ライフサイエンスコーパス: closed-chest

1 Closed-chest 40 min I/R was performed in 20 pigs sacrifi

2 Closed-chest 40-min ischemia/reperfusion was performed i

3 taneous valve interventions has emerged as a closed-chest alternative for all patients, but particula

4 te that under physiological conditions, with closed-chest and phasic negative intrathoracic pressure

5 ty-four measurements were performed in eight closed-chest anesthetized greyhounds at baseline and dur

6 analysis in Langendorff perfused hearts and closed-chest anesthetized mice also indicated depressed

7 was performed by cardiac catheterization in closed-chest anesthetized mice, by pressure-volume-loop

8 recorded from the apical 4-chamber view in 7 closed-chest anesthetized mongrel dogs during 5 differen

9 osis were studied 1 or 2 months later in the closed-chest anesthetized state.

10 ssed in pigs after an over-night fast in the closed-chest anesthetized state.

11 artery was perfused at constant pressure in closed-chest, anesthetized dogs, and exogenous adenosine

12 ng MBF showed excellent reproducibility in a closed-chest animal model of chronic CAD.

13 s study was to quantitatively evaluate, in a closed-chest animal model, a noninvasive method of measu

14 In closed-chest animals the threshold and inflexion pressur

15 In closed-chest animals, pericardiotomy was performed using

16 mits efficient percutaneous gene delivery in closed-chest animals.

17 dium content changes over time in an in vivo closed-chest canine model (n=13) of myocardial infarctio

18 Resuscitation was by closed-chest cardiopulmonary bypass, postcardiac arrest

19 d by MRI for 30 minutes of untreated VF in a closed-chest, closed-pericardium model in 6 swine.

20 ght mongrel dogs underwent an acute 2-minute closed-chest coronary artery occlusion while continuous

21 or using porcine models of MI created with a closed-chest coronary artery occlusion-reperfusion techn

22 vein injection of AF0145 (10 to 40 mg) in 13 closed chest dogs (mean weight 25.6 kg).

23 in the absence of ischemia in anesthetized, closed-chest dogs and pigs.

24 MA sites (DT-A) was measured in nine normal closed-chest dogs by use of surgically implanted radiopa

25 We studied groups of anesthetized closed-chest dogs that had AV produced by radiofrequency

26 Closed-chest dogs underwent 90 min left anterior descend

27 Ten closed-chest dogs underwent 90-min coronary artery occlu

28 Closed-chest dogs were anesthetized, pretreated with atr

29 as studied using radiopaque markers in eight closed-chest dogs with acute posterior left ventricular

30 Eleven chronically instrumented closed-chest dogs with multivessel coronary stenosis wer

31 In 15 closed-chest dogs, atrial fibrillation was simulated by

32 Mitral regurgitation was created in 11 closed-chest dogs.

33 ly invasive port-access cardiac surgery with closed chest endovascular cardiopulmonary bypass.

34 Adult farm pigs (n=5) were subjected to closed-chest experimental MI.

35 Importantly, in vivo closed-chest hemodynamic assays revealed normal left ven

36 tion, but the minimum unsafe level for AC in closed-chest humans is not known.

37 Repetitive closed-chest I/R (15 minutes) was performed daily in C57

38 ted an epicardial HIU ablation catheter in a closed chest, in vivo swine model.

39 ine anesthetized and mechanically ventilated closed-chest Landrace pigs (67 +/- 2 kg).

40 4796 can be visualized on in vivo imaging in closed chest large animal model after intravenous inject

41 ht to show the feasibility of catheter-only, closed-chest, large-vessel anastomosis (superior vena ca

42 ion) at distinct times of the day, using the closed-chest left anterior descending coronary artery oc

43 We examined 7 dogs 2 days after a 90-minute closed-chest left anterior descending coronary artery oc

44 to apex in seven dogs 2 days after a 90-min closed-chest left anterior descending coronary occlusion

45 inal echocardiography, rats underwent either closed-chest left ventricular (LV) catheterization or La

46 went transthoracic echo Doppler studies, and closed-chest left ventricular pressures with direct left

47 ested the hypothesis that when compared with closed-chest manual compressions at 80 chest compression

48 For 1.2 MPa and 2.2 MPa, open- or closed-chest MCE, Evans blue content in tissue within th

49 ers and physiological assay results (ECG and closed-chest Millar catheter) were within the normal ran

50 disruption and antibody neutralization in a closed-chest model of reperfused murine myocardial infar

51 In this report we compare closed chest models of canine and mouse infarction/reper

52 Two closed-chest models representing different rates of coll

53 e performed using a chronically instrumented closed chest mouse model.

54 ection in normal canines with open (n=3) and closed chest (n=5) and in a pig model with features of h

55 ith an open chest compared with those with a closed chest (P=.0083).

56 We used a closed-chest pig model of nonocclusive coronary stenosis

57 Anesthetized, closed-chest piglets were intubated and ventilated for 3

58 were recorded simultaneously in anesthetized closed-chest pigs (n=5) during sinus rhythm, and epicard

59 In 29 closed-chest pigs, myocardial ischemia was induced by in

60 by external defibrillation in anesthetized, closed-chest pigs.

61 Twelve pigs underwent closed-chest placement of a flow reducer for 70%-90% lum

62 A closed-chest rat model was implemented by using an infla

63 Epinephrine given during closed-chest resuscitation increases blood flow across t

64 This rupture and inadequacy of closed-chest resuscitation were felt to be associated wi

65 Interventions: Closed-chest resuscitation with opened and closed chest

66 and improve the effectiveness and outcome of closed-chest resuscitation.

67 a rat model of ventricular fibrillation and closed-chest resuscitation.

68 and improve outcome using a porcine model of closed-chest resuscitation.

69 before an 8-minute interval of conventional closed-chest resuscitation.

70 thophysiology and the role of open-heart vs. closed-chest resuscitative measures are discussed.

71 In this study we used a closed-chest rodent model of chronic recurring myocardia

72 studied 1 month after instrumentation in the closed-chest sedated state.

73 rformed 1-5 mo later with the animals in the closed-chest sedated state.

74 multaneous biplane videofluoroscopy in seven closed-chest, sedated sheep before and during asynchrono

75 y recovery period, animals were studied in a closed-chest, sedated, autonomically blocked state.

76 stained atrial fibrillation was induced in 8 closed-chest sheep with burst pacing and continuous peri

77 stained atrial fibrillation was induced in 8 closed-chest sheep with burst pacing and maintained with

78 Closed-chest stunning and SEMI were produced by angiopla

79 Closed-chest swine (n = 20) were prepared with an 80% co

80 In this closed-chest swine model of VF, substantial right ventri

81 This study investigated in closed-chest swine the effect of a persistent critical c

82 derwent 40 min of coronary occlusion using a closed-chest technique.

83 : Closed-chest resuscitation with opened and closed chest tubes and medical and fluid interventions w

84 Nonlethal closed-chest unilateral lung contusion was induced in a

85 ower a microimplant (2 mm, 70 mg) capable of closed-chest wireless control of the heart that is order

86 (open-chest) or modified four-chamber view (closed-chest) with 1:4 end systolic electrocardiogram tr