ライフサイエンスコーパス: animal behavior

1 aturation and also modulates many aspects of animal behavior.

2 ard or punishment are fundamental drivers of animal behavior.

3 the functional impact of defined neurons for animal behavior.

4 automate the measurement and the analysis of animal behavior.

5 ant consequences for synaptic plasticity and animal behavior.

6 rofoundly impact landscapes, ecosystems, and animal behavior.

7 ting interpretable, quantitative measures of animal behavior.

8 Motion vision is important in guiding animal behavior.

9 ve our understanding of the neural basis for animal behavior.

10 that now seem to underlie much of human and animal behavior.

11 ng animals for relating cellular dynamics to animal behavior.

12 e a classic paradigm for the study of innate animal behavior.

13 nd its contribution to neuronal function and animal behavior.

14 an identified 2 orientations to the study of animal behavior.

15 critical for correct synaptic inhibition and animal behavior.

16 to higher-level biological processes such as animal behavior.

17 fic groups of neurons, circuit function, and animal behavior.

18 ds to be understood in a larger framework of animal behavior.

19 has important consequences for signaling and animal behavior.

20 rd circuitries and their emergent control of animal behavior.

21 n, dopaminergic levels and the corresponding animal behavior.

22 herd hypothesis are consistent with observed animal behavior.

23 nitary choice, is a fundamental component of animal behavior.

24 n both the physiology and pathophysiology of animal behavior.

25 zing and understanding neuronal networks and animal behavior.

26 seen a surge in methods to track and analyze animal behavior.

27 animal communication and, more generally, of animal behavior.

28 with concrete examples from cell biology and animal behavior.

29 citable cell action potentials is central to animal behavior.

30 the assembly of neural circuits that encode animal behavior.

31 sure to environmental contaminants can alter animal behavior.

32 d effectively as possible, and even to study animal behavior.

33 vely few lncRNAs have been shown to underlie animal behavior.

34 from large neural populations and unimpeded animal behavior.

35 tant role in unravelling the complexities of animal behavior.

36 reased neurotransmitter levels and corrected animal behavior.

37 t decisions are ubiquitous in both human and animal behavior.

38 rless tracking has revolutionized studies of animal behavior.

39 lity to directly relate receptor dynamics to animal behavior.

40 ntly regulates neuronal circuit activity and animal behavior.

41 it has never been used for the assessment of animal behavior.

42 es window of potentiation without effects on animal behavior.

43 ut the patterns, causes, and consequences of animal behavior.

44 IL-17 production mediates CNS processes and animal behavior.

45 to investigate physiological constraints on animal behavior.

46 s homeostatic plasticity can be reflected in animal behavior.

47 e sensory detection is key for understanding animal behavior.

48 Adrenergic signaling profoundly modulates animal behavior.

49 fects on homeostatic synaptic plasticity and animal behavior.

50 red by tracking neuron shape, physiology, or animal behavior.

51 underlie brain function and ultimately shape animal behavior.

52 anism by which a microbial community affects animal behavior.

53 or describing brain activity associated with animal behavior.

54 ncreased neuronal cell death, and defects in animal behavior.

55 general, contributes to circuit function and animal behavior.

56 responses to stimuli and produce changes in animal behavior.

57 GRASP1 in glutamatergic synapse function and animal behavior.

58 ions of neurons and have profound impacts on animal behavior.

59 namic situations that are typical of natural animal behavior.

60 an external MF that is capable of modifying animal behavior.

61 hts into how populations of neurons generate animal behavior.

62 Reward perception guides all aspects of animal behavior.

63 which glia control NRE shape and associated animal behavior.

64 ce and engineering to quantitatively measure animal behavior.

65 t and does not lead to obvious alteration of animal behavior.

66 human dance clearly has no direct analog in animal behavior.

67 n the wild provides fundamental insight into animal behavior.

68 widely used model for genetic dissection of animal behaviors.

69 tructure of the CNS and in the modulation of animal behaviors.

70 ool to study the neural circuitry underlying animal behaviors.

71 integrate diverse signals to elicit discrete animal behaviors.

72 ng the roles of central 5-HT in a variety of animal behaviors.

73 cal rhythms that might account for circadian animal behaviors.

