1 s of reward-motivated memory formation using
event-related FMRI.
2 f target detection dysfunction in ADHD using
event-related fMRI.
3 sentations in early visual areas using rapid
event-related fMRI.
4 We used an
event-related fMRI adaptation paradigm to test whether t
5 e neural correlates of crowding by combining
event-related fMRI adaptation with a change-detection pa
6 In this study, we combined
event-related fMRI and a location-based negative priming
7 ion and recollection-based source retrieval,
event-related fMRI and EEG time courses revealed a clear
8 We use
event-related fMRI and effective connectivity analysis t
9 Recent
event-related fMRI and PET studies are adding crucial da
10 We measured brain activity using
event-related fMRI as participants recalled answers to 1
11 Continuous Performance Task while undergoing
event-related fMRI at 1.5 T.
12 Second, we measured
event-related fMRI BOLD responses in human primary visua
13 en performed a cognitive control task during
event-related fMRI data acquisition.
14 Event-related fMRI data were collected while participant
15 The temporal specificity of the
event-related fMRI design also minimized possible contam
16 ith distracting stimuli using a hybrid block/
event-related fMRI design and a task that varied the pro
17 Here, we used an
event-related fMRI design to distinguish human brain are
18 Using a hybrid block/
event-related fMRI design, we characterized proactive an
19 In a rapid
event-related fMRI design, we measured cortical activity
20 worker, as well as stranger faces in a rapid
event-related FMRI design.
21 ecordings of saccadic eye movements and fast
event-related fMRI during a continuous visual detection
22 We investigated this issue using
event-related fMRI during encoding of emotional and neut
23 que as in humans, we performed a mixed block/
event-related fMRI experiment in macaques.
24 Using a slow
event-related fMRI experiment, we investigated whether t
25 implications for the interpretation of rapid
event-related fMRI experiments, as well as for recently
26 ging events were essentially the same in two
event-related fMRI experiments, which compared passive a
27 maging (fMRI)--in particular single-trial or
event-related fMRI--
has now considerably advanced the po
28 We tested this hypothesis using
event-related fMRI in male and female human subjects by
29 we also address the broad impact that rapid
event-related fMRI is likely to have on functional neuro
30 Recently developed
event-related fMRI methods were used to analyze the data
31 ctivity during attention shifts using rapid,
event-related fMRI of human observers as they covertly s
32 Here, using
event-related fMRI on human participants, we contrasted
33 s in monkeys (Macaca mulatta), we adopted an
event-related fMRI paradigm that closely resembled a hum
34 The
event-related fMRI paradigm was composed of one warning
35 An
event-related fMRI paradigm was used to investigate brai
36 Using a rapid
event-related fMRI paradigm, we measured neural similari
37 sant taste were presented to subjects during
event-related fMRI scanning.
38 tes of non-verbal visual working memory with
event-related fMRI ('
Shape task').
39 examination of classification learning using
event-related FMRI showed rapid modulation of activity i
40 pplied a recently developed method to assess
event-related fMRI signal changes during free recall.
41 Event-related fMRI signals increased concomitantly in th
42 Our current
event-related fMRI study investigated response selection
43 The present
event-related fMRI study provides evidence for an altern
44 We present a human
event-related fMRI study with a two-factorial stimulus s
45 In this
event-related fMRI study, an implicit task was used in w
46 In the present
event-related fMRI study, skin conductance and continuou
47 In this
event-related fMRI study, we employed a low effort, high
48 We report a hybrid (block and
event-related) fMRI study in 17 healthy adults, which pe
49 In an
event-related fMRI task dissociating component numerical
50 pproach to assess BOLD-signal variability in
event-related fMRI task paradigms.
51 Experiment 2 used an
event-related fMRI technique to separate signals during
52 The present study utilized
event-related fMRI to address the role of the human peri
53 We used
event-related fMRI to assess whether brain responses to
54 We employed
event-related fMRI to constrain cognitive accounts of me
55 We used
event-related fMRI to determine the underlying neural me
56 In this experiment, we used
event-related fMRI to examine practice-related activatio
57 Here we used
event-related fMRI to examine the relationship between a
58 understand its neural underpinnings, we used
event-related fMRI to examine the time course of activat
59 We used rapid
event-related fMRI to measure hemodynamic responses to i
60 ron, McClure et al. and O'Doherty et al. use
event-related fMRI to provide some of the strongest evid
61 Minimally deprived smokers underwent fast
event-related fMRI twice: once with a nicotine patch (21
62 Event-related fMRI was employed to characterize differen
63 Rapid,
event-related fMRI was used to address this question.
64 Event-related fMRI was used to compare brain activation
65 Here, fast
event-related fMRI was used to identify the brain networ
66 Using
event-related fMRI,
we addressed this question by compar
67 Using
event-related fMRI,
we assessed the neural correlates of
68 Using
event-related fMRI,
we confirmed that tools grabbed spat
69 Using
event-related fMRI,
we examined whether anticipatory neu
70 Using
event-related fMRI,
we investigated how people weigh the
71 n was confirmed by a conjunction analysis of
event-related fMRI,
which showed significantly elevated
72 Using
event-related fMRI while concurrently recording skin con
73 signal profile, subjects were scanned using
event-related fMRI while undergoing appetitive condition
74 Using
event-related fMRI,
Wittmann and colleagues report in th