5 research outputs found
Advantages and Disadvantages of the University Entrance Exam Reform Integrating Arts and Science
Get PDF不分文理高考不仅仅是高考文理科合并那么简单,它需要在科目改革的同时照顾到试题的改革,需要在不分文理的前提下照顾到不同学生的潜力倾向,需要以高考的改革来带动中小学教育的变革,因而是一项牵一发而动全身的社会系统工程。我们必须对改革中可能出现的诸多具体问题进行认真思考,并着力解决。Integrating arts and sciences in the university entrance exam is not just merging the arts and sciences.It needs to take the reform of the questions into count as well as the reform of the subjects. It also needs to consider the student's to different tendencies under the premise of integrating arts and sciences. It needs to drive changes in the primary and secondary education with the reform of university entrance examination. It is a social systems engineering. We need to carefully think about it and strive to resolve many of the specific problems in the reforming
Effects of two kinds of organic fertilizers on the growth and nutritional equality of perennial ryegrass
No full text为了了解不同有机肥对黑麦草生长和营养品质的影响,试验在种植黑麦草的土壤施加牛粪和猪粪有机肥,测定了黑麦草粗蛋白、粗纤维、粗脂肪等指标。结果表明:施用有机肥对黑麦草生长有较好的促进作用。在施肥处理120天时,猪粪组株高与对照组表现出极显著差异(P<0.01);猪粪组和牛粪组黑麦草分蘖数和产量也有所增加。施加有机肥能显著提高黑麦草的营养品质,在出苗75天时,猪粪组与牛粪组、对照组的P含量差异显著(P<0...
壳聚糖/siRNA纳米粒的制备与性能研究
No full text利用静电自组装法制备了壳聚糖/siRNA纳米粒,建立了SYBR -old核酸染料法测定siRNA复合率(CR),并系统性考察了n(N)/n(P)比,壳聚糖分子量(Mw)、脱乙酰度(DD )及制备环境pH 值、缓冲液浓度(Bc)对纳米粒siRNA 复合率、粒径及表面电位的影响规律. 结果表明,siRNA 复合率由n(N)/n(P)0.5时的(18.6±4.0)%快速增大至n(N)/n(P)为2时的(92.9±2.0)%,但随n(N)/n(P)增大复合率不再升高;n(N)/n(P)〈2时,难以形成稳定纳米粒,复合物表面电位为负,n(N)/n(P)由5升至150时,纳米粒粒径由(179.3±5.7)nm 增大至(235.5±8.3)nm,表面电位由(17.2±1.3)mV 升高至(23.6±0.9)mV.另外,n(N)/n(P)150时,CR 随DD 升高而升高,随Bc升高而降低;纳米粒粒径随Mw 增大而增大,随DD及缓冲液浓度(Bc)升高而减小;纳米粒表面电位随DD 升高而升高,随pH 值及Bc 升高而降低.n(N)/n(P)比对纳米粒特性及siRNA 复合率影响最为显著,调整n(N)/n(P)、Mw、DD 、pH 值及离子强度可得到siRNA 复合率在90% 以上,粒径100-300nm,表面电位15-25mV 的纳米粒
壳聚糖/siRNA纳米粒的制备与性能研究
No full text利用静电自组装法制备了壳聚糖/siRNA纳米粒,建立了SYBR -old核酸染料法测定siRNA复合率(CR),并系统性考察了n(N)/n(P)比,壳聚糖分子量(Mw)、脱乙酰度(DD )及制备环境pH 值、缓冲液浓度(Bc)对纳米粒siRNA 复合率、粒径及表面电位的影响规律. 结果表明,siRNA 复合率由n(N)/n(P)0.5时的(18.6±4.0)%快速增大至n(N)/n(P)为2时的(92.9±2.0)%,但随n(N)/n(P)增大复合率不再升高;n(N)/n(P)〈2时,难以形成稳定纳米粒,复合物表面电位为负,n(N)/n(P)由5升至150时,纳米粒粒径由(179.3±5.7)nm 增大至(235.5±8.3)nm,表面电位由(17.2±1.3)mV 升高至(23.6±0.9)mV.另外,n(N)/n(P)150时,CR 随DD 升高而升高,随Bc升高而降低;纳米粒粒径随Mw 增大而增大,随DD及缓冲液浓度(Bc)升高而减小;纳米粒表面电位随DD 升高而升高,随pH 值及Bc 升高而降低.n(N)/n(P)比对纳米粒特性及siRNA 复合率影响最为显著,调整n(N)/n(P)、Mw、DD 、pH 值及离子强度可得到siRNA 复合率在90% 以上,粒径100-300nm,表面电位15-25mV 的纳米粒
