热杀菌条件对NFC冬枣汁成分及抗氧化活性的影响研究

为了研究不同热杀菌条件对NFC冬枣汁理化性质、活性成分及抗氧化活性的影响,本文以冬枣为研究对象,设置了低温长时杀菌(75℃,5、10、15、20、25 min)和高温短时杀菌(90℃,0.25、0.50、0.75、1.00、1.50 min)两个处理,考察了NFC冬枣汁的可溶性固形物含量、pH值、总酸含量、VC含量、DPPH清除率、亚铁离子还原率等指标。研究结果表明,两种杀菌方式对NFC冬枣汁基本理化性质影响不显著(P>0.05)。相比于低温长时杀菌,高温短时杀菌的△E值更低,更能保持冬枣汁原有的色泽。两种杀菌处理后多酚、VC含量均显著降低(P<0.05),低温长时杀菌25 min后VC含量未检出,抗氧化活性也显著低于高温短时杀菌(P<0.05)。因此,通过对NFC冬枣汁品质变化的分析,发现高温短时杀菌能更好地保持原有的色泽和营养成分。     

超临界CO_2对哈密瓜汁中大肠杆菌的杀灭效果研究

以哈密瓜汁中的大肠杆菌为研究对象,采用超临界CO_2技术(压力10、20、35 MPa,温度35、45、55℃),以温度、压力、保压时间为自变量,以大肠杆菌存活对数为因变量,对哈密瓜汁中大肠杆菌进行超临界CO_2(SCCO_2)杀菌效果的研究。采用一级反应动力学模型分析超临界CO_2对大肠杆菌的杀菌动力学;采用透射电镜观察超临界CO_2对大肠杆菌超微结构的影响。试验结果表明,在35～55℃、10～35 MPa的条件下对哈密瓜汁中大肠杆菌进行超临界二氧化碳处理,灭菌速率分为先快后慢两个阶段;随温度和压力的提高,大肠杆菌的灭菌速率均逐步上升;经超临界二氧化碳处理后,大肠杆菌细胞出现明显的缺陷,部分细胞壁消失。     

番茄汁加工技术研究进展

本文针对番茄汁加工技术当中的关键问题进行综述,并提出了存在的问题以及建议,以期为番茄汁加工企业提高番茄汁品质提供一定的技术理论支持。     

无核白浓缩汁加工工艺

以无核白葡萄干为原料,对无核白浓缩汁的生产工艺进行研究,确定最佳的工艺条件。结果表明,料液比1∶3,复水温度50℃,复水时间4 h为无核白葡萄干最佳复水条件;酶解最佳工艺条件酶解时间60 min,pH值3,酶解温度40℃;旋转蒸发最佳条件温度80℃,浓缩无核白汁可溶性固形物为40 Brix。     

葡萄汁奶酒发酵工艺研究

本文以牛奶和葡萄为原料,通过单因素和正交试验优化了葡萄汁奶酒的发酵工艺。结果表明,影响葡萄汁奶酒感官评分因素的强弱顺序依次为发酵温度>接种量>发酵时间>蔗糖添加量>葡萄汁添加量,通过计算发现最佳组合为发酵温度25℃,发酵时间5d,接种量1.00%∶0.50%∶1.50%,蔗糖添加量8%,葡萄汁添加量11%。该组合酿制的葡萄汁奶酒感官评分最高,为92分。经测得,葡萄汁奶酒在最佳发酵工艺条件下的总糖为9.5g/L、酒精体积分数为6.8%,总酸质量浓度为7.2g/L,氨基酸态氮质量浓度为0.21g/L。该葡萄汁奶酒中的天门冬氨酸、谷氨酸、异亮氨酸、亮氨酸、赖氨酸和脯氨酸含量显著高于奶酒和牛奶中的含量(P<0.05)。     

Potential of indigenous Bacillus spp. as probiotic feed supplements in an extruded low‐fish‐meal diet for juvenile olive flounder,Paralichthys olivaceus

A 12‐week feeding trial was designed to assess the probiotic potential of indigenous Bacillus amyloliquefaciens and/or Bacillus subtilis singly or in combination with Bacillus licheniformis in an extruded feed for olive flounder (Paralichthys olivaceus) juveniles. A high fish meal (FM) diet (control) and a low‐FM diet containing an alternative protein blend (30% FM replacement, FM30) were formulated. Three other experimental diets were prepared by inclusion of B. amyloliquefaciens (BA), B. subtilis (BS), or a mixture of B. amyloliquefaciens, B. subtilis, and B. licheniformis (BASL) into FM30 diet, with a final concentration of 10⁶ CFU/g diet. Results indicated that the FM30 diet was well tolerated by flounder, and the overall performance was not affected by dietary treatments. Lysozyme activity and total immunoglobulin level were significantly reduced in flounders when fed with the FM30 diet compared with the BASL and BA diets, respectively. The Bacillus additives neither enriched the relative abundance of the corresponding Bacillus spp. in the relevant gut microbiota of olive flounder nor modulated the presumptive gene functions of the gut microbiome. Despite the absence of growth‐promoting effect, the tested probiotics could still be economically viable for use as immunostimulants in commercial flounder diets with partial FM replacement.     

