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1 vity in the right inferior frontal gyrus and supramarginal gyrus.
2 flow values, in a subnetwork centered at the supramarginal gyrus.
3 gyrus, whereas area 44 is connected with the supramarginal gyrus.
4 rus, has strong connections with the rostral supramarginal gyrus.
5 al areas of the cerebral cortex, as well the supramarginal gyrus.
6 hy, including the inferior frontal gyrus and supramarginal gyrus.
7 ts in the left middle frontal gyrus and left supramarginal gyrus.
8 well as the superior parietal lobule and the supramarginal gyrus.
9 nt part of the middle temporal gyrus and the supramarginal gyrus.
10 th increased GMV in the cingulate cortex and supramarginal gyrus.
11 otor area (SMA), precentral gyrus, and right supramarginal gyrus.
12 efrontal and temporal cortex, precuneus, and supramarginal gyrus.
13 in the posterior superior temporal gyrus and supramarginal gyrus.
14 nique to negative cues, psilocybin increased supramarginal gyrus activity; unique to positive cues, p
15 and independent neural network including the supramarginal gyrus also involved in emotional and visua
16 ithin the dorsolateral prefrontal cortex and supramarginal gyrus, also when other clinical and daily
17 ylvian fissure, which included the posterior supramarginal gyrus and adjacent anterior angular gyrus,
18 vely with calculation activation in the left supramarginal gyrus and bilateral anterior cingulate cor
19 , location could be decoded from angular and supramarginal gyrus and both superior and inferior front
20 aris IFG/PMv, primary motor cortex (M1), IPL/supramarginal gyrus and middle occipital gyrus (MOG) dur
21 insula associated with risk for SCZ, in left supramarginal gyrus and right frontal regions with risk
22 emporal areas, had higher degree in the left supramarginal gyrus and right gyrus rectus, and had high
23 aller right insula volume extending into the supramarginal gyrus and superior temporal gyrus (pFWE =
24 y between the dorsolateral prefrontal cortex/supramarginal gyrus and supramarginal gyrus/middle tempo
25 ecreased functional connectivity between the supramarginal gyrus and the visual brain network may neg
26 reduced functional connectivity between the supramarginal gyrus and the visual occipital and superio
27 ignificantly less metabolic activity and the supramarginal gyrus and vermis had significantly more me
28 that dysfunction of left Brodmann areas 40 (supramarginal gyrus) and 37 (posterior-inferior temporal
29 RI to identify a group of inferior parietal (supramarginal gyrus) and superior parietal (intraparieta
30 ; the right ventrolateral prefrontal cortex, supramarginal gyrus, and anterior thalamus; and bilatera
31 otor cortex, dorsolateral prefrontal cortex, supramarginal gyrus, and in ipsilateral posterior pariet
32 al prefrontal cortex, right anterior insula, supramarginal gyrus, and left inferior parietal lobule.
33 the right anterior insula/frontal operculum, supramarginal gyrus, and medial orbitofrontal cortex (al
35 regions included the caudate, lingual gyrus, supramarginal gyrus, and right and left superior and rig
36 stral middle frontal and frontal pole), left supramarginal gyrus, and right transverse temporal gyrus
37 ppocampus, fusiform/inferior temporal gyrus, supramarginal gyrus, and visual association cortex in wo
38 ed with differential engagement of the right supramarginal gyrus as well as hippocampal-cortical reor
39 e superior temporal gyrus extending into the supramarginal gyrus, as well as lesions within the basal
40 ng the central visual pathway and around the supramarginal gyrus, as well as reduced functional conne
41 for updating [bilateral MFG (BA 8) and left supramarginal gyrus (BA 39)], inhibition (left IFG BA 46
42 than controls in primary motor cortex (BA4), supramarginal gyrus (BA40), inferior frontal gyrus (BA44
43 ch has stronger connections to the posterior supramarginal gyrus, can be distinguished from both the
44 frontal gyrus, superior parietal lobule, and supramarginal gyrus, comparison subjects showed signific
45 ty in a phonologically related brain region (supramarginal gyrus) correlated with the verbalizer dime
46 e: left posterior superior temporal lobe and supramarginal gyrus; executive functions: bilateral fron
47 rtex, there was a dissociation such that the supramarginal gyrus exhibited greater activity to the ta
