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1 nd its contribution to neuronal function and animal behavior.
2 an identified 2 orientations to the study of animal behavior.
3 critical for correct synaptic inhibition and animal behavior.
4 to higher-level biological processes such as animal behavior.
5 fic groups of neurons, circuit function, and animal behavior.
6 ds to be understood in a larger framework of animal behavior.
7 ncreased neuronal cell death, and defects in animal behavior.
8 has important consequences for signaling and animal behavior.
9 rd circuitries and their emergent control of animal behavior.
10 n, dopaminergic levels and the corresponding animal behavior.
11 herd hypothesis are consistent with observed animal behavior.
12 n both the physiology and pathophysiology of animal behavior.
13 zing and understanding neuronal networks and animal behavior.
14 animal communication and, more generally, of animal behavior.
15 with concrete examples from cell biology and animal behavior.
16 general, contributes to circuit function and animal behavior.
17 citable cell action potentials is central to animal behavior.
18 the assembly of neural circuits that encode animal behavior.
19 responses to stimuli and produce changes in animal behavior.
20 GRASP1 in glutamatergic synapse function and animal behavior.
21 ions of neurons and have profound impacts on animal behavior.
22 namic situations that are typical of natural animal behavior.
23 an external MF that is capable of modifying animal behavior.
24 hts into how populations of neurons generate animal behavior.
25 Reward perception guides all aspects of animal behavior.
26 which glia control NRE shape and associated animal behavior.
27 ce and engineering to quantitatively measure animal behavior.
28 t and does not lead to obvious alteration of animal behavior.
29 human dance clearly has no direct analog in animal behavior.
30 n the wild provides fundamental insight into animal behavior.
31 aturation and also modulates many aspects of animal behavior.
32 ard or punishment are fundamental drivers of animal behavior.
33 the functional impact of defined neurons for animal behavior.
34 anism by which a microbial community affects animal behavior.
35 automate the measurement and the analysis of animal behavior.
36 ant consequences for synaptic plasticity and animal behavior.
37 ting interpretable, quantitative measures of animal behavior.
38 ve our understanding of the neural basis for animal behavior.
39 that now seem to underlie much of human and animal behavior.
40 ng animals for relating cellular dynamics to animal behavior.
41 e a classic paradigm for the study of innate animal behavior.
42 and magnetosensitive molecules important for animal behaviors.
43 ng the roles of central 5-HT in a variety of animal behaviors.
44 tein-coupled receptors (GPCRs) regulate many animal behaviors.
45 cal rhythms that might account for circadian animal behaviors.
46 analysis of the impact of a gene mutation on animal behaviors.
47 controlling circuits associated with complex animal behaviors.
48 nfer the sensed levels of these stimuli from animal behaviors.
49 ns one of the most mysterious yet ubiquitous animal behaviors.
50 widely used model for genetic dissection of animal behaviors.
51 tructure of the CNS and in the modulation of animal behaviors.
52 ool to study the neural circuitry underlying animal behaviors.
53 rientation discrimination was evident in the animals' behavior.
54 accumbens influenced specific aspects of the animals' behavior.
55 characteristic properties on the transgenic animals' behavior.
56 best neurons were marginally better than the animals' behavior.
57 sed before discrimination was evident in the animals' behavior.
58 e same sounds generated independently of the animals' behavior.
59 that appeared to recur frequently during the animals' behavior.
60 activity that recurred frequently during the animals' behavior.
