ライフサイエンスコーパス: spatial processing

1 ppocampal-anterior thalamic interactions for spatial processing.

2 ell turning, suggesting an important role in spatial processing.

3 rticularly for tasks requiring attention and spatial processing.

4 retrosplenial complex, a region involved in spatial processing.

5 retrosplenial complex, a region involved in spatial processing.

6 ciptal areas further suggested impairment in spatial processing.

7 trahippocampal communication is critical for spatial processing.

8 ctivation being postulated to interfere with spatial processing.

9 t are involved in tactile, multisensory, and spatial processing.

10 most powerfully observed for face memory and spatial processing.

11 pocampus, an area of the brain involved with spatial processing.

12 rmance, most consistently in face memory and spatial processing.

13 as that are typically associated with visual-spatial processing.

14 portance of the superior temporal sulcus for spatial processing.

15 Aged mPFC neurons showed normal spatial processing.

16 ion-dependent processes drive this change in spatial processing.

17 ) that may deliver vibrissal cues to PPC for spatial processing.

18 ty-independent circuits specialized for fine spatial processing.

19 al interactions are required for appropriate spatial processing.

20 ntrolateral prefrontal cortex is involved in spatial processing.

21 ecrease in a behavioral measure of selective spatial processing.

22 es in noise filtering, intensity coding, and spatial processing.

23 d prefrontal regions specialized in auditory spatial processing.

24 t-reversing gratings, often reveal nonlinear spatial processing.

25 ria with LOD scores >2.2 were identified for spatial processing (2p25 and 16q23), sensorimotor dexter

26 We investigated how auditory spatial processing adapts to stimulus statistics by pres

27 However, spatial processing also led to significant auditory cort

28 e corticostriatal-thalamic network mediating spatial processing and directed attention.

29 ical components of the circuitry involved in spatial processing and directed attention.

30 d extensively with brain regions involved in spatial processing and eye movement control.

31 deficits and no associations between visual-spatial processing and functional domains, pointing to a

32 memory component, but depends more on visuo-spatial processing and is most sensitive to dysfunction

33 campal CA fields directly and, thus, informs spatial processing and memory.

34 the medial temporal lobe (MTL) that supports spatial processing and navigation.

35 ion of neurogenesis in the face of increased spatial processing and physical activity demands.

36 This learning may be limited by immature spatial processing and probabilistic reasoning abilities

37 nd another that emphasizes the importance of spatial processing and scene construction.

38 Thus, in addition to their role in spatial processing and sensorimotor integration, posteri

39 structures might be especially important for spatial processing and spatial memory.

40 The first explores auditory spatial processing and the role of the auditory cortex i

41 ion/flexibility, verbal memory, face memory, spatial processing, and emotion processing and for speed

42 executive function, episodic memory, visual-spatial processing, and language.

43 d monkeys can lead to behavioral deficits in spatial processing, and many parietal neurons, such as i

44 ub region within a brain network involved in spatial processing, and necessary for episodic memory.

45 cutive function, learning and memory, visual-spatial processing, and psychomotor function.

46 object detection, coordinate and categorical spatial processing, and temporal ordering for visual obj

47 in most sensory and motor tasks, timing and spatial processing are intrinsic properties of neural fu

48 er, the results reveal strong differences in spatial processing between hippocampal area CA1 and VS,

49 We conclude that spatial processing bias following pulvinar damage can be

50 lucidating this process illuminates not only spatial processing but also, more generally, how the bra

51 ical and lesion studies implicate the OFC in spatial processing, but there is little direct evidence

52 ween the two states, such as most aspects of spatial processing, but there were significant differenc

53 Spatial processing by receptive fields is a core propert

54 nal organization, they also demonstrate that spatial processing co-localizes with visual processing a

55 These findings delineate auditory spatial processing deficits in typical and posterior Alz

56 tral stimuli and controlled for mnemonic and spatial processing demands, both important issues given

57 define ventrolateral object and dorsolateral spatial processing domains in the prefrontal cortex of n

58 Female CJL mice displayed impaired spatial processing during a spontaneous alternation task

59 lly coupled with hippocampal place cells for spatial processing during natural behavior.

