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1 rs (model-free adaptation processes, such as associative learning).
2 s, such as odorant recognition and olfactory associative learning.
3 el cortex, as well as diminished spatial and associative learning.
4 ne-induced synaptic plasticity, and drug-cue associative learning.
5 e computationally more complex than "simple" associative learning.
6 m deficits in complex cognitive function and associative learning.
7 orphism on motor facilitation and visuomotor associative learning.
8 he acquisition of new expected values during associative learning.
9 nucleus accumbens shell that are related to associative learning.
10 the acquisition of new expected value during associative learning.
11 y cortex (GC) of alert rats before and after associative learning.
12 ffect not predicted by theoretical models of associative learning.
13 rebellum during acquisition and retention of associative learning.
14 es behavior through both associative and non-associative learning.
15 a model for psychiatric treatments based on associative learning.
16 (BLA) plays a central role in such forms of associative learning.
17 mechanisms for coincidence detection during associative learning.
18 tal cortex (VMF), a brain region critical to associative learning.
19 uli, replicating the logical requirement for associative learning.
20 esian and reinforcement learning theories of associative learning.
21 n postnatal development compared with simple associative learning.
22 inergic input neurons are required for taste associative learning.
23 orrelates of the described PAC1-R effects on associative learning.
24 encoding of task-relevant information during associative learning.
25 layed by top-down connections rather than by associative learning.
26 ioral actions and predictive sensory cues by associative learning.
27 te of biological circuit motifs that support associative learning.
28 ects of drugs of abuse as well as supporting associative learning.
29 est that motor-visual neurons originate from associative learning.
30 eval, similarity-based partial matching, and associative learning.
31 nd negative states and events, beyond simple associative learning.
32 d in the control of adaptive behavior, e.g., associative learning.
33 itry may underlie age-related differences in associative learning.
34 ppropriately registered and retrieved during associative learning.
35 , brain regions critical for emotion-related associative learning.
36 rk of a mathematical neural network model of associative learning.
37 circuit basis of striatal motor control and associative learning.
38 deficits in habituation, working memory and associative learning.
39 ye-Hall model (PKH)--an influential model of associative learning.
40 d in motor control, sensory integration, and associative learning.
41 these changes have important consequences in associative learning.
42 o enhance efficient sensory processing after associative learning.
43 ptor signaling is thought to be required for associative learning.
44 mutants exhibit strongly impaired olfactory associative learning.
45 utual reward delivery in male rats can drive associative learning.
46 mine signaling as a key neural mechanism for associative learning.
47 ing in Drosophila, is critical for olfactory associative learning.
48 yed by Markel was unsuitable for testing for associative learning.
49 cortical networks are simply a byproduct of associative learning.
50 are often dissociated from more "low-level" associative learning.
51 rties of local cortical networks result from associative learning.
52 lum plays a crucial role in sensorimotor and associative learning.
53 apses, priming or inhibiting the circuit for associative learning.
54 can influence striatal circuits involved in associative learning.
55 ronmental variation, which we suggest favors associative learning.
56 the mushroom body (MB) is the major site of associative learning.
57 aversive events and have been implicated in associative learning.
58 understanding how dopamine RPEs could drive associative learning.
59 s, but they usually have little to say about associative learning.
60 visual and episodic memory and visuospatial associative learning (-0.140 standard deviations per ris
69 oppositional control over reward-seeking and associative learning and are critically involved in rein
71 on, VTA mTOR signaling regulates cocaine-cue associative learning and cocaine-induced synaptic plasti
72 vity in Adk(Deltabrain) mice restored normal associative learning and contextual memory and attenuate
73 anner, serving as a coincidence detector for associative learning and likely representing a downstrea
74 n essential memory trace for a basic form of associative learning and memory - classical conditioning
75 ditioning study demonstrated that contextual associative learning and memory in inducible transgenic
76 d eIF4B phosphorylation, whereas spatial and associative learning and memory performances were improv
87 SC1 mice showed intact performance in simple associative learning and normal responses in consumption
89 hat mirror neurons originate in sensorimotor associative learning and that their function is determin
90 esity may be linked to impaired reward-based associative learning and that this impairment may be spe
92 hat mirror neurons originate in sensorimotor associative learning and therefore a new approach is nee
94 nter-temporal choice and cognitive control), associative learning, and affective and social aspects.
