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CH1:
Is
fixed action pattern a useful concept? |
 |
CH1:
Pleiotropy
of behavioral genes |
|
CH2:
Neurobiology of echolocation in bats |
|
CH2:
Echolocation by insect-eating bats |
|
CH2:
Principles of auditory information-processing derived from neuroethology |
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CH3:
Auditory neuroscience: a time for coincidence? |
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CH3:
Instructed learning in the auditory localization pathway of the barn owl |
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CH3:
Coding of auditory space |
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CH3:
Creating a sence of auditory space |
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CH3:
The synthesis and use of the owl's auditory space map |
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CH4:
Neural correlates of key stimulus & releasing mechanism: a case
study & 2 concepts |
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CH4:
Forebrain & midbrain structures involved in prey-catching behaviour
of toads |
|
CH5:
Selective processing of call songs by auditory neurons in the female
cricket |
|
CH5:
Spatial acuity of ultrasonic hearing in flying crickets |
|
CH6:
Phase-dependent presynaptic modulation of mechanosensory signals in
locust flight |
|
CH6:
The central nervous control of insect flight |
|
CH6:
Neural circuits in the flight system of the locust |
|
CH7:
A lateral excitatory network in the escape circuit of crayfish |
|
CH7:
50 years of a command neuron: the neurobiology of escape behavior of
the crayfish |
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CH7:
The role of higher centers in reprogramming low-level circuits |
|
CH8:
The role of auditory feedback in birdsong |
|
CH8:
Neural mechanisms of birdsong memory |
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CH9:
Small brains, bright minds (honeybees!) |
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CH9:
Cognition in an insect: the honeybee |
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CH10:
Molecular nodes in memory processing: insights from Aplysia |
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CH10:
Cellular mechanisms of learning in Aplysia |
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CH11:
Deconstructing memory in Drosophila |
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CH11:
Mushroom body memoirs: from maps to models |
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CH11:
Mental retardation genes in Drosophila |
