ライフサイエンスコーパス: circulatory arrest

1 ith arrested heart, on-pump with hypothermic circulatory arrest).

2 tained after handgrip exercise (posthandgrip circulatory arrest).

3 ng periods of low cerebral blood flow and/or circulatory arrest.

4 on were preserved following deep hypothermic circulatory arrest.

5 infants undergoing arch surgery, the use of circulatory arrest.

6 cardiopulmonary bypass and deep hypothermic circulatory arrest.

7 ion, and during ischemia produced by forearm circulatory arrest.

8 ion during deep hypothermic bypass and after circulatory arrest.

9 esumed to result from transient intracranial circulatory arrest.

10 activation after deep hypothermic bypass and circulatory arrest.

11 yhemoglobin desaturation in the brain during circulatory arrest.

12 ve during ascending aortic replacement under circulatory arrest.

13 vity (EEG and evoked potentials) or cerebral circulatory arrest.

14 eath, which must be a minimum of 5 min after circulatory arrest.

15 a and prediction of the need for hypothermic circulatory arrest.

16 ures that indicated the need for hypothermic circulatory arrest.

17 renal blood flow (basal versus posthandgrip circulatory arrest, 4.3 +/- 0.1 versus 3.5 +/- 0.2 mL.mi

18 d precontraction) and profoundly hypothermic circulatory arrest (42+/-5%, P<.05) than in vessels from

19 d highest with on-pump CABG with hypothermic circulatory arrest (5.3% [95% CI, 2.0%-11%]).

20 lin was reduced after profoundly hypothermic circulatory arrest (83+/-3%, P<.05), but was similar in

21 vels showed a correlation with the length of circulatory arrest and aortic cross-clamp time.

22 Mean times to circulatory arrest and electrical asystole were 8 +/- 1

23 Times to circulatory arrest and electrical asystole were recorded

24 gorithm in a defibrillator determine rapidly circulatory arrest and facilitate prompt initiation of e

25 iogram system be used to distinguish between circulatory arrest and other collapse states?

26 dure alone does not affect IQ, but length of circulatory arrest and pH management are associated with

27 mal fluids to have in the circulation during circulatory arrest and reperfusions need to be determine

28 Graded handgrip exercise, posthandgrip circulatory arrest, and administration of intra-arterial

29 C; then they were subjected to 60 minutes of circulatory arrest, and afterward, rewarmed with cardiop

30 ies (PSS: peripheral cardiopulmonary bypass, circulatory arrest, and non-median sternotomy).

31 c process in a rat model of deep hypothermic circulatory arrest, and that intestinal injury, and loca

32 opulmonary bypass time or ischemic time, and circulatory arrest; and postoperative--delayed sternal c

33 We recommend circulatory arrest as the optimum modality for patients

34 cells as central players in deep hypothermic circulatory arrest-associated responses, and opens novel

35 ss ([CPB] Hct 30%, 100 mL/kg/min), 60-minute circulatory arrest at 15 degrees C, and 40-minute rewarm

36 tus, lower IQ was associated with the use of circulatory arrest before the Fontan operation (P=0.002)

37 ategy used in infant heart surgery was total circulatory arrest (CA) or low-flow cardiopulmonary bypa

38 n of 40 ml saline into a forearm vein in the circulatory arrested condition.

39 cardiopulmonary bypass and deep hypothermic circulatory arrest (CPB/DHCA) in a pediatric model.

40 to minimize the duration of deep hypothermic circulatory arrest (DHCA) and efforts to ameliorate the

41 or 30%, followed by 1-hour deep hypothermic circulatory arrest (DHCA) and rewarming on CPB.

42 and efficacy of a period of deep hypothermic circulatory arrest (DHCA) during elective replacement of

43 The technique of deep hypothermic circulatory arrest (DHCA) for cardiothoracic surgery is

44 ch repair, requiring either deep hypothermic circulatory arrest (DHCA) or antegrade cerebral perfusio

45 tegies as an alternative to deep hypothermic circulatory arrest (DHCA).

46 rfusion (ACP) compared with deep hypothermic circulatory arrest (DHCA).

47 cardiopulmonary bypass with deep hypothermic circulatory arrest (DHCA).

48 pothermic cardiopulmonary bypass (dhCPB) and circulatory arrest (DHCA).

49 nd pulmonary function after deep hypothermic circulatory arrest (DHCA).

50 ending the safe duration of deep hypothermic circulatory arrest (DHCA).

