ライフサイエンスコーパス: venous system

1 site or within the same system (arterial vs venous system).

2 thways requires ablation within the coronary venous system.

3 spectrum of disorders caused by an abnormal venous system.

4 injecting hypertonic saline into the limbal venous system.

5 tion of disseminated HCC cells in the portal venous system.

6 injecting hypertonic saline into the limbal venous system.

7 ates, that function to propel lymph into the venous system.

8 the unique characteristics of the peripheral venous system.

9 the kidney prior to its leaving through the venous system.

10 BMP signaling in development of the cerebral venous system.

11 permits repeated injections into the portal venous system.

12 eated by repeated injections into the portal venous system.

13 a transvenous approach through the coronary venous system.

14 cing from selected sites within the coronary venous system.

15 e of any other large tributary of the portal venous system.

16 em but is dispensable for the left-hand side venous system.

17 dium and coronary arteries, but not with the venous system.

18 thods were used to destroy the valves of the venous system.

19 pathway from the extracellular space to the venous system.

20 iceal hemorrhage, had thrombus in the portal venous system.

21 ible due to diffuse thrombosis of the portal venous system.

22 n to cerebral venous outflow via the jugular venous system.

23 a cava with retrograde flow into the azygous venous system.

24 pensated for by increased flow in the azygos venous system.

25 n the removal of harmful substances into the venous system.

26 Cs) guided by mapping of the septal coronary venous system.

27 smooth muscle cells to form the arterial and venous systems.

28 atients had a threadlike intrahepatic portal venous system; a 2-stage complete closure was successful

29 diomarker outflow from the feet via the deep venous system, also observed in the superficial venous s

30 t a previously undefined role in the retinal venous system and associated mural cells.

31 ffective method for decompressing the portal venous system and controlling bleeding from esophageal a

32 tioning of the electrode within the coronary venous system and do not, therefore, guarantee proper po

33 that takes into account the function of the venous system and its interaction with the right and lef

34 that takes into account the function of the venous system and its interaction with the right heart m

35 aired coronary artery formation, whereas the venous system and microvasculature are normal.

36 e of unsuccessful ablation from the coronary venous system and multiple endocardial LV/right ventricu

37 ausative fibrin clots may originate from the venous system and paradoxically migrate through physiolo

38 o-part review focuses on the function of the venous system and right heart under normal and stressed

39 arcinoma (HCC) cells often invade the portal venous system and subsequently develop into portal vein

40 -rCBV images were used to reveal the brain's venous system and vascularity in and around any lesions

41 ng the blood flow dynamics within the portal venous system, and in some cases, adding cellular therap

42 t part describes the basic physiology of the venous system, and part two focuses on the role of the v

43 n intraocular fluids directly into the eye's venous system, and that the villous structures are sites

44 patients with CVCs develop DVT of the upper venous system, and the risk increases with duration of c

45 Thrombi in the portal venous system are common in patients with refractory var

46 oses a model that describes how arterial and venous systems are specified and established.

47 frequency ablation (RFA) within the coronary venous system as a function of the distance between the

48 gin and entry from the superior and inferior venous systems, as well as the course taken in between,

49 Venous system attenuation was significantly lower in pro

50 significant differences in the extracranial venous systems between MS patients and HC subjects were

51 y for the development of the right-hand side venous system but is dispensable for the left-hand side

52 essure arterial system to the lower-pressure venous system during untreated VF, thereby overdistendin

53 e pressure differential between arterial and venous systems during perfusion, rapid organ cooling, an

54 lymphatic network is mainly derived from the venous system, evidence supports the existence of lympha

55 cardial cell introduction using the coronary venous system for direct myocardial access and cell deli

56 osis, partial recanalization within affected venous system has been achieved and the patient is remis

57 blood flow was restored throughout the deep venous system in 16 patients (80%) during thrombolytic t

58 g information about the lower extremity deep venous system in a single examination.

59 tem, and part two focuses on the role of the venous system in different pathophysiologic states, part

60 An improved understanding of the role of the venous system in health and disease will allow intensivi

61 An improved understanding of the role of the venous system in pathophysiologic conditions will allow

62 In the venous system, intravascular thrombi can cause venous th

63 anatomical localization data for the hepatic venous system is feasible.

64 e that sympathetic drive from the PVN to the venous system is under tonic GABAergic control.

65 sentery (n = 2), mediastinum (n = 4), portal venous system (n = 1), and peritoneal cavity (n = 1).

66 US for evaluating hemodynamics in the portal venous system of patients with liver cirrhosis and may b

67 the formation of blood clots within the deep venous system of the body.

68 The venous system of the leg was investigated with Duplex ul

69 ly, followed by traditional US of the entire venous system of the lower extremity from the inguinal l

70 STARFIRE to depict the deep and superficial venous systems of the lower extremities, and suggest the

71 led indications and occurred in arterial and venous systems, often resulting in serious morbidity and

72 qualitative assessments of the intracranial venous system on preflight and postflight MR venograms.

73 ous system, also observed in the superficial venous system once the tourniquets were released.

74 The cerebral venous system plays a crucial role in neurological and v

75 ranching in multiple vascular beds while the venous system remained normal.

76 HSV1yCD administered into the portal venous system replicates preferentially in liver metasta

77 enous pressure from the arms to the cerebral venous system, resulting in venous ischaemia to the dien

78 Until recently, the venous system's contribution to the circulatory system h

79 ography is sensitive and specific for portal venous system thrombosis and can provide information tha

80 hunting arterial blood into the brain's deep venous system through aberrant direct connections.

81 delivery of oxygenated blood by means of the venous system to the ischemic foot to prevent amputation

82 ow-pressure, minimally pulsatile flow of the venous system to the pulsatile flow of the arterial circ

83 43% of cases, involving more frequently the venous system, typically as Budd-Chiari syndrome.

84 In all livers, access to the portal venous system via the umbilical vein was successfully ac

85 nol stent developed for dedicated use in the venous system (Vici Venous Stent System, Veniti, Inc/Bos

86 Thrombotic events of the portal venous system were observed in 6 patients who received e

87 after ablation if performed in the coronary venous system within 5 mm of a significant CA.

88 ess was defined as entry into the mesenteric venous system without traversal of any retroperitoneal o