61 Taken together, these findings suggest that animal behavior, amyloid plaque deposition, and AbetaPP
62 gnaling pathways are important regulators of animal behavior and are pharmacological targets in a wid
64 ace and have found applications ranging from animal behavior and ecology to speciation, macroevolutio
65 toms, 2) a lack of equivalency between model animal behavior and human psychiatric symptoms, and 3) t
67 Temperature sensation has a strong impact on animal behavior and is necessary for animals to avoid ex
70 s of temporal organization on all aspects of animal behavior and physiology, this study sheds light o
71 cs in cell therapy can link transplantation, animal behavior and postmortem analysis to enable the id
72 eper understanding of olfaction and taste in animal behavior and reproduction provides opportunities
75 Locomotion is an integral component of most animal behaviors and many human diseases and disorders a
76 odulate neural circuits controlling adaptive animal behaviors and physiological processes, such as fe
77 gic neurons have been implicated in numerous animal behaviors and psychiatric disorders, but the mole
78 f Bergmann glia can be activated by specific animal behaviors and undergo excitation of sufficient ma
79 c-based systems that are used for monitoring animal behavior, and it enables simultaneous recording o
80 during sleep there is a complete absence of animal behavior, and the ensemble spike activity is spar
81 Visual motion perception is critical to many animal behaviors, and flies have emerged as a powerful m
82 though descriptions of striking diversity in animal behavior are plentiful, little is known about the
89 odels for the molecular basis of stereotypic animal behavior as well as a target for the design of mo
90 e relationship between neuronal activity and animal behavior, as well as for cell biological and phys
91 ting and important questions about human and animal behavior but at the same time faces uncertainty a
92 direction to move is a ubiquitous feature of animal behavior, but the neural substrates of locomotor
93 tides, critical brain peptides that modulate animal behavior by affecting the activity of almost ever
95 ncepts empirically derived from the study of animal behavior can be used to understand the neural imp
96 ur results indicate that excitable cells and animal behavior can provide modulatory inputs into the e
98 of the neural substrates underlying complex animal behaviors depends on precise activity control too
100 theory and evolution, the evolution of sex, animal behavior, evolutionary transitions and molecular
101 try when injected alone or had any effect on animal behavior except for dizocilpine, CPP, CGP40116 an
102 interactions that are capable of modulating animal behavior, extracellular tyrosine phosphorylation
103 ches have been applied to predict aspects of animal behavior from the recorded activity of population
106 Speculations on the genetic component of animal behavior have been fueled primarily by single-gen
109 ve suggested to explain self-organized group animal behavior: (i) a zone-based model where the group
110 increasing anatomical, electrophysiological, animal behavior, imaging, metabolic, and psychophysical
113 taxa and impacting negatively upon critical animal behaviors including foraging, reproduction, and c
115 euromodulator that regulates many aspects of animal behavior, including mood, aggression, sex drive,
116 Dopaminergic neurons play important roles in animal behavior, including motivation, reward and locomo
117 ut subfield-accounted for induced changes in animal behavior independent of the underlying mechanism
118 discuss further how properties of individual animal behavior, inferred by using the Fokker-Planck equ
123 es has demonstrated that a common feature of animal behavior is of no use to small free-swimming orga
131 r to produce the extraordinary repertoire of animal behaviors is arguably one of the most challenging
132 he nervous system with limited disruption of animal behavior, light-delivery systems beyond fiber opt
133 molting cycles involve rhythmic cellular and animal behaviors linked to the periodic reconstruction o
134 ts that fundamental regulation of this basic animal behavior may be conserved through evolution from
135 k proteins represent an avenue through which animal behavior may directly affect the molecular proper
136 demonstrated in vivo proof of concept in an animal behavior model where known antipsychotics are act
140 LIP neurons did not correlate well with the animals' behavior or any of our estimated measures of va
141 prior to any detectable phenotypes and then animal behavior, pathology and longevity were assessed.
144 neuronal activity is a prime determinant of animal behavior, relationships between astrocytic excita
147 ven after the representation stabilized, the animals' behavior remained different in the novel places
148 arning have each become important domains of animal behavior research in recent years yet have remain
150 Kaufman, with additional insight from recent animal behavior research, behavioral neuroscience, and c
151 ting specific synapses, which indicates that animal behavior results from the coordinated activity of
154 neural circuits.SIGNIFICANCE STATEMENT Many animal behaviors such as birdsong consist of variable se
155 receptors were involved in BPN's effects on animal behavior tests sensitive to antidepressant drugs.
157 ion making is a vital component of human and animal behavior that involves selecting between alternat
158 ts often promise to illuminate sophisticated animal behavior, the analyses brought to bear on these d
159 cues from the environment are used to direct animal behavior through a complex network of connections
160 ioral ecologists argue that evolution drives animal behavior to efficiently solve the problems animal
161 rchers in ecology, conservation biology, and animal behavior using logical argument and repeated Mont
163 erstand how such microbial parasites control animal behavior, we examine the cell-level interactions
165 important neural regulators of many complex animal behaviors, we explored the function of the FMRFam
166 ein localization, synaptic transmission, and animal behaviors, we find that reduced function of UNC-1
167 tion of dopamine D1 or D2 antagonists on the animals' behavior were similar in that both reduced brea
168 corporating the high-pass controller matches animal behavior, whereas the model with the low-pass con
169 ther the generative mechanisms for human and animal behavior will require a philosophically indetermi
170 ed by the latest series of studies comparing animal behavior with electrophysiological recordings in
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