96 that executive functions very much build on associative learning, and argue that executive functions
97 oscillations play a key role in perception, associative learning, and conscious awareness and have b
98 ditional feeding practices, familiarization, associative learning, and observational learning affect
99 h perspective captures a different aspect of associative learning, and their synthesis offers insight
100 ational-decision approach is superior to the associative-learning approach of Cook et al. at explaini
102 ed behaviors in animals, including olfactory associative learning, arousal, and temperature-preferenc
104 ression of GluA1 subunits in CeA accelerated associative learning, as shown by reduced minimum time o
105 ppm of NO and NO(2), respectively) affected associative learning behaviour of honey bees (Apis melli
106 Our results reveal a marked difference in associative learning between normal-weight and obese wom
108 ere not only manifests important features of associative learning but also provides general insights
109 quence of events characterizing this type of associative learning but not during the acquisition proc
110 to improve basic research in domains such as associative learning, but also to play an important role
111 ve been observed in limbic brain areas after associative learning, but little is known about the exci
114 n of a memory trace occurs through classical associative learning, but which memory trace is eligible
115 of learning: nonassociative habituation and associative learning by pairing with a starvation uncond
116 Phasic dopamine signaling participates in associative learning by reinforcing associations between
117 demonstrate that the regulation of olfactory associative learning by serotonin is mediated by its dow
118 sing evidence that individual experience and associative learning can affect processes such as ovipos
119 strate that the circuitry mediating "simple" associative learning can also replicate the various non-
121 ly, we show that how memory retention during associative learning can be prolonged in networks of neu
125 dopamine release, behavioral hyperactivity, associative learning deficits, and a paradoxical inversi
126 in state and activity.SIGNIFICANCE STATEMENT Associative learning depends on brain state and is impai
127 ultiple actions of STDP, including a role in associative learning, despite potential temporal dissoci
129 ns, and that the mechanisms underlying trace associative learning differ when items in the memory are
130 nstration of modulation of mirror neurons by associative learning does not imply absence of genetic a
132 i.e., sensory acuity) relies on differential associative learning, during which animals are forced to
137 contingency- and context-sensitive nature of associative learning explains the full range of mirror n
138 strate that changes in sensory cortex during associative learning extend to the coordination of neuro
139 urthermore, these results suggest that trace associative learning facilitates neocortical synaptic mo
140 bservers were motivated and paid to do, with associative learning facilitating orienting toward rewar
141 f opioid-induced context-reward association (associative learning) for the acquisition of reward-rela
143 orm complementary roles in supporting normal associative learning, functions that are impaired after
148 STATEMENT The specific content of pavlovian associative learning has been well studied in appetitive
150 n between similar odors through differential associative learning has not been analyzed in detail.
151 ications following forebrain-dependent trace associative learning has not been closely examined.
152 r, placebo hypoalgesia, although mediated by associative learning, has been shown to be resistant to
157 Thorase in DAT(+) neurons expressed greater associative learning in a fear conditioning paradigm.
158 onstrate that neuroplastins are required for associative learning in conditioning paradigms, e.g., tw
163 single-unit and population level), shows how associative learning in mice tunes cortical processing,
164 the intricate relation between genetics and associative learning in order to further understand the
166 lated transcription coactivator 1 (CRTC1) by associative learning in physiological and neurodegenerat
167 n 2016 Gagliano et al. reported evidence for associative learning in plants (Gagliano et al., 2016).
169 esults suggest that mutual rewards can drive associative learning in rats and is dependent on vicario
170 n of social behavior, stress regulation, and associative learning in species ranging from nematodes t
172 ns are forged by domain-general processes of associative learning in the course of individual develop
173 r how these biological signals might support associative learning in the mammalian brain in these and
174 to separate activity patterns and facilitate associative learning in the presence of trial-to-trial v
176 edictive coding" models posit a key role for associative learning in visual cognition, viewing percep
178 neurons that were strongly activated during associative learning, in this case, context-independent
179 naptic mechanisms involved in other forms of associative learning, including extinction, that update
182 ussed: Genetic predispositions interact with associative learning, infants show predispositions to im
188 This newly extended technique that induces associative learning is called "A-DecNef," and it may be
189 cumstances of use, and although this type of associative learning is dependent upon changes in gene e
193 tral tenet of Rescorla and Wagner's model of associative learning is that the reinforcement value of
198 rgue, is a positive, generative thesis about associative learning mechanisms and how they might give
199 many cognitive functions such as attention, associative learning, memory, and sensory selection.