74 analysis of the impact of a gene mutation on animal behaviors.

75 ystems to study the effects of pollutants on animal behaviors.

76 sking information vital to various nocturnal animal behaviors.

77 rks to accurately quantify a wide variety of animal behaviors.

78 ns one of the most mysterious yet ubiquitous animal behaviors.

79 and magnetosensitive molecules important for animal behaviors.

80 tein-coupled receptors (GPCRs) regulate many animal behaviors.

81 controlling circuits associated with complex animal behaviors.

82 nfer the sensed levels of these stimuli from animal behaviors.

83 e same sounds generated independently of the animals' behavior.

84 that appeared to recur frequently during the animals' behavior.

85 activity that recurred frequently during the animals' behavior.

86 accumbens influenced specific aspects of the animals' behavior.

87 characteristic properties on the transgenic animals' behavior.

88 best neurons were marginally better than the animals' behavior.

89 plitude, which is also inconsistent with the animals' behavior.

90 rientation discrimination was evident in the animals' behavior.

91 sed before discrimination was evident in the animals' behavior.

92 tagonist abolishes the ketamine's effects on animals' behaviors.

93 toreceptor signals, plays important roles in animal behavior.(1-4) Surprisingly, however, comparative

94 Taken together, these findings suggest that animal behavior, amyloid plaque deposition, and AbetaPP

95 gnaling pathways are important regulators of animal behavior and are pharmacological targets in a wid

96 al plasticity mechanisms that are crucial to animal behavior and circuit development.

97 tential to provide information on aspects of animal behavior and ecology as well as plant-animal inte

98 ace and have found applications ranging from animal behavior and ecology to speciation, macroevolutio

99 very of ecosystem services, yet the study of animal behavior and ecosystem services rarely intersect.

100 th of these options significantly affect the animal behavior and hence also the recorded brain activi

101 ite the importance of sensory thresholds for animal behavior and human health, we do not yet have a f

102 toms, 2) a lack of equivalency between model animal behavior and human psychiatric symptoms, and 3) t

103 nition of odorous objects universally shapes animal behavior and is crucial for survival.

104 Temperature sensation has a strong impact on animal behavior and is necessary for animals to avoid ex

105 The effects of glutamate spillover on animal behavior and its neural correlates are poorly und

106 uding histone and DNA modifications regulate animal behavior and memory.

107 e transformed our ability to observe aquatic animal behavior and movement.

108 g have guided our understanding of human and animal behavior and neural processing.

109 Animal behavior and neural recordings show that the brai

110 euromodulatory systems; however, its role in animal behavior and neuropsychiatric processes is poorly

111 s of temporal organization on all aspects of animal behavior and physiology, this study sheds light o

112 cs in cell therapy can link transplantation, animal behavior and postmortem analysis to enable the id

113 ers neuroprotection that both extends normal animal behavior and prolongs the life span of prion-dise

114 eper understanding of olfaction and taste in animal behavior and reproduction provides opportunities

115 ngs of ecology, infectious disease dynamics, animal behavior and social interactions of humans.

116 Color patterns of bird plumage affect animal behavior and speciation.

117 patial distribution of food resources affect animal behavior and survival.

118 precisely how changes to myelination affects animal behavior and underlying action potential conducti

119 mited to tethered embodiments that constrain animal behaviors and experimental designs.

120 Locomotion is an integral component of most animal behaviors and many human diseases and disorders a

121 odulate neural circuits controlling adaptive animal behaviors and physiological processes, such as fe

122 gic neurons have been implicated in numerous animal behaviors and psychiatric disorders, but the mole

123 f Bergmann glia can be activated by specific animal behaviors and undergo excitation of sufficient ma

124 f wildlife can impact numerous aspects of an animals' behavior and ecology.

125 ay have hidden and underestimated effects on animals' behavior and ecology.

126 ators are considered primary factors shaping animal behavior, and both are likely drivers of movement

127 pell out their consequences for the study of animal behavior, and illustrate them with various exampl

128 c-based systems that are used for monitoring animal behavior, and it enables simultaneous recording o

129 sis, microgliosis, synapse loss, compromised animal behavior, and the aggravation of Alzheimer's dise

130 during sleep there is a complete absence of animal behavior, and the ensemble spike activity is spar

131 Visual motion perception is critical to many animal behaviors, and flies have emerged as a powerful m

132 Escape is one of the most studied animal behaviors, and there is a rich normative theory t

133 sed tolerance to humans changes a variety of animal behaviors, and these behavioral modifications, su

134 though descriptions of striking diversity in animal behavior are plentiful, little is known about the

135 ave been demonstrated, sub-lethal effects on animal behavior are relatively under-studied.