毛竹活立竹竹杆创口的伤流

伤流是代谢的自然现象。毛竹(Phyllostachys pubescens Mazel ex H.de Lehaie)的鞭、杆在竹笋采挖、竹材砍伐、人为伤害、雪压折断、人工砍梢以及虫蛀等情况下均会导致伤流。毛竹的伤流对毛竹个体、竹林的生长发育会有不同程度的影响,在一定程度上可以调节生长,也可能影响竹林的质量,削弱林分的长势,甚至会招致病虫害的侵袭。目前有从活立竹体采集竹汁做饮料的做法,以及钩梢以防雪压等,这些均会在不同的程度上导致伤流,故研究伤流的规律和控制对搞好营林管理,适当开发毛竹资源是十分必要的。毛竹伤流曾有过研究^[1、2],但都是研究伐竹后造成的伤流,本文是对活立竹竹杆受伤后伤流的情况以及一些影响因素作初步探讨。     

果胶酶酶解红枣制汁工艺的研究

以红枣为原料,采用果胶酶酶解浸提的方法制备红枣汁。以红枣汁可溶性固形物含量为参考指标,通过单因素试验和正交试验,研究了果胶酶添加量、酶解时间、酶解温度和p H值对枣汁浸提效果的影响。结果表明,最佳酶解工艺如下:果胶酶添加量为0.3%,酶解时间为4h,酶解温度为55℃,最适p H值为3.5,此工艺条件下所获得的红枣汁可溶性固形物含量为15.87%,所得红枣汁枣香浓郁,无苦味,颜色红亮,稳定性好。     

酶解工艺对籽瓜浓缩汁出汁率的影响

以籽瓜为试验材料,利用果胶酶和纤维素酶进行酶解。通过单因素和正交试验确定籽瓜的最佳酶解工艺:果胶酶0.1%,纤维素酶0.05%,酶解温度45℃,酶解时间2h,酶解p H=4.5。在此最佳酶解条件下,出汁率达86.3%。     

Effects of temperature,inoculum concentration,leaf age,and continuous and interrupted wetness on infection of olive plants by Spilocaea oleagina

Experiments were conducted on olive plants in controlled environments to determine the effect of conidial concentration, leaf age, temperature, continuous and interrupted leaf wetness periods, and relative humidity (RH) during the drier periods that interrupted wet periods, on olive leaf spot (OLS) severity. As inoculum concentration increased from 1·0 × 10² to 2·5 × 10⁵ conidia mL^?1, the severity of OLS increased at all five temperatures (5, 10, 15, 20 and 25°C). A simple polynomial model satisfactorily described the relationship between the inoculum concentration at the upper asymptote (maximum number of lesions) and temperature. The results showed that for the three leaf age groups tested (2–4, 6–8 and 10–12 weeks old) OLS severity decreased significantly (P < 0·001) with increasing leaf age at the time of inoculation. Overall, temperature also affected (P < 0·001) OLS severity, with the lesion numbers increasing gradually from 5°C to a maximum at 15°C, and then declining to a minimum at 25°C. When nine leaf wetness periods (0, 6, 12, 18, 24, 36, 48, 72 and 96 h) were tested at the same temperatures, the numbers of lesions increased with increasing leaf wetness period at all temperatures tested. The minimum leaf wetness periods for infection at 5, 10, 15, 20 and 25°C were 18, 12, 12, 12 and 24 h, respectively. The wet periods during early infection processes were interrupted with drying periods (0, 3, 6, 12, 18 and 24 h) at two levels of RH (70 and 100%). The length of drying period had a significant (P < 0·001) effect on disease severity, the effect depending on the RH during the interruption. High RH (100%) resulted in greater disease severity than low RH (70%). A polynomial equation with linear and quadratic terms of temperature, wetness and leaf age was developed to describe the effects of temperature, wetness and leaf age on OLS infection, which could be incorporated as a forecasting component of an integrated system for the control of OLS.