交试验法,以菜籽饼为发酵原料,以发酵后总变化率[总变化率=0.7×中性洗涤纤维(NDF)降解率+0.15×硫甙(Gls)降解率+0.15×酸溶蛋白(TCA-SP)增加率]作为综合评价指标,在明确最优酶菌协同发酵工艺的条件下,对9个不同来源菜籽饼粕进行发酵,对发酵后的养分含量变化进行效果评价,以验证发酵工艺对不同来源菜籽饼粕的有效性。结果表明:1)在混菌固态发酵体系中加入纤维素酶、果胶酶和α-半乳糖苷酶,添加量分别为60、60、10 U/g,发酵体系NDF降解率为18.25%,Gls降解率为60.12%,TCA-SP增加率为175.72%,总变化率为48.15%。2)酶菌协同发酵显著降低了菜籽饼NDF、酸性洗涤纤维(ADF)含量,显著提高了粗蛋白质(CP)、TCA-SP、总氨基酸含量(P<0.05),使菜籽饼表面结构发生改变,使蛋白质分子质量变小。3)酶菌协同发酵显著降低了9个不同来源菜籽饼粕的NDF、Gls含量和pH(P<0.05),显著提高了TCA-SP含量(P<0.05)。由此可见,酶菌协同发酵可以提高菜籽饼粕的TCA-SP含量,降低NDF、Gls含量及pH,对不同来源菜籽饼粕均能起到改善其营养价值的作用。

发酵菜籽粕对育肥猪生长性能、腹泻率及免疫力的影响

文章旨在研究发酵菜籽粕对育肥猪生长性能、腹泻率及免疫力的影响。试验选择90头健康和生长状况良好的120日龄育肥猪,随机分为5组,每组3个重复,每个重复6头。对照组饲喂基础日粮,试验1组日粮使用9%菜籽粕替代豆粕;试验2、3和4组日粮分别使用3%、6%和9%发酵菜籽粕替代菜籽粕。试验为期70 d(预饲期7 d,正试期63 d)。试验结果表明,使用菜籽粕替代日粮中的豆粕后,育肥猪平均日增重和终末体重显著降低,料重比显著升高(P<0.05);使用发酵菜籽粕替代日粮中的菜籽粕后,育肥猪平均日增重和终末体重随发酵菜籽粕添加量升高而升高(P<0.05);此外,日粮添加菜籽粕或发酵菜籽粕对育肥猪腹泻率无显著影响(P>0.05)。菜籽粕替代日粮中的豆粕显著降低了育肥猪血清IgG含量(P<0.05),使用发酵菜籽粕替代菜籽粕的育肥猪血清IgG含量显著升高(P<0.05),在添加量为9%时达到最大值(P<0.05);使用菜籽粕替代日粮中的豆粕显著增加了育肥猪血清TNF-α含量(P<0.05),使用发酵菜籽粕替代菜籽粕显著降低了育肥猪血清TNF-α含量(P<0.05);日粮添加菜籽粕或发酵菜籽粕对育肥猪血清IgA、IgM、IL-6和IL-10含量无显著影响(P>0.05)。