ライフサイエンスコーパス: balloon catheter

1 9%, 60-79%, 80-99%, and 100%) created with a balloon catheter.

2 tented segment by progressive inflation of a balloon catheter.

3 ls of six cadaveric pigs using a microporous balloon catheter.

4 carotid arteries of rats were injured with a balloon catheter.

5 the infrarenal vena cava was occluded with a balloon catheter.

6 through the central channel of an occluding balloon catheter.

7 rcutaneous transluminal coronary angioplasty balloon catheters.

8 on drug-eluting stents (DES) or drug-eluting balloon catheters.

9 ranscranial Doppler, esophageal, and gastric balloon catheters.

10 vessels in 6 anaesthetized male sheep using balloon catheters.

11 ersus dependent regions using intrabronchial balloon catheters.

12 ulmonary pressure with the use of esophageal balloon catheters.

13 essels were dilated by using 5-6-mm-diameter balloon catheters.

14 applied to arterial segments injured by the balloon catheters.

15 Placement of esophageal balloon-catheters.

16 PVs isolation was achieved with the balloon catheter alone in 83%.

17 A 9F 64 electrode balloon catheter and a conventional 7F electrode cathete

18 nary arteries, two were injured with a 15-mm balloon catheter and either were left untreated or were

19 The addition of balloon catheters and overtubes has improved stability a

20 Balloon catheters and vaginal prostaglandins are widely

21 ual participant data meta-analysis comparing balloon catheters and vaginal prostaglandins for cervica

22 In induction of labour, balloon catheters and vaginal prostaglandins have compar

23 , intracoronary stenting or use of perfusion balloon catheters) and clinical complications (myocardia

24 elivery of 15% ethanol with a local delivery balloon catheter, and the other received no further trea

25 s traversed with a specially designed porous balloon catheter, and the wall was infiltrated with 10%

26 arteries to transmural injury, as occurs in balloon catheter angioplasty in humans, is unknown.

27 After vacuum was obtained in the balloon catheter, approximately 2.5 cc of 133Xe gas was

28 Several perfusion balloon catheters are under investigation for local drug

29 as induced in four juvenile domestic pigs by balloon catheter-based aortic dilation, enzyme-mediated

30 panation was performed without inserting the balloon catheter), BD (rats subjected to brain death by

31 in multilayer configurations on endocardial balloon catheters can establish conformal contact with c

32 ered from a local delivery catheter (channel balloon catheter, ChB) after stent implantation.

33 Balloon catheters, compared with vaginal prostaglandins,

34 By using MPI, both balloon catheters could be visualized with high temporal

35 Vs for either 4 or 8 min using a cryothermal balloon catheter (CryoCath Technologies Inc., Kirkland,

36 al laser therapy was performed using a laser-balloon catheter delivering a single dose of 10 mW for 3

37 Using the rat balloon catheter denudation model, we examined the role

38 Jagged1, Jagged2, and Notch1 through 4 after balloon catheter denudation of the rat carotid artery.

39 The balloon catheter diameters ranged from 4 to 20 mm.

40 and a lower risk was associated with primary balloon catheter dilation (HR, 0.69; 95% CI, 0.56-0.85;

41 olved silicone intubation in 669 (50.2%) and balloon catheter dilation in 256 (19.2%).

42 bing performed under anesthesia, and primary balloon catheter dilation.

43 n the response to vascular injury induced by balloon-catheter distention of the rabbit carotid artery

44 aortic root was transiently occluded with a balloon catheter during a brief ACh-induced asystole.

45 A balloon catheter ("endoaortic clamp," EAC) used for occl

46 Balloon catheters facilitate pulmonary vein (PV) isolati

47 l to Assess the Agent Paclitaxel Coated PTCA Balloon Catheter for the Treatment of Subjects With In-S

48 l to Assess the Agent Paclitaxel Coated PTCA Balloon Catheter for the Treatment of Subjects With In-S

49 phic studies demonstrated that inflating the balloon catheter forced cell-permeable ceramide into the

50 ter sequentially moving a pulmonary arterial balloon catheter from a distal to a central location, an

51 Balloon catheters have been designed to facilitate pulmo

52 5), was transferred by using a gene delivery balloon catheter in 18 femoral-iliac arteries (nine arte

53 horacic and intra-abdominal pressures with a balloon catheter in each compartment and (iii) flow at t

54 re was gradually increased by inflation of a balloon catheter in the aorta to determine the autoregul

55 METHODS AND BD was induced by inflation of a balloon catheter in the cranial cavity.

56 was slowly decreased through inflation of a balloon catheter in the inferior vena cava to identify t

57 d right atrial activation by positioning the balloon catheter in the mid right atrium via a femoral v

58 ing degrees of stenosis were induced using a balloon catheter in the proximal left anterior descendin

59 c ischemia was maintained for 40 mins with a balloon catheter in the thoracic aorta, followed by 3 hr

60 lar uterine contractions were recorded via a balloon catheter in the uterine lumen.

61 Use of such 'instrumented' balloon catheters in live animal models illustrates thei

62 The role of balloon catheters in this patient population remains ill

63 I) at baseline and at day 7 and day 14 after balloon catheter-induced denudation of the carotid arter

64 ooth muscle migration into the intima in the balloon catheter-injured rat carotid artery.

65 ulin resistant) 1 week before carotid artery balloon catheter injury and continued for 21 days, at wh

66 ein is induced in porcine arteries following balloon catheter injury and suggest that p21 is likely t

67 reatment decreases vascular damage caused by balloon catheter injury in female Zucker fatty rats.

