电子时代的医学图书馆馆员和循证医学

 

简要阐述了循证医学的概念及其基本特点，探讨了电子时代循证医学对于医学图书馆员的要

求，同时提出了电子时代医学图书馆员应该具备的知识和技能。

     

糖槭叶枯病发病规律及防治

糖槭叶枯病 Phyllosticta negundinis病菌孢子放散开始期和高峰期与每年的温、湿度变化有关。病害发生严重程度与降雨量关系密切 ,降雨早且量大时病害严重。病菌以分生孢子器和分生孢子在病叶上越冬 ,通过气流传播成为翌年初侵染源。喷洒 70 %甲基托布津可湿性粉剂 10 0 0倍液和 75%百菌清可湿性粉剂 80 0倍液均能收到较好的效果     

刺槐外斑尺蠖的发生与防治

刺槐外斑尺蠖Ectropis excellens Butler危害刺槐、枣树及农作物，在河南省安阳市一年发生4代，9月下旬至10月上旬以蛹在树干周围1．5m的土层中越冬，翌年4月中旬羽化。鸟类、天敌昆虫等对害虫有较好的控制作用，防治措施为营造混交林、保护天敌、喷施灭幼脲等生物制剂。     

关中西部四灌区旱情规律分析

为给关中西部灌区水资源合理调控提供依据，在简述干旱及其分类的基础上，指出了关中西部各类干旱多源于气象干旱。对该区7个气象站的年降水进行分析表明，各气象站年降水量的变差系数均为0．25，偏态系数均为0．5。以兴平气象站作为代表站对不同历时的旱情进行了分析，结果显示11月到来年2月发生重旱和特旱的概率较大，在30％左右，特别是12月份，概率达54％，且以特旱为主；7、8月份以中旱和重旱为主；夏玉米播前发生特旱的概率较高，达27％，拔节孕穗和抽穗开花期以特旱为主，概率达33％；冬小麦的越冬和麦黄期以特旱为主，发生概率在30％左右。     

台湾稻螟发生期预测技术与应用

作者采用室内外结合的方法,根据台湾稻螟幼虫、蛹、卵的形态特征,制定了台湾稻螟分龄分级标准,并按所测定的相应虫态历期,采用分龄分级法进行了3年的发生期预测验证,平均准确率达96.7％,用于指导大田防治1.93万hm~2,平均防治效果达85.8％。     

生姜根结线虫病原鉴定及发生规律

采用田间调查、接种试验、电镜与显微镜观察以及酯酶同工酶电泳等方法,对引发生姜癞皮病的病原及发生规律进行了研究.结果表明,引起生姜癞皮病的病原为南方根结线虫Meloidogyne incognita.该病在每年6月中旬开始发生,8、9月份危害严重.病原在生姜上一年可发生完整的4代,完成1代平均约需35天.病原主要在0～40cm的土层内分布和危害,但具体分布情况依寄主生长状况而稍有差异.南方根结线虫繁殖速率受初始接种密度的影响也很大,当初始接种密度较低时,线虫繁殖速率较高,初始接种密度增大,繁殖速率降低,其平衡密度为每100g干土746.20个卵.     

生姜癞皮病的发生危害及病原初步鉴定

生姜癞皮病在山东7月开始发病,8月中旬至9月中旬为盛发期。病株植株矮小、茎细、分枝少,叶色变淡,根茎表皮疣裂,根系腐烂,产量品质降低。病原物为南方根结线虫。砂质土壤、连作重茬、过量施钾肥均可加重该病的发生。     

Simple diagnosis using ethanol immersion of strawberry plants with latent infection by Colletotrichum acutatum, Dendrophoma obscurans, and Fusarium oxysporum f. sp. fragariae

Simple diagnosis by ethanol immersion (SDEI) to detect Glomerella cingulata was used to detect three other fungi that also cause latent infection of strawberry plants. Signs on strawberry leaves with asymptomatic latent infection by Colletotrichum acutatum became visible using SDEI. Salmon-pink conidial masses were produced in the acervuli on the treated leaves 5 days after incubation at 28°C. In the case of Dendrophoma obscurans, pycnidia with amber conidial masses formed 5 days after incubation at 28°C. The pycnidia were observed mainly on the ribs, and conidial masses exuded from the ostiole. These macroscopic conidial masses were similar to those of G. cingulata and C. acutatum. When water was dripped onto a lesion caused by D. obscurans, the pycnidia exuded white filamentous conidial masses, making the distinction of D. obscurans from G. cingulata or C. acutatum. On petioles with latent infection by Fusarium oxysporum f. sp. fragariae, white aerial hyphae grew out from the vascular tissues on the cut surface 3 days after incubation at 28°C and were easily observed by eye or with a loupe. Thus, SDEI was also useful for diagnosing latent infection of strawberry plants by C. acutatum, D. obscurans, and F. oxysporum f. sp. fragariae.     

Trichoderma Biocontrol of Colletotrichum acutatum and Botrytis cinerea and Survival in Strawberry

Trichoderma isolates are known for their ability to control plant pathogens. It has been shown that various isolates of Trichoderma, including T. harzianum isolate T-39 from the commercial biological control product TRICHODEX, were effective in controlling anthracnose (Colletotrichum acutatum) and grey mould (Botrytis cinerea) in strawberry, under controlled and greenhouse conditions. Three selected Trichoderma strains, namely T-39, T-161 and T-166, were evaluated in large-scale experiments using different timing application and dosage rates for reduction of strawberry anthracnose and grey mould. All possible combinations of single, double or triple mixtures of Trichoderma strains, applied at 0.4% and 0.8% concentrations, and at 7 or 10 day intervals, resulted in reduction of anthracnose severity; the higher concentration (0.8%) was superior in control whether used with single isolates or as a result of combined application of two isolates, each at 0.4%. Only a few treatments resulted in significant control of grey mould. Isolates T-39 applied at 0.4% at 2 day intervals, T-166 at 0.4%, or T-161 combined with T-39 at 0.4% were as effective as the chemical fungicide fenhexamide. The survival dynamics of populations of the Trichoderma isolates (T-39, T-105, T-161 and T-166) applied separately was determined by dilution plating and isolates in the mixtures calculated according to the polymerase chain reaction (PCR) using repeat motif primers. The biocontrol isolates were identified to the respective species T. harzianum (T-39), T. hamatum (T-105), T. atroviride (T-161) and T. longibrachiatum (T-166), according to internal transcribed spacer sequence analysis.