ライフサイエンスコーパス: pulmonary blood flow

1 by CPB is augmented in lambs with increased pulmonary blood flow.

2 a noninvasive, on-line monitor of changes in pulmonary blood flow.

3 of rat were reduced in shunt rats with high pulmonary blood flow.

4 e to cyclic interruption and exaggeration of pulmonary blood flow.

5 r remodeling causing increased resistance to pulmonary blood flow.

6 ulmonary hypertension secondary to increased pulmonary blood flow.

7 t (BTS), physiologically distinct sources of pulmonary blood flow.

8 pertension in this animal model of increased pulmonary blood flow.

9 shunt or a DS in infants with duct-dependent pulmonary blood flow.

10 ns, particularly for children with increased pulmonary blood flow.

11 after CPB in lambs with normal and increased pulmonary blood flow.

12 eled form as an imaging modality to evaluate pulmonary blood flow.

13 mics congenital heart disease with increased pulmonary blood flow.

14 functional single ventricle and very limited pulmonary blood flow.

15 ty, particularly for children with increased pulmonary blood flow.

16 striction was assessed as the change in left pulmonary blood flow.

17 lowering cerebral, superior vena caval, and pulmonary blood flows.

18 41 (25, 57); descending aorta, 55 (35, 75); pulmonary blood flow, 16 (0, 34); umbilical vein, 29 (11

19 At rest, TR subjects had lower pulmonary blood flow (3.6+/-0.4 versus 5.1+/-1.9 L/min;

20 sus 13.8+/-4.2 mL/min per kg; P=0.02), lower pulmonary blood flow (6.4+/-1.3 versus 10.3+/-3.3 L/min;

21 T shunts; P=0.001) and presence of antegrade pulmonary blood flow (61% of PDA stents versus 38% of BT

22 109, 265); descending aorta, 252 (160, 344); pulmonary blood flow, 77 (0, 160); umbilical vein, 134 (

23 In the absence of pulmonary blood flow, acid instillation led to a 50% dec

24 d BT shunt for infants with ductal-dependent pulmonary blood flow adjusted for differences in patient

25 tored in 14 1-month-old lambs with increased pulmonary blood flow (after in utero placement of an aor

26 Preexisting increased pulmonary blood flow alters the response of the pulmonar

27 ed in 1-month-old lambs (n=7) with increased pulmonary blood flow and 6 age-matched control lambs.

28 ncreases the annulus Z score and anterograde pulmonary blood flow and facilities simultaneous coiling

29 ove oxygenation by two mechanisms: increased pulmonary blood flow and improved ventilation-perfusion

30 were consistent with comparable increases in pulmonary blood flow and therefore stroke volumes.

31 To determine cerebral and pulmonary blood flow and to establish the hierarchy of c

32 , NPV brought about a marked increase in the pulmonary blood flow and, hence, cardiac output of Fonta

33 Over time, increased pulmonary blood flow and/or pressure results in the emer

34 ukostasis and markedly improved oxygenation, pulmonary blood flow, and graft survival.

35 provements in pulmonary vascular resistance, pulmonary blood flow, and right ventricular contractilit

36 rcise in CHF, to examine its relationship to pulmonary blood flow, and to consider its functional sig

37 ntroversy exists regarding whether accessory pulmonary blood flow (APBF) should be left at the time o

38 ing hyperpnea, and therefore that changes in pulmonary blood flow are not associated with HIB.

39 causing dependence on the arterial duct for pulmonary blood flow are often palliated with a shunt us

40 se patients are influenced by restriction of pulmonary blood flow, arrhythmia, and pacemaker requirem

41 high continuous distending pressure impedes pulmonary blood flow as evidenced by reduced lung volume

42 stent implantation in the arterial duct for pulmonary blood flow augmentation.

43 op pulmonary hypertension or to redistribute pulmonary blood flow away from the edematous lung region

44 S for cardiac conditions with duct-dependent pulmonary blood flow between January 2012 and December 3

45 was determined by Doppler echocardiography, pulmonary blood flow by inert gas re-breathing, and vaso

46 nificantly augmented in lambs with increased pulmonary blood flow compared with control lambs (P < .0

47 Pulmonary blood flow continued to improve, with a total

48 In the animals in group 1, left pulmonary blood flow decreased by 62 +/- 8 (SEM)% during

49 After 24 hrs of sepsis, left pulmonary blood flow decreased from 56 +/- 10% to 26 +/-

50 In the Normal-PLV piglets, pulmonary blood flow decreased from baseline (before inj

51 In the OA-Control piglets, pulmonary blood flow decreased in the most dependent are

52 We conclude that reduction of pulmonary blood flow decreases eNOS mRNA and protein exp

53 stulated to document hyperventilation of the pulmonary blood flow due to a right-to-left EIS were (1)

54 Pulmonary blood flow during cardiac arrest and cardiopul

55 HPV was assessed as the decrease in left pulmonary blood flow during hypoxia, measured with an ul

56 would demonstrate increased heterogeneity of pulmonary blood flow during hypoxia.