136 Though sex differences in animal behavior are ubiquitous, their neural and genetic

137 Complex animal behaviors are built from dynamical relationships

138 Animal behaviors are commonly organized into long-lastin

139 molecular modulators promoting or inhibiting animal behaviors are key steps to understand how neural

140 Although human and animal behaviors are largely shaped by reinforcement and

141 Complex animal behaviors are likely built from simpler modules,

142 ference exists could shed light on how whole animal behaviors are organized.

143 Animal behaviors are reinforced by subsequent rewards fo

144 Many 'hard-wired', innate animal behaviors are related to reproduction.

145 Goal-directed animal behaviors are typically composed of sequences of

146 terations in FB neural-circuit wiring affect animal behaviors are unknown.

147 Animal behavior arises from the coordinated activity of

148 odels for the molecular basis of stereotypic animal behavior as well as a target for the design of mo

149 We focus in particular on animal behaviors as a basis for understanding potential

150 e relationship between neuronal activity and animal behavior, as well as for cell biological and phys

151 ve emerged to automate the quantification of animal behavior at a resolution not previously imaginabl

152 uirements similar to those needed to monitor animal behavior at high resolution and at low tag mass.

153 ting and important questions about human and animal behavior but at the same time faces uncertainty a

154 direction to move is a ubiquitous feature of animal behavior, but the neural substrates of locomotor

155 tides, critical brain peptides that modulate animal behavior by affecting the activity of almost ever

156 ole of autophagy in mouse SPN physiology and animal behavior by generating conditional knockouts of A

157 The manipulation of animal behavior by parasitic organisms is one of the mos

158 Astrocytes can affect animal behavior by regulating tripartite synaptic transm

159 Tracking animal behavior by video is one of the most common tasks

160 hat robust, reproducible neural function and animal behavior can be achieved.

161 Animal behavior can be decomposed into a sequence of dis

162 ncepts empirically derived from the study of animal behavior can be used to understand the neural imp

163 ur results indicate that excitable cells and animal behavior can provide modulatory inputs into the e

164 Animal behavior can, therefore, serve as a functional re

165 ical attributes of the stimulus and that the animals' behavior can be decoded from the activity of th

166 ces, coprolites represent direct evidence of animal behavior captured in the fossil record.

167 How animal behavior changes over time has been explored thro

168 Muth, who studies bees to better understand animal behavior, cognition and health at the University

169 Studies of animal behavior consistently demonstrate that the social

170 An investigation into animal behavior data archiving practices revealed low ra

171 Increasing archiving of animal behavior data will improve the integrity of curre

172 of the neural substrates underlying complex animal behaviors depends on precise activity control too

173 In particular, animal behavior displays both fractal dynamics and perio

174 only help understand how the organization of animal behavior emerges from multiscale interactions bet

175 theory and evolution, the evolution of sex, animal behavior, evolutionary transitions and molecular

176 try when injected alone or had any effect on animal behavior except for dizocilpine, CPP, CGP40116 an

177 interactions that are capable of modulating animal behavior, extracellular tyrosine phosphorylation

178 ches have been applied to predict aspects of animal behavior from the recorded activity of population

179 A vast array of animal behavior-from locomotion to human speech-is thoug

180 Extinct animal behavior has often been inferred from qualitative

181 Linking structural changes in neurons to animal behavior has proven challenging.

182 er this affects neuronal fate, function, and animal behavior, has not been explored.

183 Speculations on the genetic component of animal behavior have been fueled primarily by single-gen

184 Few subjects in animal behavior have more exotic mystery than magnetic-f

185 ationships between astrocytic excitation and animal behavior have remained opaque.