200 rategy is computationally distinguished from associative learning methods that rely on direct observa
201 isition of S-C and S-R associations using an associative learning model and then used trial-by-trial
202 sults reveal that predictions from classical associative learning models do not always hold for stres
204 ession of CeA AMPA receptors facilitates the associative learning of context-drug reward, an importan
205 We address this question in the context of associative learning of faces using a sensory preconditi
207 attributed to pervasive nicotine-reinforced associative learning of incentive cues that is highly re
208 ve enough sensorimotor experience to support associative learning of mirror neurons ("wealth of the s
209 dback termed "DecNef" [9], we tested whether associative learning of orientation and color can be cre
210 omega-3 deficiency on olfactory and tactile associative learning of the economically highly valued h
213 However, there is no clear evidence that associative learning of visual features occurs in early
215 tors seem to have little influence on simple associative learning or on stimulus-driven responding.
216 s from the retrosplenial cortex (RSC) during associative learning over days using chronic two-photon
223 eling with fMRI, we show that during tactile associative learning, prior expectations modulate connec
227 findings argue that selective attention and associative learning processes mediated by anatomically
229 is that schizophrenia risk CNVs impact basic associative learning processes, abnormalities of which h
230 al. argue that mirror neurons originate from associative learning processes, without evolutionary inf
232 phaly and deficits in motor coordination and associative learning, recapitulating the human phenotype
233 resent complex stimuli, principle neurons of associative learning regions receive combinatorial senso
234 Melrose, and Stern (2003) found higher-order associative, learning-related activation in the striatum
235 lowest quartile) midlife episodic memory and associative learning (relative risk (RR) = 1.38, 95% con
238 of the four Dlg paralogs showed that simple associative learning required Dlg4, whereas Dlg2 and Dlg
243 Mechanisms of acquisition include cue-target associative learning, reward learning, and sensitivity t
244 ing were nonsignificant (episodic memory and associative learning: RR = 1.19, 95% CI: 0.92, 1.54; sho
248 e, we demonstrate impairment in reward-based associative learning specific to food in obese women.
249 ng excitability changes in the cerebellum in associative learning, such as in trace or delay eye-blin
251 at dopamine transients support sensory-based associative learning, suggest that the dopamine system s
252 his process, we introduced ambiguity into an associative learning task by presenting aversive outcome
254 erarchical Bayesian modeling with fMRI on an associative learning task in 28 male human participants
255 Trace eyeblink conditioning (EBC) is an associative learning task in which a stimulus-free trace
256 electrodes while subjects participated in an associative learning task requiring them to learn an ass
257 mbus terrestris) in an ecologically relevant associative learning task under controlled laboratory co
263 We studied the role of MBONs in several associative learning tasks and in sleep regulation, reve
264 object recognition, spatial orientation, and associative learning tasks), we decided to study in beha
267 have broad implications for how to override associative learning that has become maladaptive and off
268 d indicate that V1 itself is a substrate for associative learning that may inform the timing of visua
269 multisite recording at successive stages of associative learning, that the coherence of firing patte
270 the combination between non-associative and associative learning, the modelling approach allows us t
271 ere that if mirror neurons develop purely by associative learning, then they cannot by themselves exp
272 tive learning may be understood according to associative learning theories, in addition to sensorimot
273 de, extinction has moved beyond the realm of associative learning theory and behavioral experimentati
277 brain's motor systems, or rather depends on associative learning, through repeated cooccurrence of v
278 or neurons make predictions that differ from associative learning: Through Hebbian Learning, mirror n
279 etic variants might interact with visuomotor associative learning to configure the system to respond
280 Here we explore the potential for repeated associative learning to shape and engender synesthetic e
281 effect of the unconditioned stimulus during associative learning to the axons of Drosophila mushroom
283 al investigation and abnormal discrimination/associative learning, unlike the de novo mutations in un
286 izophrenia CNVs impact on specific phases of associative learning we combined human genetics with exp
288 Because ASIC1A has been suggested to promote associative learning, we hypothesized that disrupting AS
289 stinguish from the classical Hebbian type of associative learning where presynaptic glutamate release
291 (STDP) serves as a key cellular correlate of associative learning, which is facilitated by elevated a
292 enhanced fear generalization or a deficit in associative learning, which may in turn represent a cent
293 sociative knowledge by studying visual-motor associative learning with functional magnetic resonance
294 cortex, these sensory inputs are combined by associative learning with olfactory and visual inputs fo
296 mushroom body function as parallel units of associative learning, with different learning rates, mem
297 demonstrate that the loss of HDAC2 improves associative learning, with no effect in nonassociative l
298 phases differ in aversive but not appetitive associative learning, with solitarious locusts showing a
299 dala bdnf expression and TrkB activation for associative learning within aversive contexts has been e
300 tributions to the theoretic understanding of associative learning, yet they still struggle when the t