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以丁酸和 DEET 混合物作为条件刺激和非条件刺激,对高加索蜜蜂(Apis mellifera caucasica)进行触须条件反射实验。

Proboscis conditioning experiments with honeybees, Apis mellifera caucasica, with butyric acid and DEET mixture as conditioned and unconditioned stimuli.

机构信息

Laboratory of Behavioral Biology and Comparative Psychology, Oklahoma State University, Stillwater, Oklahoma, USA.

出版信息

J Insect Sci. 2010;10:122. doi: 10.1673/031.010.12201.

DOI:10.1673/031.010.12201
PMID:20879917
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3388969/
Abstract

Three experiments are described investigating whether olfactory repellents DEET and butyric acid can support the classical conditioning of proboscis extension in the honeybee, Apis mellifera caucasica (Hymenoptera: Apidae). In the first experiment DEET and butyric acid readily led to standard acquisition and extinction effects, which are comparable to the use of cinnamon as a conditioned stimulus. These results demonstrate that the odor of DEET or butyric acid is not intrinsically repellent to honey bees. In a second experiment, with DEET and butyric acid mixed with sucrose as an unconditioned stimulus, proboscis conditioning was not established. After several trials, few animals responded to the unconditioned stimulus. These results demonstrate that these chemicals are gustatory repellents when in direct contact. In the last experiment a conditioned suppression paradigm was used. Exposing animals to butyric acid or DEET when the proboscis was extended by direct sucrose stimulation or by learning revealed that retraction of the proboscis was similar to another novel odor, lavender, and in all cases greatest when the animal was not permitted to feed. These results again demonstrate that DEET or butyric acid are not olfactory repellents, and in addition, conditioned suppression is influenced by feeding state of the bee.

摘要

描述了三个实验,旨在研究驱虫剂避蚊胺和丁酸是否能支持高加索蜜蜂(膜翅目:蜜蜂科)的触角延伸经典条件反射。在第一个实验中,避蚊胺和丁酸很容易导致标准的获得和消退效应,与肉桂作为条件刺激的效果相当。这些结果表明,避蚊胺或丁酸的气味对蜜蜂本身并没有内在的驱避性。在第二个实验中,当避蚊胺和丁酸与蔗糖混合作为非条件刺激时,触角条件反射并没有建立起来。经过几次试验,很少有动物对非条件刺激做出反应。这些结果表明,这些化学物质在直接接触时具有味觉驱避性。在最后一个实验中,使用了条件抑制范式。当动物的触角因直接蔗糖刺激或学习而伸展时,暴露于丁酸或避蚊胺中,揭示了触角的回缩与另一种新的气味,薰衣草相似,在所有情况下,当动物不允许进食时,回缩最大。这些结果再次表明,避蚊胺或丁酸不是嗅觉驱避剂,此外,条件抑制受蜜蜂进食状态的影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/eaf2/3388969/9270d3fd9acf/f01_01.jpg

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