186 ve suggested to explain self-organized group animal behavior: (i) a zone-based model where the group

187 increasing anatomical, electrophysiological, animal behavior, imaging, metabolic, and psychophysical

188 Foraging theory predicts animal behavior in many contexts.

189 Artificial light at night (ALAN) changes animal behavior in multiple invertebrates and vertebrate

190 Crucially, animal behavior in natural settings implies that the bra

191 l task or stimulate neural activity based on animal behavior in real-time is an important tool for ex

192 We investigated the role of animal behavior in retention and homing of coral reef fi

193 Measuring animal behavior in the context of experimental manipulat

194 of whether and how such pollutants influence animal behavior in the wild.

195 ate new investigations into genetic basis of animal behaviors in natural 3-D environments.

196 singly recognized the importance of studying animal behaviors in naturalistic environments to gain de

197 urces also offer many opportunities to study animal behavior including long-term and large-scale comp

198 taxa and impacting negatively upon critical animal behaviors including foraging, reproduction, and c

199 The striking patterns of collective animal behavior, including ant trails, bird flocks, and

200 euromodulator that regulates many aspects of animal behavior, including mood, aggression, sex drive,

201 Dopaminergic neurons play important roles in animal behavior, including motivation, reward and locomo

202 ut subfield-accounted for induced changes in animal behavior independent of the underlying mechanism

203 Tit-for-tat is a familiar principle from animal behavior: individuals respond in kind to being he

204 discuss further how properties of individual animal behavior, inferred by using the Fokker-Planck equ

205 Animal behavior involves complex interactions between ph

206 Animal behavior is adapted to the sensory environment in

207 How pruning of single-neuron endings impacts animal behavior is also unclear.

208 Investigating the evolution of animal behavior is difficult.

209 Animal behavior is directed by the integration of sensor

210 Animal behavior is encoded in neuronal circuits in the b

211 An explicit focus on information in animal behavior is far from novel - we simply build on t

212 Animal behavior is highly structured.

213 What fascinates us about animal behavior is its richness and complexity, but unde

214 Tolman proposed that complex animal behavior is mediated by the cognitive map, an int

215 Here we argue that most animal behavior is not the result of clever learning alg

216 Effectively shaping human and animal behavior is of great practical and theoretical im

217 es has demonstrated that a common feature of animal behavior is of no use to small free-swimming orga

218 The evolutionary diversification of animal behavior is often associated with changes in the

219 Animal behavior is often viewed as stemming from predict

220 they reconfigure neural circuits and modify animal behavior is poorly understood.

221 ropogenic substrate vibrations in disrupting animal behavior is poorly understood.

222 Much of animal behavior is regulated to accomplish goals necessa

223 Animal behavior is remarkably robust despite constant ch

224 Animal behavior is shaped both by evolution and by indiv

225 Animal behavior is shaped by a variety of "internal stat

226 Animal behavior is shaped through interplay among genes,

227 ese inputs are integrated to jointly control animal behavior is still poorly understood.

228 Animal behavior is synchronized to the 24-hour light:dar

229 An important feature of animal behavior is the ability to switch rapidly between

230 Animal behavior is ultimately the product of gene regula

231 ceived and transmitted to modulate HIF-1 and animal behavior is unknown.

232 r to produce the extraordinary repertoire of animal behaviors is arguably one of the most challenging

233 he nervous system with limited disruption of animal behavior, light-delivery systems beyond fiber opt

234 molting cycles involve rhythmic cellular and animal behaviors linked to the periodic reconstruction o

235 aging task based on an ecological account of animal behavior (marginal value theorem), human particip

236 ts that fundamental regulation of this basic animal behavior may be conserved through evolution from

237 k proteins represent an avenue through which animal behavior may directly affect the molecular proper

238 demonstrated in vivo proof of concept in an animal behavior model where known antipsychotics are act

239 The conventional paradigm in animal behavior modelling consists of maximisation of so

240 Animal behavior, molecular phenotypes, neuropathology, a

241 bservations have shown distinct responses in animal behavior often emulating nocturnal behavior, the

242 Animal behaviors often are decomposable into discrete, s

243 analyzing synaptic integrity and performing animal behavior on T1R3KO mice.

244 s, links between the proposed algorithms and animal behaviors or circuit mechanisms remain elusive.

245 LIP neurons did not correlate well with the animals' behavior or any of our estimated measures of va

246 prior to any detectable phenotypes and then animal behavior, pathology and longevity were assessed.

