ライフサイエンスコーパス: emotional valence

1 d a behaviourally interpretable dimension of emotional valence.

2 s an additional evaluation of the underlying emotional valence.

3 applying a judgment bias paradigm to assess emotional valence.

4 stimuli or stimuli with positive or negative emotional valence.

5 hat self-reference is highly correlated with emotional valence.

6 ed an interaction between self-reference and emotional valence.

7 human smiles varied in relation to perceived emotional valence.

8 ities are inversely related as a function of emotional valence.

9 ved flavor intensity, taste persistence, and emotional valence.

10 refrontal cortex, they were not modulated by emotional valence.

11 hcare had no effect on comments' category or emotional valence.

12 nse to 15 randomized pictures with different emotional valences: 5 unpleasant, 5 pleasant, and 5 neut

13 Our findings suggest that emotional valence affects micro-level guided variation,

14 cannot be explained by positive or negative emotional valence alone.

15 ne could be critical for regulating negative emotional valence and anxiety in decision-making.

16 l assessment (QBA) were associated with both emotional valence and arousal and were considered the be

17 We observed that 17% of neurons responded to emotional valence and arousal of visual stimuli accordin

18 's disease (PD) and the affective ratings of emotional valence and arousal performed subsequently.

19 lected and their relationship to anticipated emotional valence and arousal was analysed using linear

20 eparate regions, possibly those sensitive to emotional valence and arousal.

21 n of parameters including indicators of both emotional valence and arousal.

22 rios expected to elicit responses varying in emotional valence and arousal.

23 in their opinions from other psychologist in emotional valence and four categories.

24 adient similar to the right hippocampus, but emotional valence and intensity were not directly associ

25 The neural circuits underlying emotional valence and motivated behaviors are several sy

26 significantly enhanced our understanding of emotional valence and motivated behaviors.

27 he medial prefrontal cortex is implicated in emotional valence and prosocial attitudes/behaviors.

28 tructures whose function may be to establish emotional valence and response priorities.

29 DBS due to its key role in regulating fear, emotional valence, and prosocial behaviour.

30 d item memory are differentially affected by emotional valence, and the age-related decline in associ

31 ons from dynamic faces, using a dimension of emotional valence as a test case.

32 Vocalisations are a potential indicator of emotional valence as they can reflect the internal state

33 ing to music, fluctuations between different emotional valences bias temporal encoding process toward

34 ulated in real-time by volitional control of emotional valence, but not arousal.

35 ective connectivity analysis showed that the emotional valence-dependent attention field was closely

36 Failure to activate limbic regions during emotional valence discrimination may explain emotion pro

37 ting patients and comparison subjects on the emotional valence discrimination task revealed voxels in

38 r in the amygdala and hippocampus during the emotional valence discrimination task than during the ag

39 vities are inversely related with respect to emotional valence during the WM task.

40 activity during WM; DLPFC was influenced by emotional valence, enhanced by pleasant and reduced by u

41 derlying conditions of negative and positive emotional valence, focusing particularly on mechanisms t

42 (MPFC), a classifier trained to discriminate emotional valence for one stimulus (e.g., animated situa

43 stract attribute measures such as beauty and emotional valence for these pieces.

44 atically controlled music, which can isolate emotional valence from the arousal dimension, to elucida

45 sms of differentiating positive and negative emotional valence have remained unknown.

46 the MET by examining differential effects of emotional valence in a large sample of autistic children

47 itory cortex that portends the assignment of emotional valence in amygdala that in turn influences th

48 es, providing evidence for the importance of emotional valence in evoking mental imagery.

49 ssion of positive versus negative sentiment (emotional valence) in first-person bereavement narrative

50 n enhanced responses to faces with different emotional valence, in both the amygdala and the visual c

51 current review, we focus specifically on how emotional valence influences retrieval processes, examin

52 ividuals, there is no clear consensus on how emotional valence influences this multidimensional proce

53 How does emotional valence information, computed in the amygdala,

54 ny species and thus, an understanding of how emotional valence is expressed is needed.

55 Here, we manipulated the attention field by emotional valence, negative faces versus positive faces,

56 Here, we show that the emotional valence of a word presented in English constra

57 Emotional valence of action outcomes was manipulated by

58 modulation of SoA is based on predicting the emotional valence of action outcomes.

59 al information specifically, rather then the emotional valence of an environment.

60 The emotional valence of animals is challenging to assess, d

61 Brain mechanisms that reflect emotional valence of baby signals among parents vary acc

62 edial prefrontal cortex (mPFC) regulates the emotional valence of both rewarding and aversive experie

63 Emotional valence of comments shows a generally balanced

64 activation is affected differentially by the emotional valence of external stimuli.

65 ally, the relation between an action and the emotional valence of its outcome was predictable in some

66 tedness of PES symptoms; and (3) explore the emotional valence of PES and the relationship to anxiety

67 solo music improvisation to examine how the emotional valence of sound and gesture are integrated wh

68 ected nodes of the gustatory system-code the emotional valence of taste stimuli (i.e., palatability),

69 istinguished facial change determined by the emotional valence of the message, and this also generali

70 r, and we used a bias paradigm to assess the emotional valence of the observer to determine whether e

71 Subjective ratings of the emotional valence of the picture sets were recorded.

72 fication of search targets regardless of the emotional valence of the stimuli.

73 quired unmedicated patients to recognize the emotional valence of visual images and to determine whet

74 is selectivity appeared to be independent of emotional valence or arousal and may reflect the importa

75 decreasing right amygdala reactivity (across emotional valence) (p = 0.033).

76 decreasing right amygdala reactivity (across emotional valence) (p = 0.033).

77 cators of arousal exist, clear indicators of emotional valence, particularly positive valence, are st

78 mpared to other pictures regardless of their emotional valence (pleasant, neutral, and unpleasant) or

79 mages grouped into categories that varied in emotional valence (pleasantness) and arousal.

80 We have recently investigated emotional valence (pleasantness) perception across the p

81 s alternated between tasks of discriminating emotional valence (positive versus negative) and age (ov

82 (mood disorder patients/healthy volunteers), emotional valence (positive/negative emotions) and treat

83 Maladaptive circuit changes in emotional valence processing can underlie the pathophysi

84 While subjects evaluated the picture set for emotional valence, regional cerebral blood flow was meas

85 demonstrate a three-way interaction between emotional valence, repetition, and task relevance and su

86 entation of emotional stimuli, assignment of emotional valence/salience to stimuli, stimulus-reinforc

87 ltivoxel pattern analyses indicated that FPl emotional valence signals likely originated from interco

88 Here we assumed that perception of facial emotional valence (the emotion's pleasantness) changes w

89 In this study, we attempted to assess emotional valence through memory in 1- and 3-week-old pi

90 ar and anxiety and is important in assigning emotional valence to cognitive processes.

91 plicated in arousal and in the assignment of emotional valences to stimuli and memories.

92 eparate the processing of self-reference and emotional valence using ERPs.

93 dissociation of territories that respond to emotional valence versus salience or arousal value.

94 f content annotations that included actions, emotional valence, visual cues and auditory cues.

95 Negatively scored emotional valence was associated with elevated log PHQ-4

96 Emotional valence was quantified using the VADER algorit

97 The activity of some neurons was related to emotional valence, whereas different neurons responded t

98 r temporal lobe activation is independent of emotional valence, whereas medial prefrontal regions sho

99 Empathy, the capacity for shared emotional valence with others, can allow for cooperativi

100 e experiences can be differentiated from the emotional valence with which they are inextricably assoc