多杀菌素与碳酸铵复合微球的制备及其对沙棘绕实蝇成虫的防治效果

doi:10.11707/j.1001-7488.20200821

摘要/Abstract

摘要：

目的: 为克服单独使用引诱剂或农药防治沙棘绕实蝇成虫的局限性，通过采用微球包埋的方法将农药和引诱剂制成微球，使二者在林间缓慢释放，明确该药剂引诱及杀死沙棘绕实蝇的效果。方法: 以明胶和聚乳酸作为载体，多杀菌素和碳酸铵为芯材，通过溶剂挥发法制备含有杀虫剂与引诱剂的微球；碳酸铵为水溶性，多杀菌素为脂溶性，因此采用从里到外的"水溶性物质1/油溶性物质/水溶性物质2"的包埋步骤实现对引诱剂和农药的包埋；采用单因素试验设计，同时固定另外4种因素即聚乳酸、多杀菌素、明胶和反应温度，测定不同碳酸铵含量对微球理化性质的影响；采用红外光谱仪检测多杀菌素和碳酸铵是否成功包封在微球内；采用高效液相色谱法（HPLC）测定微球中多杀菌素的含量；应用凯氏定氮仪测量并计算出微球中的碳酸铵包载量；使用透析袋法测量多杀菌素的释放速率；使用手持氨检测器检测微球对氨气的缓释效果；微球的形态采用扫描电子显微镜进行观察和记录；微球的大小和粒度分布则采用激光粒度分析仪进行分析；采用生物测定方法测试微球对沙棘绕实蝇成虫的引诱和致死作用；并在野外开展无人机喷洒微球防治沙棘绕实蝇的试验。结果: 红外光谱分析显示，多杀菌素和碳酸铵被成功包封在微球内；以碳酸铵为变量时，微球中多杀菌素和碳酸铵的载药量和包封率均呈先增大后减小的趋势；微球中的多杀菌素持续释放时间约为15天，高于纯多杀菌素持续释放时间（7天），纯碳酸铵最长释放历期为6天，而微球中的碳酸铵最长缓释历期为14天，能够实现杀虫剂和引诱剂持续释放的目的；制备的4种不同含量碳酸铵形成的微球都呈球形、分散状，大小较为均匀，表面多孔，微球平均粒径60 μm左右；所制备的微球对沙棘绕实蝇的毒杀和引诱作用分别与对照相比都存在显著差异（P < 0.05）；与对照相比，沙棘绕实蝇的虫口密度平均降低约76.13%，沙棘果实的受害率平均降低约75.38%。结论: 采用多杀菌素和碳酸铵制成的微球，可达到缓释效果，具有引诱和杀死沙棘绕实蝇的作用，可用于沙棘绕实蝇的防治。

关键词: 微球, 沙棘绕实蝇, 多杀菌素, 碳酸铵

Abstract:

Objective: Rhagoletis batava obseuriosa(RBO) is one of the major fruit borers of sea buckthorn. There are some limitations in using attractant or pesticide alone have limitations to control the RBO adults,thus the microsphere techniques were used to embed pesticides and attractants into microspheres in order to attract and kill the RBO adults,and prolong their effectiveness period in the field. Method: Gelatin and polylactic acid were used as the wall materials of microspheres,and spinosad and ammonium carbonate were used as the core materials. The microspheres containing the insecticide and attractant were prepared by the solvent evaporation method. Since ammonium carbonate is water-solubile and spinosad is oil-solubile,a water-in-oil- and then in-water(W1/O/W2) double-emulsion method was used to encapsulate the attractant and the insecticide. A single factor experimental design was adopted by taking different quantities of ammonium carbonate as variable,and polylactic acid,spinosad,gelatin and reaction temperature as fixed value,to evaluate the influence of different ammonium carbonate contents encapsulated in the microspheres on the physical and chemical properties of the microspheres. Infrared spectroscopy was used to detect if spinosad and ammonium carbonate were successfully embedded in the microspheres. The spinosad contents in the microspheres were determined using HPLC(High Performance Liquid Chromatography),and the ammonium carbonate content could be calculated by measured the N content within a sample using the Kjeldahl apparatus. Dialysis bag techniques and HPLC method were used to evaluate the release rates of spinosad from the microspheres. The quantities of ammonia released from the microspheres were evaluated every day by using an ammonia detector. The morphology of the microspheres was checked by the scanning electron microscope. The sizes and the span index were measured using a laser particle size analyzer. The attractiveness and lethal effect of the microspheres on the RBO adults were studied by bioassay. The microspheres were also sprayed in the field by the drone to test their control of the RBO adults. Result: The result of the infrared spectroscopy test showed that both the spinosad and the ammonium carbonate were successfully embedded in the microspheres. With increasing the quantities of ammonium carbonate,the quantities of spinosad and ammonium carbonate encapsulated in the microspheres firstly increasing then decreasing. The release of spinosad from the microspheres was able to last for 15 days,which was longer than the release time by the given same quantity of pure spinosad 7 days. The release of ammonium carbonate from the microspheres could last 14 days,also longer than that by the same quantities of pure ammonium carbonate only 6 days. Therefore,the prepared microspheres could fulfil the objective of prolonging the release period of insecticide and the attractant. The microspheres prepared by the different ammonium carbonate contents were spherical and dispersed,with uniform size,porous surface. The average diameter of microsphere was about 60 μm. There were significant differences (P < 0.05) in the attractiveness and lethal effect between the four kinds of ammonium carbonate content microspheres and the control,indicating that the prepared microspheres had attracting and killing ability to the RBO adults. Compared with the control,the population densities of the RBO decreased by about 76.13%,and the damage rates of the sea buckthorn fruits decreased by about 75.38%. Conclusion: The spinosad and ammonium carbonate have been successfully encapsulated into the microspheres,and both embedded compounds had continuous release effect. The prepared microspheres have the attractive and lethal effect on RBO adults,and could be used for the control of RBO.

Key words: microspheres, Rhagoletis batava obseuriosa, spinosad, ammonium carbonate

中图分类号:

S763.306

程态明,李彦艳,魏建荣,苏智. 多杀菌素与碳酸铵复合微球的制备及其对沙棘绕实蝇成虫的防治效果[J]. 林业科学, 2020, 56(8): 191-200.

Taiming Cheng,Yanyan Li,Jianrong Wei,Zhi Su. Preparation of Composit Microspheres of Spinosad and Ammonium Carbonate and the Control Effects on Rhagoletis batava obseuriosa Adults(Diptera: Tephritidae)[J]. Scientia Silvae Sinicae, 2020, 56(8): 191-200.

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项目 Item	LT₅₀/h	95%置信区间 95% Confidence interval	毒力回归方程式 Regression equation	相关系数 Correlation coefficient	P
蒸馏水Distilled water	79.84±8.94a	69.72~94.757	y=-4.369+2.297x	0.921 7	< 0.05
B1	6.23±2.94b	2.784~9.126	y=-1.746+2.197x	0.903 8	< 0.05
B2	7.24±2.99b	4.077~9.965	y=-2.039+2.371x	0.951 2	< 0.05
B3	6.69±3.14b	3.54~9.382	y=-1.826+2.212x	0.923 5	< 0.05
B4	7.18±2.35b	4.414~9.586	y=-2.172+2.537x	0.964 4	< 0.05

项目 Item	LT₅₀ /h	95%置信区间 95% Confidence interval	毒力回归方程式 Regression equation	相关系数 Correlation coefficient	P
蒸馏水distilled water	117.62±9.22a	99.724~149.527	y=-3.397+1.641x	0.927 8	< 0.05
B1	25.05±7.54b	15.305~31.675	y=-3.442+2.461x	0.934 9	< 0.05
B2	23.79±4.10b	18.268~28.113	y=-3.079+2.237x	0.913 5	< 0.05
B3	19.06±4.84b	13.265~23.312	y=-3.993+3.119x	0.965 1	< 0.05
B4	18.50±3.94b	9.422~24.647	y=-3.072+2.424x	0.938 6	< 0.05

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