247 Animal behavior plays a critical role in the delivery of

248 ogen infection that are linked to individual animal behavior, prey choice, and habitat use.

249 Animal behavior provides context for understanding disea

250 ttle understanding of the factors that drive animal behavior proximately.

251 neuronal activity is a prime determinant of animal behavior, relationships between astrocytic excita

252 in the retina and brain, but their roles in animal behavior remain poorly understood.

253 nd the roles of those sarcomeric proteins in animal behaviors remain unclear.

254 ven after the representation stabilized, the animals' behavior remained different in the novel places

255 tory cortex (A1) participates in instructing animal behavior remains debated.

256 Automated detection of complex animal behaviors remains a challenging problem in neuros

257 ow astrocytes are recruited during different animal behaviors remains limited.

258 Comprehensive descriptions of animal behavior require precise three-dimensional (3D) m

259 arning have each become important domains of animal behavior research in recent years yet have remain

260 tial methodological issues in ecological and animal behavior research today.

261 Kaufman, with additional insight from recent animal behavior research, behavioral neuroscience, and c

262 ting specific synapses, which indicates that animal behavior results from the coordinated activity of

263 These studies combine animal behavior, sensory biology, phylogenetics, and art

264 need to be taken into account when studying animal behavior.SIGNIFICANCE STATEMENT Memory is a criti

265 partner, excretion, controls and constrains animal behavior, size, and energetics remains largely un

266 Animal behavior spans many timescales, from short, secon

267 Collective animal behavior studies have led the way in developing m

268 d tracking of individuals is revolutionizing animal behavior studies, but further progress hinges on

269 neural circuits.SIGNIFICANCE STATEMENT Many animal behaviors such as birdsong consist of variable se

270 receptors were involved in BPN's effects on animal behavior tests sensitive to antidepressant drugs.

271 The basic elements of animal behavior that are critical to survival include en

272 First, we discuss several types of animal behavior that commentators cite as evidence again

273 Foraging for food is a rich and ubiquitous animal behavior that involves complex cognitive decision

274 ion making is a vital component of human and animal behavior that involves selecting between alternat

275 Decision-making is a ubiquitous component of animal behavior that is often studied in the context of

276 essary step for quantitative descriptions of animal behavior that link environmental cues, internal n

277 ts often promise to illuminate sophisticated animal behavior, the analyses brought to bear on these d

278 lications for research on human and nonhuman animal behavior, the evolution of cooperation, and frequ

279 cues from the environment are used to direct animal behavior through a complex network of connections

280 ncing, advanced bioinformatics analyses, and animal behavior to determine how E2F3a and E2F3b contrib

281 ioral ecologists argue that evolution drives animal behavior to efficiently solve the problems animal

282 e importance of respecting the complexity of animal behavior to interpret neural function and validat

283 rchers in ecology, conservation biology, and animal behavior using logical argument and repeated Mont

284 Animal behavior usually has a hierarchical structure and

285 Animal behavior was classically considered to be determi

286 Instead, animals' behavior was explained by a normative account t

287 erstand how such microbial parasites control animal behavior, we examine the cell-level interactions

288 By fusing simulated and real animal behavior, we isolated predator effects while cont

289 Here, inspired by the natural structure of animal behaviors, we address this challenge by proposing

290 important neural regulators of many complex animal behaviors, we explored the function of the FMRFam

291 ein localization, synaptic transmission, and animal behaviors, we find that reduced function of UNC-1

292 egmentation inferred from neural data to the animals' behavior, we can explore and discover novel cor

293 tion of dopamine D1 or D2 antagonists on the animals' behavior were similar in that both reduced brea

294 corporating the high-pass controller matches animal behavior, whereas the model with the low-pass con

295 e to estimates from the literature for other animal behaviors, which suggests that problem-solving is

296 ther the generative mechanisms for human and animal behavior will require a philosophically indetermi

297 ty was assessed by colorectal distension and animal behavior with an automatic behavior recognition s

298 ed by the latest series of studies comparing animal behavior with electrophysiological recordings in

299 Diet selection is a fundamental aspect of animal behavior with numerous ecological and evolutionar

300 Coordination of animal behavior with reproductive status is often achiev