48 parietal lobule (IPL) (corresponding to the supramarginal gyrus) exhibited reduction in neural activ
49 gulate cortex, bilateral precuneus, and left supramarginal gyrus for fearful (relative to neutral) fa
50 The reconstructed timeline suggests that the supramarginal gyrus in IPL links decision regions in pre
51 ial role of the superior parietal lobule and supramarginal gyrus in mediating competition between vis
52 cuneus/calcarine fissure/precuneus, and left supramarginal gyrus/inferior parietal gyrus during angry
53 interaction effect on activation in the left supramarginal gyrus, irrespective of diagnostic group (Z
54 before the UP of lexical competition in left supramarginal gyrus, left superior temporal gyrus, left
55 in right anterior to middle cingulate, right supramarginal gyrus, left thalamus, and midbrain bilater
56 al prefrontal cortex/supramarginal gyrus and supramarginal gyrus/middle temporal gyrus was associated
57 late of the default mode network, insula and supramarginal gyrus of the executive control network and
58 mulation focused on either the left anterior supramarginal gyrus or opercular part of the left inferi
59 and to the white matter adjacent to the left supramarginal gyrus, over and above overt speech product
60 ompared with nonfood brain activation in the supramarginal gyrus (P < 0.005, corrected for multiple c
62 sample 1 were replicated in sample 2: right supramarginal gyrus (p(uncorrected) < 0.05, SBC = -0.32)
63 postcentral gyri, supplementary motor area, supramarginal gyrus, posterior temporal cortex, and infe
64 r = -0.19, P(uncorrected) = 0.049) and right supramarginal gyrus (r = -0.19, p(uncorrected) = 0.043)
65 regions including middle frontal gyrus, and supramarginal gyrus relative to young subjects and those
66 exhibited gray matter abnormalities in left supramarginal gyrus, right striatum, right inferior fron
67 ial magnetic stimulation (rTMS) of the right supramarginal gyrus (rSMG) in humans lengthened the perc
68 iated with increased activation in the right supramarginal gyrus (rSMG), in a location distinct from
69 with affective self-other distinction (right supramarginal gyrus [rSMG]), in participants watching vi
70 planted microelectrode arrays located in the supramarginal gyrus (SMG) and primary somatosensory cort
71 whether the functional contribution of left supramarginal gyrus (SMG) during action reprogramming de
74 signal differences at bilateral sites in the supramarginal gyrus (SMG) of the inferior parietal lobul
75 stently after lesions that include the right supramarginal gyrus (SMG), a part of the inferior pariet
76 M(sa)) for the superior frontal gyrus (SFG), supramarginal gyrus (SMG), and cingulate gyrus (CG) from
77 ion was administered on 50% of trials to the supramarginal gyrus (SMG), anterior intraparietal sulcus
78 or temporal/middle temporal gyrus (STG/MTG), supramarginal gyrus (SMG), posterior inferior frontal gy
79 frontal activation in neonates while by left supramarginal gyrus (SMG), superior temporal gyrus (STG)
80 peech, neural activity was recorded from the supramarginal gyrus (SMG), ventral premotor cortex (PMv)
82 that inferior parietal cortex (specifically supramarginal gyrus [SMG]) integrates saccade and visual
84 t categorically processing area was the left supramarginal gyrus: stimuli from different phonetic cat
85 ory cortex, insula, superior temporal gyrus, supramarginal gyrus, striatum, amygdala, cerebellum, and
88 ssification included the postcentral cortex, supramarginal gyrus, superior temporal cortex, and precu
89 36, z = 8; FWE-corrected P = .009), and the supramarginal gyrus (t168 = 5.03; peak MNI coordinates x
92 nal cortex thickness, hippocampal volume and supramarginal gyrus thickness demonstrated an area under
93 h inattention and impulsivity; additionally, supramarginal gyrus thickness mediated the association w
94 nother dataset, which previously yielded the supramarginal gyrus using a univariate adaptation-fMRI p
95 ral gyrus), regular words (planum temporale, supramarginal gyrus, ventral precentral and postcentral
98 l cortex, and the right caudate and anterior supramarginal gyrus were correlated with the TFI control
99 motor cortex) and sensory-motor integration (supramarginal gyrus) were unaffected by remifentanil.
101 emotor cortex, pre- and postcentral gyri and supramarginal gyrus with minimal extension into auditory
102 .01; activation of the right postcentral and supramarginal gyrus: Z max, 3.73; P < .001; deactivation