ライフサイエンスコーパス: frontal pole

1 udate, left inferior frontal gyrus, and left frontal pole.

2 eft rostral middle frontal regions, and left frontal pole.

3 stinctively human component in ventrolateral frontal pole.

4 unterexamples to conclusions recruited right frontal pole.

5 BOLD activation in left cerebellum and right frontal pole.

6 3) in which SD was repeatedly evoked in the frontal pole.

7 human-specific patterns of expression in the frontal pole.

8 atter between the anterior cingulate and the frontal poles.

9 nd dorsal to the principal sulcus and in the frontal pole; 3) a caudolateral network (CLPFC) in and r

10 e to which the latter two regions influenced frontal pole activity correlated with participant-specif

11 nt was mediated by gray matter volume in the frontal pole and anterior cingulate gyrus.

12 connect with largely separate regions of the frontal pole and more medial premotor and dorsal prefron

13 ilateral reductions of cortical thickness in frontal pole and superior frontal gyrus, and similar eff

14 d decreased with the orbital frontal cortex, frontal pole and the dorsal ACC, suggesting a down-regul

15 ral gyrus, middle and superior frontal gyri, frontal pole, and cingulate gyrus in S-allele carriers c

16 t cortex was reciprocally connected with the frontal pole (area 10), rostral principal sulcus (area 4

17 s consolidate the left medial portion of the frontal pole as particularly altered in major depression

18 related with left dorsal anterior insula and frontal pole atrophy.

19 ostructurally informed subdivisions of human frontal pole between depressed patients and comparison s

20 rtex (Brodmann's area 8), the right inferior frontal pole (Brodmann's area 10), and the right lateral

21 ization of neurons in four cortical regions (frontal pole [Brodmann's area 10], primary motor [area 4

22 ribe their comparison of transcriptomes from frontal pole, caudate nucleus, and hippocampus of multip

23 ulo-opercular control network, including the frontal pole, cingulate cortex, and anterior insula.

24 The frontal pole cortex (FPC) expanded markedly during human

25 l activation than comparison subjects in the frontal pole, dorsolateral and ventrolateral prefrontal

26 The heterogeneous human frontal pole has been identified as a node in the dysfun

27 nalysis found a significantly smaller medial frontal pole in depressed patients, with a negative corr

28 microstructurally defined medial area of the frontal pole in depressed patients.

29 The growth of the frontal pole in humans has pushed area 25 and area 32pl,

30 scribe the intracerebral hemodynamics at the frontal pole in the circumscribed period between wakeful

31 occurred in the medial prefrontal cortex and frontal pole in the patients who responded positively to

32 We found that the frontal pole integrates effort and risk costs through fu

33 r with grey matter volume asymmetries in the frontal pole, lateral occipital pole or temporal pole.

34 pars opercularis, rostral middle frontal and frontal pole), left supramarginal gyrus, and right trans

35 their functional coupling patterns with the frontal pole, medial prefrontal, and dorsal prefrontal c

36 mplicating the bilateral anterior cingulate, frontal pole, medial temporal lobe, opercular cortex and

37 ral anterior cingulate cortex (rACC), medial frontal pole (mFP) and periaquiduct grey (PAG) are signi

38 uman region sometimes referred to as lateral frontal pole more closely resembled area 46, rather than

39 Frontal pole ODI mediated the negative relationship of a

40 A left-sided region of the frontal pole of the brain (BA 9/10) was selectively acti

41 Group 2 animals (n = 9), the (non-ischemic) frontal pole of the ipsilateral hemisphere was electrica

42 e closely resembled area 46, rather than the frontal pole, of the macaque.

43 y in the right superior, medial orbital, and frontal pole regions of the prefrontal cortex (p < .01).

44 cingulate cortex, parahippocampal gyri, and frontal pole, that exhibited activity uniquely associate

45 ntral prefrontal regions including the right frontal pole, the medial and lateral orbitofrontal gyrus

46 as well as increased thickness of the right frontal pole, the right lateral parietal lobules, and th

47 analysis showed that hippocampal volume and frontal pole thickness differed between patients who ach

48 (socio-affective) versus lateral (cognitive) frontal pole to major depression pathogenesis is current

49 ds, subregion specificity in the left medial frontal pole volume in depressed patients was demonstrat

50 In a second approach, frontal pole volume was compared by subdivision-naive mu

51 Frontal pole volume was first compared between depressed

52 -0.40, P=0.002) between serum VEGF and total frontal pole volume was found in patients with schizophr

53 ater activation in the left caudate and left frontal pole was associated with abstinence-induced subj

54 Indeed, the frontal pole was shown to structurally and functionally

55 tion of emotion (inferior frontal cortex and frontal pole) was negatively correlated with both the nu