ライフサイエンスコーパス: motor region

1 mpared to resting-state patterns in the same motor region.

2 elated with MEP amplitudes in the upper limb motor region.

3 l prefrontal cortex, functions as a visceral motor region.

4 NMDA) receptors following stimulation of non-motor regions.

5 g task-relevant information in visual and/or motor regions.

6 oss much of the brain, including sensory and motor regions.

7 movement representations in spared cortical motor regions.

8 ional connectivity with subcortical and (pre)motor regions.

9 and dose-dependent thinning of the cortical motor regions.

10 similarity of paralimbic and primary sensory/motor regions.

11 higher energetic costs than those in sensory-motor regions.

12 ring would be associated with high forces in motor regions.

13 er-order brain regions and either sensory or motor regions.

14 piratory modulation, with highest density in motor regions.

15 iii) elicit stronger effects of TMS on these motor regions.

16 corticography was recorded over auditory and motor regions.

17 rocal interactions with temporal and frontal motor regions.

18 as actions are produced by modality-specific motor regions.

19 these deep-layer cells also target brainstem motor regions.

20 s, lateral frontal cortex, and somatosensory/motor regions.

21 densely connected with other frontal cortex motor regions.

22 ngulate gyrus and right sensorimotor and pre-motor regions.

23 2% identity to MYO3 across the motor and non-motor regions.

24 y inactivated, indicating plasticity in song motor regions.

25 g frontal and parietal areas [10, 11], other motor regions [12-15], and also the existence of multise

26 Consistent with prior data, the cortical motor regions activated during the motor task showed gre

27 s also densely connected with frontal cortex motor regions, albeit to a lesser extent than the M1 gra

28 activity pulses that appeared in the disused motor regions and CON control regions.

29 well established in humans for language and motor regions and correlate with handedness.

30 mal anticorrelation between dorsal attention/motor regions and default-mode/frontoparietal regions, p

31 31P-MRS was acquired from cerebral motor regions and from tibialis anterior during rest and

32 ciation cortices relative to primary sensory/motor regions and have implications for understanding po

33 ved stronger recruitment of primary auditory-motor regions and low visual engagement.

34 wed impaired connectivity between cerebellar motor regions and neocortical visuomotor and premotor re

35 between the left precentral gyrus and other motor regions, and between Broca's and Wernicke's areas.

36 already in early sensory, somatosensory, and motor regions, and only for political content.

37 actions between auditory, somatosensory, and motor regions, and the hemispheric lateralization patter

38 One metastate is associated with sensory and motor regions, and the other involves areas related to h

39 ge-scale circuit model suggests that sensory-motor regions are a driver of FC dynamics.

40 parietal, higher-order language regions, and motor regions are involved in beta.

41 Secondary motor regions are less efficient at generating motor out

42 cted by an associative account, responses in motor regions are observed for novel and/or abstract vis

43 rdless of age group, stronger coupling among motor regions, as well as between language/speech region

44 temporal, fronto-insular, and supplementary motor regions, as well as between the amygdala and dorsa

45 of upper-limb casting revealed that disused motor regions became more strongly connected to the cing

46 h and language processing, where sensory and motor regions better align with the model's speech embed

47 yses revealed higher sodium concentration in motor regions (bilateral precentral gyri, corticospinal

48 in striatal areas but also in extrastriatal "motor" regions, bilaterally.

49 nd closely in unimodal, primary sensory, and motor regions, but diverge in transmodal cortex, particu

50 mispheric inhibitory effects between primary motor regions can explain subjective post-stroke fatigue

51 nd more balanced between visual and auditory-motor regions compared with the spatial pathway.

52 nnectivity among a bilateral network of core motor regions comprising M1, lateral premotor cortex, an

53 and inter-hemispheric interactions among key motor regions constitute an important pathophysiological

54 tigated the hypothesis that areas beyond the motor regions could participate in RtG planning and exec

55 the medial frontal cortex, salience network, motor regions, default mode network, and cerebellum.

56 the cortex concentrated in visual and somato-motor regions, distinct from the pattern of intersubject

57 nduced changes in coupling within or between motor regions during motor preparation may affect cortic

58 3-33 Hz) broadband oscillatory activity) in motor regions during movement compared to rest, as well

59 d the activation and interaction of cortical motor regions during simple, internally paced and extern

60 and the increased activation in the cortical motor regions during the dopamine-replete state was posi

61 s task have revealed selective activation of motor regions during the perception of 'natural' versus

62 Truncation mutants lacking the motor region failed to localize to filopodial tips but s

63 The divergent non-motor regions flanking the ATPase domain are critical in

64 ntal, premotor, supplementary, and cingulate motor regions, following training of a challenging dynam

65 did not consistently distinguish sensory and motor regions from paralimbic and association regions: (

66 Each motor region has unique terminations in the ipsilateral

67 Responses within the stimulated motor region have previously been found to correlate wit

68 lved correlated activity throughout multiple motor regions; however, we found no evidence for plastic

69 ever, it is difficult to target the cervical motor region in a rodent using a non-penetrating stimulu

70 y regulates kinesin-1 via the amino-terminal motor region in the context of the incoming viral partic

71 overy in a number of primary and non-primary motor regions in all patients, but no session effects we

72 movement-related activation in ipsilesional motor regions in chronic subcortical stroke patients.

