ライフサイエンスコーパス: great vessel

1 the antibodies in the blood pools (heart and great vessels).

2 are required for remodeling of the heart and great vessels.

3 truncus arteriosus and abnormalities of the great vessels.

4 s to direct blood flow through the heart and great vessels.

5 the formation of the mature aortic arch and great vessels.

6 eate casts of blood flow of the chambers and great vessels.

7 nexpected plasticity in the formation of the great vessels.

8 o avoid laparotomy and cross-clamping of the great vessels.

9 en to the innermost endothelial cells of the great vessels.

10 utermost, adventitial cell population in the great vessels.

11 dventitial cell population of the developing great vessels.

12 rolling chronic inflammatory diseases of the great vessels.

13 a function of blood volume in the heart and great vessels.

14 Six needles (5.2%) were placed into the great vessels.

15 he immune system, and chronic disease of the great vessels.

16 measurements of blood flow in the heart and great vessels.

17 icular septal defect, 4 transposition of the great vessels, 3 patient ductus arteriosus, 3 partial an

18 ildren and can be used to delineate abnormal great vessel anatomy.

19 ith a constellation of heart, outflow tract, great vessel and pharyngeal gland defects that phenocopi

20 ing thoracic aorta, such as proximity to the great vessels and arch tortuosity, have been and remain

21 nomalous coronary artery with respect to the great vessels and cardiac chambers.

22 lular matrix protein abundantly expressed in great vessels and cardiac valves during embryogenesis, a

23 Transposition of the great vessels and common ventricle had higher rates of n

24 r, with higher rates of transposition of the great vessels and common ventricle patients compared wit

25 Significant constriction of the great vessels and ductus arteriosus was observed with L-

26 ter-generated three-dimensional image of the great vessels and ductus arteriosus.

27 malformations of the cardiac outflow tract, great vessels and heart due, at least in part, to failur

28 e are extensive defects in remodeling of the great vessels and heart resulting in death at ~E14.5.

29 are essential for normal development of the great vessels and the heart, giving rise to a range of c

30 nary veins, scattered within the wall of the great vessels, and a strictly delimited cluster between

31 allot, Ebstein anomaly, transposition of the great vessels, and common ventricle) and (2) patients <2

32 In addition to information about the heart, great vessels, and coronary arteries, these examinations

33 We find that the great vessels are strikingly dilated and frequently deve

34 Great vessel areas correlated well with body surface are

35 ac magnetic resonance reference Z scores for great vessel areas in normal children and adolescents in

36 maging (ventricular volumes and function and great vessel blood flow) and hemodynamic assessment (inv

37 ng the function and anatomy of the heart and great vessels, but its emerging role as one of the domin

38 lood vessels, nor by defects in the heart or great vessels, but were due to abnormal development of t

39 uses a variety of pharyngeal arch artery and great vessel defects, as well as malformations in many o

40 The malalignment of the great vessels described in this animal model are similar

41 uency of vessel defects scored at the end of great vessel development.

42 enital heart disease, but normative data for great vessel dimensions in pediatric subjects are scarce

43 is in native (2C) or mechanical valves (1B), great vessel disease and injury (2C), penetrating chest

44 In the cardiac outflow tract and great vessels, ET(A)(-/-) cells are excluded from the wa

45 In all patients, ventricular volumes and great vessel flow were measured.

46 tricuspid atresia with transposition of the great vessels in 4, and other diagnoses in 3.

47 onship between the coronary arteries and the great vessels in subjects with normal cardiac morphology

48 The ductus differs primarily from the great vessels in that it is a muscular rather than an el

49 c neural crest in formation of the heart and great vessels in the mouse and, furthermore, shows that

50 to the blood pool, visible as the heart and great vessels in the trunk and limbs, plus diffuse signa

51 dibulum (OFT myocardial remnant) beneath the great vessels, indicating failure of OFT shortening.

52 fined as pneumothorax, hemothorax, aortic or great vessel injury, 2 or more rib fractures, ruptured d

53 metric embryonic aortic arches to the mature great vessels is a complex morphogenetic process, requir

54 ascular smooth muscle differentiation in the great vessels is disrupted.

55 malities eventually lead to various types of great vessel malformations highly similar to those seen

56 ithin the DGS phenotypic spectrum, including great vessel malformations, hypoplastic pulmonary and ao

57 E axis signaling in the vulnerable heart and great vessels may be essential in controlling and preven

58 ly with respect to assessment of cardiac and great vessel morphology and left ventricular function.

59 ammation (n = 4), blood pool activity in the great vessels (n = 2), bowel uptake (n = 1) and unknown

60 enzyme, ECE-1, in the pharyngeal arches and great vessels of the developing chick embryo.

61 congenitally corrected transposition of the great vessels often reach childbearing age.

62 nding to multimodal stressors applied to the great vessels or heart.

63 umental in diagnosing cardiac and associated great vessel pathology and in identifying structural abn

64 e studies assign the embryonic origin of the great vessel progenitors to the interface between the ph

65 eal arches, from which many craniofacial and great vessel structures arise.

66 s, as well as defects in cardiac outflow and great vessel structures, which are derived from cephalic

67 es are vital for the development of a mature great vessel system.

68 FT cardiomyocytes by PCD is required for the great vessels to make their proper connections with the

69 e instances, the infundibulum connected both great vessels to the right ventricle in a side-by-side a

70 re injuries in children, such as cardiac and great vessel trauma, may remain undiagnosed precisely be

71 ssures and samples from cardiac chambers and great vessels using antegrade, transseptal, and retrogra

72 s, eg, neural tube defects, transposition of great vessels, ventricular septal defect, atrial septal

73 Associated deformity of the trachea or great vessels was recorded as absent or present.

74 congenitally corrected transposition of the great vessels was studied in 22 women.

75 2 patients (50%), and d-transposition of the great vessels was the diagnosis for 4 patients (16%).

76 images, and through-plane flow images of the great vessels were acquired.

77 ded surface display images of the airway and great vessels were generated from volumetric CT data and

78 congenitally corrected transposition of the great vessels were identified.

79 artery and its course in relationship to the great vessels were unequivocally demonstrated.

80 nary patterns, both of which loop around the great vessels, were associated with significant mortalit

81 ressed in neural crest, developing heart and great vessels, whereas Ahdc1 is not.

82 %-58%) and proximity to the aortic valve and great vessels (with potential for dissection complicatio