60 erolateral temporal cortex involved in visuo-spatial processing during the RPM.

61 the establishment of modules with different spatial processing emphasis.

62 l visual features arises from reward-induced spatial processing enhancement of peripheral valuable ob

63 tative role for vision in restoring auditory spatial processing following potential cross-modal reorg

64 It is widely held that the spatial processing functions underlying rodent navigatio

65 upations involving frequent navigational and spatial processing, had the lowest proportions of deaths

66 unctioning of the neural circuits supporting spatial processing have yet to be assessed in children w

67 This offers a novel means for investigating spatial-processing impairments in hemispatial neglect.

68 A recent study of spatial processing in amusia makes a controversial claim

69 ocused on visual working memory and auditory spatial processing in dorsolateral prefrontal cortex (PF

70 l measurements and behavior demonstrates how spatial processing in face-selective regions may enable

71 However, it is unknown how spatial processing in high-level regions contributes to

72 These results not only show that spatial processing in high-level visual regions is dynam

73 a virtual space paradigm to assess auditory spatial processing in patient cohorts with clinically ty

74 iolation, suggesting a unique involvement of spatial processing in signed syntax.

75 varying degrees to understand the genesis of spatial processing in the amygdala.

76 endent on structures in this region, such as spatial processing in the case of the hippocampus.

77 ctivation being postulated to interfere with spatial processing in the hippocampal circuit.

78 functional homologues correlated with better spatial processing in the neglected hemispace during bot

79 Visual and somesthetic cues are used for spatial processing in the posterior parietal cortex (PPC

80 visual inputs to auditory cortex can enhance spatial processing in the presence of multisensory cues

81 the parietal lobe activation associated with spatial processing in the undisturbed driving task decre

82 Spatial processing is a core component of auditory scene

83 ive computation, but rather that hippocampal spatial processing is an active process likely regulated

84 iscrimination performance, for example, when spatial processing is required and the stimuli have a hi

85 features and task domains such as attention, spatial processing, language and math.

86 regions that participate in both object and spatial processing may be specialized for flexible exper

87 te that hippocampal-dependent impairments in spatial processing may occur prior to parietal cortex-de

88 cluded deficits in both dimensions of visual-spatial processing (mean [SD] Wechsler Visual-Spatial In

89 We test the hypothesis that spatial processing mechanisms in the early visual system

90 We propose that the spatial processing mode is complemented by a temporal on

91 early theories of PPA emphasized its role in spatial processing, more recent reports of its function

92 zation--e.g., right brain specialization for spatial processing--necessitating a convergence of infor

93 lationship between preparatory activation of spatial processing networks and efficient conflict resol

94 wed a dissociation between measures of visuo-spatial processing not observed in non-NVLD children.

95 mice, we find surprising asymmetries in the spatial processing of eye-specific visual input in binoc

96 We also identified asymmetries in the spatial processing of ON and OFF stimuli, which suggest

97 onments, we examined the effects on auditory spatial processing of rearing ferrets with localization

98 rimotor guidance of sound production and the spatial processing of sound.

99 impacts the brain circuits dedicated to the spatial processing of touch.

100 However, the spatial processing properties of individual SBCs and the

101 attention; verbal, face, and spatial memory; spatial processing; sensorimotor processing; and emotion

102 appear to be robustly involved in selective spatial processing.SIGNIFICANCE STATEMENT We examined ne

103 uous performance test (CPT-AC), and CVc with spatial processing (SPD-CVc).

104 stem are crucial for aspects of temporal and spatial processing, such as theta oscillations and grid

105 Participants also completed a visual-spatial processing task while undergoing magnetoencephal

106 al regions involved in visual, auditory, and spatial processing that supported stimulus-specific repr

107 Activity specific for spatial processing was isolated by contrasting discrimin

108 eto-occipital activity, possibly involved in spatial processing, was also revealed in children with C

109 Neuroanatomical correlates of auditory spatial processing were assessed using voxel-based morph

110 te to path integration and basic allocentric spatial processing, whereas the late maturation of the r

111 ortex thought to be concerned primarily with spatial processing, whereas the posterior pseudosylvian

112 t to compute dichotomous representations for spatial processing, with the medial EC (MEC) providing a