Simultaneous long-term recordings at two neuronal processing stages in behaving honeybees

In both mammals and insects neuronal information is processed in different higher and lower order brain centers. These centers are coupled via convergent and divergent anatomical connections including feed forward and feedback wiring. Furthermore, information of the same origin is partially sent via...

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Bibliographic Details
Published in:Journal of visualized experiments 2014-07 (89)
Main Authors: Brill, Martin Fritz, Reuter, Maren, Rössler, Wolfgang, Strube-Bloss, Martin Fritz
Format: Article
Language:English
Subjects:
Animals
Apis mellifera
Bees - anatomy & histology
Bees - physiology
Brain - physiology
Electrodes, Implanted
Electrophysiology - instrumentation
Electrophysiology - methods
Neurons - physiology
Neuroscience
Olfactory Pathways - physiology
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Summary:In both mammals and insects neuronal information is processed in different higher and lower order brain centers. These centers are coupled via convergent and divergent anatomical connections including feed forward and feedback wiring. Furthermore, information of the same origin is partially sent via parallel pathways to different and sometimes into the same brain areas. To understand the evolutionary benefits as well as the computational advantages of these wiring strategies and especially their temporal dependencies on each other, it is necessary to have simultaneous access to single neurons of different tracts or neuropiles in the same preparation at high temporal resolution. Here we concentrate on honeybees by demonstrating a unique extracellular long term access to record multi unit activity at two subsequent neuropiles1, the antennal lobe (AL), the first olfactory processing stage and the mushroom body (MB), a higher order integration center involved in learning and memory formation, or two parallel neuronal tracts2 connecting the AL with the MB. The latter was chosen as an example and will be described in full. In the supporting video the construction and permanent insertion of flexible multi channel wire electrodes is demonstrated. Pairwise differential amplification of the micro wire electrode channels drastically reduces the noise and verifies that the source of the signal is closely related to the position of the electrode tip. The mechanical flexibility of the used wire electrodes allows stable invasive long term recordings over many hours up to days, which is a clear advantage compared to conventional extra and intracellular in vivo recording techniques.
ISSN:1940-087X
1940-087X
DOI:10.3791/51750