68 After a balloon catheter injury in the adult, a developmental se

69 regulation of proteolytic activity following balloon catheter injury in the rat carotid artery.

70 ells to nitric oxide (NO), or in response to balloon catheter injury in vivo.

71 s (SMCs) in vivo, the present study used the balloon catheter injury model in the rat carotid artery.

72 n the inner layer of the media 2 hours after balloon catheter injury of rat arteries, which declined

73 All animals underwent balloon catheter injury of the left iliac artery.

74 e development of neointimal thickening after balloon catheter injury of the rat carotid artery.

75 After balloon catheter injury to carotid arteries, expression

76 ar signal events of arterial cells following balloon catheter injury to rat carotid artery.

77 Using a different arterial injury model (balloon catheter injury), we showed that expression of t

78 After balloon catheter injury, neointimal hyperplasia was sign

79 and repair in a rat model of carotid artery balloon catheter injury.

80 TIMP-2, in rat carotid arteries subjected to balloon catheter injury.

81 d is necessary for their proliferation after balloon catheter injury; however, intimal smooth muscle

82 Notably, balloon catheter-integrated LMP microelectrode arrays sh

83 y obstruction was created by inflating a 5-F balloon catheter into a secondary bronchus.

84 mL of sodium chloride through a SPIO-labeled balloon catheter into the sodium chloride-filled vessel

85 very rates and maternal safety profiles, but balloon catheters lead to fewer adverse perinatal events

86 e recently demonstrated that ceramide-coated balloon catheters limit vascular smooth muscle cell (VSM

87 EDPVRs were recorded during balloon catheter obstruction of inferior vena cava inflo

88 go CT colonography with an inflatable rectal balloon catheter or a standard thin rectal tube.

89 lymer, does not fracture when crimped onto a balloon catheter or during deployment in the artery.

90 n a facility under general anesthesia with a balloon catheter or intubation.

91 that Tyshak II and PTS sizing (NuMed Braun) balloon catheters performed adequately as temporary valv

92 o the level seen with exercise by means of a balloon catheter placed in the mitral valve.

93 ocedure the tip of a microwire inserted into balloon catheter placed in the pericallosal artery cause

94 d to one lobe of the rabbit lung by use of a balloon catheter placed under fluoroscopic guidance.

95 uced in instrumented swine by inflation of a balloon catheter placed under the cranium.

96 intraabdominal pressures were measured with balloon catheters placed in the oesophagus and stomach.

97 hepatic venous hemofiltration using a double balloon catheter positioned in the retrohepatic inferior

98 ere mechanically activated by inflation of a balloon catheter positioned in the thoracic aorta at hea

99 The inflated balloon catheter remained in situ for 5 days, at which t

100 erent rates of revascularization and cost of balloon catheters required to offset potential savings i

101 ous transluminal coronary angioplasty (PTCA) balloon catheters, restored by a process strictly contro

102 The balloon catheter selected was advanced across the stenot

103 tion of follow-up, or size of the balloon or balloon catheter shaft.

104 Here, we show that ceramide-coated balloon catheters significantly reduced neointimal hyper

105 The balloon catheter system allows homogenous drug delivery

106 s a 133-Xenon (133Xe) radioactive gas-filled balloon catheter system.

107 ome was lower in women who were allocated to balloon catheters than in those allocated to vaginal pro

108 system consists of a 9F multielectrode-array balloon catheter that has 64 active electrodes and ring

109 Costs were calculated based on the number of balloon catheters, the amount of contrast agent used and

110 or placebo (166) delivered into a centreing balloon catheter through an automatic afterloader.

111 tem that utilizes a noncontact, 64 electrode balloon catheter to compute virtual electrograms simulta

112 ect visualization by using through-the-scope balloon catheters to the end point of 15 mm.

113 elastic membranes of otherwise conventional balloon catheters, to provide diverse, multimodal functi

114 by stepwise volume expansion of an epidural balloon catheter until negative cerebral perfusion press

115 In contrast, rectal balloon catheter use was not significantly associated wi

116 ial to reduce cost depended on the number of balloon catheters used and the rates of urgent revascula

117 Percutaneous Transluminal Angioplasty [PTA] Balloon Catheter vs Standard PTA for the Treatment of At

118 A balloon catheter was inserted into the aorta for the imp

119 A 40-mm balloon catheter was inserted over this guidewire and in

120 thelial cells, and then a specially designed balloon catheter was introduced into the lumen of the th

121 pless antenna) that could be placed within a balloon catheter was manufactured.

122 n vivo technical validation, the microporous balloon catheter was placed in the CBD by means of a tra

123 A balloon catheter was placed in the infarct artery at the

124 A balloon catheter was placed in the left anterior descend

125 For in vivo validation, the balloon catheter was placed into coronary arteries of se

126 A descending aortic occlusion-infusion balloon catheter was placed through the femoral artery.

127 An aortic balloon catheter was placed with its tip just distal to

128 Afterward, a segmented balloon catheter was positioned and automatically loaded

129 Esophageal and gastric balloon catheters were passed through the anaesthetized

130 Used PTCA balloon catheters were shipped to a central facility and

131 al mapping, a novel compliant radiofrequency balloon catheter with 10 irrigated, flexible electrodes

132 oronary devices comprised of a semicompliant balloon catheter with an engineered coating that allows

133 as induced by sudden inflation of a subdural balloon catheter with continuous monitoring of arterial

134 cranial pressure by inflation of an epidural balloon catheter with saline (1 mL/20 min) until brain d

135 tion of the colon produced by inflation of a balloon catheter with varying volumes of water.

136 ons, although paclitaxel is the only drug on balloon catheters with proven inhibition of restenosis.