73 Crucially, however, distinct motor regions in the precentral gyrus sparked by articul

74 Overall, the forelimb motor region included: (1) a large caudal forelimb area

75 ves the SMA and cortical regions outside the motor regions, including prefrontal and parietal regions

76 The enzyme was found in motor regions, including the dorsal motor nucleus of the

77 try of connectivity was assessed in the hand motor region, incorporating tumor position, perfusion, g

78 whereas activity in insular, cingulate, and motor regions is best explained in terms of stimulus unc

79 we have found that cholinergic input to both motor regions is required for task acquisition.

80 that a network of auditory and superior pre/motor regions is universally activated in the process of

81 ynchronized brain activity among sensory and motor regions may also play a critical role.

82 These activations in motor regions may possibly reflect volitional effort to

83 These molecules share a conserved motor region of approximately 340 amino acids, which is

84 dyslexics relative to the controls in a pre-motor region of Broca's area (BA 6/44).

85 The general structural features of the motor region of myosin superfamily members are now well

86 ivity between frontal cortical areas and the motor region of the striatum as a putative substrate for

87 ucleus is a specialized autonomic-projecting motor region of the striatum, whereas the lateral and an

88 ic carrot DNA, DcKRP120-1, homologous to the motor region of tobacco TKRP125.

89 models N-terminal scaffolding and C-terminal motor regions of DnaB to produce a clear break in the he

90 blood oxygen level dependent signal of three motor regions of interest in each hemisphere.

91 ends of white matter volume loss in relevant motor regions of the brain as measured via MRI.

92 d with a unique gene expression signature in motor regions of the brain implicated in neurodegenerati

93 s linking sound perception and production in motor regions of the brain, so this ability is not speci

94 ty in the motor cortex and striatum, two key motor regions of the brain.

95 s the immature networks in children included motor regions of the brain.

96 nitive-behavioural dysfunction affecting non-motor regions of the brain.

97 em, decreasing response times and activating motor regions of the brain.

98 I, and VIII bilaterally corresponding to the motor regions of the cerebellum (z score = 3.96 and 3.42

99 rain correlates of stuttering are the speech-motor regions of the non-dominant (right) cerebral hemis

100 ally, it is thought that action selection in motor regions originates from a competitive process that

101 ed a buildup of choice-selective activity in motor regions over time reflecting the integrated sensor

102 , fast spindles (13.5-15 Hz) at task-related motor regions predicted overnight enhancement in procedu

103 ies on a distributed network of temporal and motor regions rather than any specific anatomical landma

104 t predominantly contralateral frontoparietal motor regions, recordings in patients revealed that move

105 gined transformations to the equation or the motor region reflecting manual programming.

106 in the proportion of activated voxels in any motor region (relative to the total number of activated

107 The recruitment of motor regions requires modulatory input to shape circuit

108 e cognitive control, less is known about how motor regions respond to rapid and unexpected changes in

109 model of increasing degrees of damage to the motor regions responsible for gait i.e. IUGR, IUGR + hyp

110 culate nucleus and primary visual cortex) to motor regions (secondary and primary motor cortex and gi

111 We demonstrate that, beyond motor regions, several areas, such as the visual and the

112 evels, including auditory, sensorimotor, and motor regions, suggesting the representation of sensorim

113 tions between basal ganglia circuits and the motor regions that directly control performance.

114 in several identical primary and nonprimary motor regions that is independent of time after stroke.

115 r expression in the cerebellum and striatum, motor regions that may contribute to the improved behavi

116 PMd and remote right-hemispheric and mesial motor regions that was only present during arbitrary vis

117 Among the brain's motor regions, the cortico-basal ganglia circuit is part

118 recorded from neurons in the red nucleus, a motor region thought to be important for initiating move

119 e, sport novices recruit lower-level sensory-motor regions, thought to support the instantiation of m

120 ral cingulate (M3) and caudal cingulate (M4) motor regions through the corona radiata (CR), internal

121 chimeric kinesin-1 that fuses the N-terminal motor region to the tail and a tail variant unable to in

122 luctuation of functional connectivity in all motor regions to a level closer to that of healthy parti

123 onal gradients extending from perceptual and motor regions to cortical areas representing more abstra

124 put, and show that the cells projecting from motor regions to insular cortex are engaged shortly befo

125 k together with right-hemispheric and mesial motor regions to sustain visuomotor mapping performed wi

126 tients with FND exhibited increased SFC from motor regions to the bilateral posterior insula, TPJ, mi

127 and raphespinal innervation to the cervical motor region was promoted by C'ase plus transplant.

128 ansient synchronization between auditory and motor regions was observed.

129 uctuation of functional connectivity between motor regions were associated with improvements in tremo

130 sions positive for p62 immunostaining in non-motor regions were strongly over-represented in the C9OR

131 d following stimulation, particularly in non-motor regions where less is known about TMS physiology.

132 ndings suggest that PPTg input to downstream motor regions, where it can be integrated with other rel

133 s observed mainly in the primary sensory and motor regions, whereas low GSCORR was seen in the associ

134 The caudal ZI primarily connected with motor regions, while the rostral ZI received a topograph

135 recurring activation patterns of interacting motor regions (whole-brain intrinsic motor network state

136 FC that included only hypothesized value and motor regions with models trained on whole-brain FC.

137 molecular basis for the function of the non-motor regions within the context of full-length MCAK is

138 We hypothesized that recruitment of motor regions would shift from primary to secondary moto