51 Cannulation and heparinization after circulatory arrest does not prevent successful normother

52 rmia, cardiopulmonary bypass, and periods of circulatory arrest, factors that may potentially increas

53 evacuation and resuscitative surgery during circulatory arrest, followed by delayed resuscitation; b

54 to 18 degrees C followed by deep hypothermic circulatory arrest for 120 mins.

55 y bypass before instituting deep hypothermic circulatory arrest for 45 minutes.

56 rgery, deep hypothermic CPB for 40 mins, and circulatory arrest for 60 mins.

57 n of the intimal tear and use of hypothermic circulatory arrest for distal anastomosis results in acc

58 atrium requires thoracotomy and hypothermic circulatory arrest for successful removal of the tumour,

59 ation of the whole organism during prolonged circulatory arrest ( > or = 1 hr), followed by resuscita

60 al perfusion (RCP) with profound hypothermic circulatory arrest has been subject to much debate.

61 cardiopulmonary bypass and deep hypothermic circulatory arrest have allowed the open repair of many

62 .08), and cumulative duration of hypothermic circulatory arrest (HCA) (P=0.09) approached significanc

63 Hypothermic circulatory arrest (HCA) provides neuroprotection during

64 ransesophageal echocardiography; hypothermic circulatory arrest (HCA) with retrograde cerebral perfus

65 metabolic deficit observed after hypothermic circulatory arrest (HCA).

66 ion surgery with the use of deep hypothermic circulatory arrest (HCA).

67 nominate artery or by the use of hypothermic circulatory arrest (HCA).

68 s and criteria for the diagnosis of cerebral circulatory arrest in CT angiography.

69 d with the use of cardiopulmonary bypass and circulatory arrest in patients with a retrohepatic or su

70 cardiopulmonary bypass and deep hypothermic circulatory arrest, is associated with systemic inflamma

71 Filtration ceased upon circulatory arrest (n = 3).

72 Circulatory arrest occurred 7.6+/-0.3 min following WLST

73 nimation research; complete reversibility of circulatory arrest of 1 hr in dogs under profound hypoth

74 r to ventilation with 100% oxygen (O2) after circulatory arrest of the donor.

75 onal cerebral perfusion and deep hypothermic circulatory arrest on 1-year outcomes; no difference was

76 t method, deep hypothermia with either total circulatory arrest or continuous low-flow cardiopulmonar

77 ing the aortic arch without deep hypothermic circulatory arrest or even cardiopulmonary bypass.

78 dly hypothermic (16 degrees C with 1 hour of circulatory arrest) or normothermic (37 degrees C) CPB f

79 ary hypertension (P=0.03) and in cases where circulatory arrest (P=0.01) or inotropic support (P=0.01

80 nd "other complex" (P=0.003) or prior use of circulatory arrest (P=0.03), as well as a reoperation wi

81 cardiopulmonary bypass and deep hypothermic circulatory arrest, p = .05).

82 No evidence exists that profound hypothermic circulatory arrest (PHCA) improves survival or reduces t

83 voluntary contraction, followed by 2 min of circulatory arrest pre-, in- and post-flight.

84 schemic stroke, acute kidney injury, trauma, circulatory arrest, sickle cell disease and sleep apnea.

85 Using the database of the Boston Circulatory Arrest Study involving 171 children with D-t

86 < 0.0001), cross-clamp time, (P < 0.03) and circulatory arrest time (P < 0.003) were associated with

87 h longer total support time (P=.002), longer circulatory arrest time (P=.004), longer length of intub

88 uded both pre- and intraoperative variables, circulatory arrest time and right ventricular hypoplasia

89 m withdrawal of life-supporting treatment to circulatory arrest was 150 minutes.

90 The use of RCP with profound hypothermic circulatory arrest was associated with a reduction in mo

91 Aortic repair with or without circulatory arrest was associated with comparable early

92 MSNA during post-handgrip circulatory arrest was higher post- than pre- or in-flig

93 The necessity of hypothermic circulatory arrest was successfully predicted in 94% (45

94 Hypothermic circulatory arrest was used in 52 patients (mean 38 +/-

95 arch reconstruction, the use and duration of circulatory arrest were significantly associated with ne

96 neurological outcome after deep hypothermic circulatory arrest when pH-stat cardiopulmonary bypass i

97 In contrast, during post-handgrip circulatory arrest, which isolates muscle metaboreceptor

98 cardiopulmonary bypass and deep hypothermic circulatory arrest with calpain inhibition were associat