精梳棉卷成卷过程中起泡问题分析

介绍了成卷工艺对棉卷结构的影响以及棉卷成卷过程中起泡现象与准备工艺的关系.分析了棉卷成卷工艺过程中起泡过程和起泡原因,提出了防止起泡的措施.     

煮熟和干燥处理对黄藤笋抗氧化活性的影响

通过测定黄藤熟笋、生笋(鲜切笋)、熟笋干和生笋干的水和4种不同浓度乙醇提取物中的自由基清除能力、总还原能力、总多酚含量和总黄酮含量,研究了煮熟、干燥加工方法对黄藤笋提取物抗氧化活性的影响。结果表明,煮熟处理能保持或提高提取物的抗氧化活性,干燥处理则相反。乙醇提取物比水提取物具有更高的抗氧化活性,以50%~75%的乙醇提取溶剂效果最好。熟笋在所有溶剂中的自由基清除能力、总还原能力、总多酚含量和总黄酮含量均表现出最高水平,表明煮熟是黄藤笋适宜的加工利用方式。     

Wx^mp基因背景下可溶性淀粉合成酶基因SSⅡa和去分支酶基因PUL对水稻蒸煮食味品质的影响

【目的】分析在同一主效基因(Wx^mp)背景下可溶性淀粉合成酶基因SSⅡa和去分支酶基因PUL对稻米蒸煮食味品质的影响,以期为水稻品质遗传改良提供依据。【方法】选择在SSⅡa和PUL存在多态性而其他淀粉合成酶相关基因没有多态性的半糯品系宁0145和粳稻品种武运粳21进行杂交,获得F2群体与F3株系。利用分子标记,选择含有Wx^mp基因的F2单株与F3株系,将这些F2单株与F3株系分成SSⅡa^nPUL^n、SSⅡa^nPUL^w、SSⅡa^wPUL^n和SSⅡa^wPUL^w4种基因型(n和w分别表示该基因来源于宁0145和武运粳21),分析不同基因型蒸煮食味品质性状的差异,探讨同一Wxmp基因背景下不同SSⅡa和PUL等位基因对蒸煮食味品质性状的影响。【结果】不同基因型间蒸煮食味品质性状均存在显著差异,来源于武运粳21的SSⅡa^w基因和PUL^w基因分别使直链淀粉含量增加0.29%~1.00%和0.62%~1.18%,且PUL的效应大于SSⅡa,两者间存在互作效应。SSⅡa^w基因和PUL^w基因降低胶稠度和崩解值,提高了热浆黏度、冷胶黏度、消减值和回复值,对糊化温度、峰值黏度和峰值时间的作用较小。【结论】明确了Wx^mp背景下SSⅡa和PUL基因对稻米蒸煮食味品质的遗传效应,该研究结果为SSⅡa和PUL基因的分子标记辅助选择改良稻米品质提供了理论依据。     

单缸柴油机曲轴装配方式的改进设计

曲轴部件是整台柴油机的关键部件,装配质量的好坏直接影响柴油机的性能.目前单缸柴油机曲轴装配主要是手工装配,转配过程费事费力.通过重新设计工艺工装设备,使用液压静压方式,可以减少工人劳动强度、提高劳动生产率.     

一种新式护坡——模压混凝土砌块护坡

在对传统护坡型式缺陷进行分析的基础上,介绍了一种新式护坡—模压混凝土砌块护坡,通过对其生产工艺、施工工艺以及优点等方面的阐述,说明该护坡系统有良好应用前景。     

牛基因组DNA两种提取方法的比较研究

研究哺乳动物基因组DNA的水煮抽提法，并将传统的酚仿抽提法和水煮法进行比较，水煮法即通过对细胞的煮沸和冷却，使细胞破裂、蛋白变性，从而获得用于PCR扩增的模板DNA的方法。通过电泳分析和PCR扩增检测了所提取基因组DNA的完整性、可行性。检测时采用3对引物对2种方法提取的DNA进行了PCR扩增，同时对冷冻保存的基因组DNA也进行了扩增检测。结果表明：水煮法提取基因组DNA是一种快速、简便、经济、高效的方法。     

泰安市污水处理厂处理城市污水的研究

本文详细阐述了AB工艺的原理及A2O工艺的特点。并就测得的数据分析了CODcr与BOD5之间显著的线性关系;对年间、季度间的CODcr去除率进行方差分析,结果表明CODcr年间去除率存在一定差异,季度间去除率稳定;通过比较TP与TN的去除率,分析了具有脱氮除磷功能的A2O工艺在实际运行中存在的问题。     

Fatty Acid Porfiles of Farm-Raised Catfish Fillet:

Fatty acid profiles of the total lipids and the phospholipid classes of farm-raised channel catfish (Ictalurus punctatus) fillets were analyzed. Monoenes represented 49.22 mol% of the total lipid fatty acids while polyunstaturated fatty acids (PUFA) accounted for 19.37 mol%. The total n-3 PUFA content was low (4.22 mol%). The total saturated fatty acids as 31.44 mol %. Catfish contained phosphatidylcholine (PC), phosphatidylethanolamine (PE), phosphatidylinositol (PI), phosphatidylserine (PS), lysophosphatidylcholine (LPC), and sphingomyelin (SPH). Analysis for the individual phospholipid class fatty acid profiles indicated that PI had a high concentration of 18:0 (33.20 mol%) and 20:4 n-6 (13.08 mol%). Phosphatidylethanolamine had the highest concentrations of combined eicosapentaenoic acid, and docoshahexaenoic acid, of 17.37 mol%. Higher ratios of n-3/n-6 PUFA were found in the phospholipid classes than the total lipids. LPC and SPH did not contain measurable PUFA of the n-3 series. The level of 18:1 n-9 in PC, PE, and LPC was approximately 31 mol% whereas in PI, PS, and SPH, the level was approximately 16 mol%. The understanding of the basic distribution of fatty acids in the individual phospholipid classes of channel catfish may be an essential first step in explaining the protective role of 18:1 n-9 and n-3 PUFA against thrombotic and cardiovascular disorder in humans.     

Pigeonpea Nutrition and Its Improvement

Abstract

Pigeonpea (Cajanus cajan [L.] Millsp.), known by several vernacular and trade names such as red gram, tuar, Angola pea, Congo pea, yellow dhal and oil dhal, is one of the major grain legume crops of the tropics and sub-tropics. It is a favorite crop of small holder dryland farmers because it can grow well under subsistence level of agriculture and provides nutritive food, fodder, and fuel wood. It also improves soil by fixing atmospheric nitrogen. India by far is the largest pigeonpea producer where it is consumed as decorticated split peas, popularly called as ‘dhal’ In other countries, its consumption as whole dry seed and green vegetable is popular. Its foliage is used as fodder and milling by-products form an excellent feed for domestic animals. Pigeonpea seeds contain about 20-22% protein and appreciable amounts of essential amino acids and minerals. Dehulling and boiling treatments of seeds get rid of the most antinutritional factors such as tannins and enzyme inhibitors. Seed storage causes considerable losses in the quality of this legume. The seed protein of pigeonpea has been successfully enhanced by breeding from 20-22% to 28-30%. Such lines also agronomically performed well and have acceptable seed size and color. The high-protein lines were found nutritionally superior to the cultivars because they would provide more quantities of utilizable protein and sulfur-containing amino acids.