ライフサイエンスコーパス: pericardium

1 to provide excellent anatomic detail of the pericardium.

2 ificantly longer than non-crosslinked bovine pericardium.

3 nces from neighboring cells, such as the epi/pericardium.

4 copically, no patient had an entirely normal pericardium.

5 r, skeletal muscle, myocardium, and visceral pericardium.

6 rug as result of a reservoir function of the pericardium.

7 l by attaching it to the edges of the opened pericardium.

8 in non-skeletal tissues including liver and pericardium.

9 inputs from thoracic structures, such as the pericardium.

10 ardiography cannot reliably detect thickened pericardium.

11 86% specific for the detection of thickened pericardium.

12 be used to distinguish diseased from normal pericardium.

13 a hiatus hernia, which had fistulated to the pericardium.

14 %; P =.004), bone marrow, adrenal gland, and pericardium (24.7% v 15.9%; P =.004).

15 ers of degranulating mast cells (MCs) in the pericardium (26.6 to 45.9%, P < 0.01), increased histami

16 e the myocardium, valves, coronary arteries, pericardium, also to assess cardiac structure and functi

17 his review aims to elucidate the role of the pericardium and its interaction with the remainder of th

18 ved from mesothelial cells lining the lungs, pericardium and peritoneum, and are often associated wit

19 rosslinked materials with crosslinked bovine pericardium and porcine dermis materials exhibiting a hi

20 dogs expressed IL-8 mRNA (in the synovia and pericardium), and three dogs had TNF-alpha mRNA in tribu

21 ich all the pleura is removed with the lung, pericardium, and diaphragm.

22 dermis, large arterial vessels, epicardium, pericardium, and heart valves at various stages of roden

23 for IL-8 mRNA in multiple tissues (synovia, pericardium, and peritoneum), and 10 dogs expressed TNF-

24 eratrial or interventricular septal defects, pericardium, and site and size of the great veins (IVC a

25 organs or tissues, such as arteries, nerves, pericardium, and the walls of the organs of the gastroin

26 ed to crosslink porcine aortic cusps, bovine pericardium, and type I collagen.

27 evaluation of the ejection fraction, aorta, pericardium, and valves all without the inherent risks o

28 Despite bovine pericardium (BP) being the primary biomaterial used in h

29 have focused on generation of unfixed bovine pericardium (BP) extracellular matrix (ECM) for clinical

30 the large vessels and the heart, within the pericardium, can result in cardiac arrhythmia suppressio

31 ending aortic bypass graft via the posterior pericardium (CoA bypass) allows simultaneous intracardia

32 ibution of FALCs was heterogeneous, with the pericardium containing large numbers of these clusters.

33 more severe around the base of the heart and pericardium, corresponding to sites of marked infiltrati

34 uman, and porcine origin; and derivatives of pericardium, dermis, and small intestine submucosa.

35 Sclera, pericardium, dura mater and cornea are available as a pa

36 in or around the systemic venous return and pericardium during development.

37 nd migratory properties underlie the ectopic pericardium formation.

38 metanephric kidneys, gonads, and defects in pericardium formation.

39 cross-linked porcine aortic valves or bovine pericardium frequently causes the clinical failure of th

40 lthough constriction with a normal-thickness pericardium has been demonstrated clinically by noninvas

41 annulus or reconstruction of the valve using pericardium in disease that primarily affects the valve.

42 1) with the pericardium intact, 2) with the pericardium intact and inotropic support, and 3) with th

43 artery (RCA) under 3 conditions: 1) with the pericardium intact, 2) with the pericardium intact and i

44 However, the pericardium is affected by virtually every category of d

45 extra-anatomic CoA bypass via the posterior pericardium is an excellent single-stage approach for pa

46 The pericardium is clearly an exception.

47 on with acute RV dilatation within an intact pericardium is partly attributable to impaired LV systol

48 stion assay revealed that crosslinked bovine pericardium materials resisted enzymatic degradation sig

49 on in HIV, which involves the myocardium and pericardium, may explain the high rate of myocardial fib

50 es of untreated VF in a closed-chest, closed-pericardium model in 6 swine.

51 icardial observations in an open-chest, open-pericardium model of swine VF indicate that blood flows

52 HIV infection may involve the pericardium, myocardium, coronary arteries, pulmonary va

53 duced erythrocyte velocity, and yolk sac and pericardium oedema.

54 With the pericardium open, the same ischemic insult resulted in b

55 al restraint limited LV dilatation; with the pericardium opened, moderate MR accompanied LV dilatatio

56 sing pericardial restraint and then with the pericardium opened.

57 hen cardiac rupture is contained by adherent pericardium or scar tissue.

58 r artery), tumor against a tissue (e.g., the pericardium or wall of any gastrointestinal tract organ)

59 s, including abdominal cavities, pleura, and pericardium, or in body tissue.

60 ants of PV anterograde velocities in an open-pericardium, paced (70 and 90 beats/min) pig model in wh

61 In an open-pericardium, paced (70 and 90 bpm) pig model of LV regio

62 dermal implants (porcine aortic cusps/bovine pericardium) pretreated with TGA demonstrated significan

63 epta and vessels, as well as other heart and pericardium procedures, from January 1, 2008, to Decembe

64 he vessels, and 7284 (46.9%) other heart and pericardium procedures.

65 With an intact pericardium, RCA occlusion produced a decrease in LV end

66 The pericardium represents an important focus of morbidity a

67 n normal open-chest animal preparations, the pericardium restrains LV filling when central blood volu

68 pport structures and chamber, as well as the pericardium, right and left atrial appendages, the junct

69 n short-axis DHE sequences by contouring the pericardium, selecting normal septal myocardium as a ref

70 The pericardium serves many important functions, but it is n

71 ing shortening of the annulus with suture or pericardium show promise.

72 aging to have a longer residence time in pig pericardium than a low-molecular-weight (0.5 kDa) analog

73 athway is involved in the development of the pericardium, the sinus horn myocardium, and the alignmen

74 ties on the degradation of bovine cornea and pericardium tissues under controlled tension.

75 We hypothesized that resection of the pericardium using a minimally invasive epicardial approa

76 Delayed hyperenhancement (DHE) of the pericardium usually represents ongoing inflammation and

77 h 2-mm ring electrodes was introduced in the pericardium via a steerable sheath.

78 re, and percutaneously administered into the pericardium via subxiphoid puncture in rabbits.

79 The fetal pericardium was absent.

80 In 5 pigs (60-75 kg), the pericardium was exposed using surgical subxiphoidal epic

81 The pericardium was of normal thickness (< or =2 mm) in 26 p

82 was performed in 75% of cases and autologous pericardium was the material used to patch this incision

83 Autologous pericardium was used to patch the defect in 30 patients

84 ection of glutaraldehyde-preserved allograft pericardium was used.

85 acking Robo1 revealed partial absence of the pericardium, whereas Robo1/2 double mutants additionally

86 ardiac chamber (including the myocardium and pericardium) which relaxes quickly and fills to a large

87 the heart valves, the conduction system, and pericardium, which may take years to manifest clinically

88 ntact and inotropic support, and 3) with the pericardium wide open.

89 rosis and infiltration of the myocardium and pericardium with inflammatory cells.