57 A brief period of NPV increased pulmonary blood flow from 2.4 to 3.5 L x min(-1) x /m(-2

58 HAPE-susceptible individuals have increased pulmonary blood flow heterogeneity in acute hypoxia, con

59 spin labeling) was used to quantify spatial pulmonary blood flow heterogeneity in three subject grou

60 Nonpulsatile pulmonary blood flow in Fontan circulation results in pu

61 Changes in pulmonary blood flow in response to Ach were determined

62 required reoperation related to the BCPS or pulmonary blood flow in the early postoperative period:

63 tery pressure due to increased resistance to pulmonary blood flow in the setting of portal hypertensi

64 and a higher likelihood of absent upper lobe pulmonary blood flow in these patients.

65 one early death, and procedures to decrease pulmonary blood flow in three patients.

66 In a rat model of high pulmonary blood flow-induced pulmonary vascular collagen

67 VEC MRI has the ability to quantify pulmonary blood flow inside the lumen of nitinol stents.

68 Increased pulmonary blood flow is believed to contribute to the de

69 The pulsatile nature of pulmonary blood flow is important for shear stress-media

70 The spatial distribution of regional pulmonary blood flow is preserved during partial liquid

71 on emission tomography to measure fractional pulmonary blood flow, lung water concentration (LWC), an

72 Infants with ductal-dependent pulmonary blood flow may undergo palliation with either

73 e purpose of consistency and makes sense, as pulmonary blood flow measurements are not corrected for

74 blood only to the systemic circuit, whereas pulmonary blood flow occurs passively.

75 stigate the effects of preexisting increased pulmonary blood flow on these changes; and to better def

76 Infants with ductal-dependent pulmonary blood flow palliated with either a PDA stent o

77 Redistribution of pulmonary blood flow (PBF) away from edematous regions o

78 trated that computed tomography (CT)-derived pulmonary blood flow (PBF) heterogeneity is greater in s

79 Pulmonary blood flow (PBF) is a critical determinant of

80 is determined regional perfusion parameters, pulmonary blood flow (PBF), and mean transit time (MTT).

81 Pulmonary blood flow (PBF), first-pass bolus kinetic par

82 ay be related to the pre-iNO distribution of pulmonary blood flow (PBF).

83 onary vascular resistance (PVR) and increase pulmonary blood flow (PBF); more gradual changes occur o

84 Hyperoxia did not change cerebral and pulmonary blood flow; Po2 increased 94% (P=0.01).

85 t intentionally left in place to augment the pulmonary blood flow provided by the BDG.

86 Carbon monoxide transfer factor (TLCO) and pulmonary blood flow (Q(C)) were measured by a rebreathe

87 Oximetry underestimated CMR-measured pulmonary blood flow (Qp) by an average of 1.1 L/min per

88 n pulmonary artery was ligated distally, and pulmonary blood flow (Qp) was provided through a 5-mm ao

89 e measured in vivo the distribution of total pulmonary blood flow (QPA) between the right (QRPA) and

90 dex accounted for the increased cerebral and pulmonary blood flow (R=0.73, P=0.02) and cerebral O2 tr

91 Changes in pulmonary blood flow rate can alter the size of the perf

92 artery shunt or Sano modification to provide pulmonary blood flow rather than the standard modified B

93 e-to-pulmonary artery shunt as the source of pulmonary blood flow, rather than the modified Blalock-T

94 ng injury was evaluated by the left-to-right pulmonary blood flow ratio, the weight gain of the isogr

95 +/-3.3 L/min; P=0.001), and less increase in pulmonary blood flow relative to VO2 (+4.6+/-1.1vs +6.2+

96 Patients had a two-ventricular repair (A) or pulmonary blood flow supplied by an aortopulmonary shunt

97 e at birth, allowing for a rapid increase in pulmonary blood flow that is essential for efficient gas

98 With duct-dependent pulmonary blood flow, the procedure carries high risk, a

99 usion ratio throughout the lung by directing pulmonary blood flow to better ventilated areas of the l

100 Pulmonary blood flow to lung units with a normal VA/Q ra

101 ich were also associated with an increase in pulmonary blood flow, transpulmonary efficiency, and rig

102 further modified by active redistribution of pulmonary blood flow under hypoxic and hyperoxic conditi

103 reserve (PFR) was calculated as the ratio of pulmonary blood flow velocity in response to Ach relativ

104 ite were assessed by measuring the change in pulmonary blood flow velocity with a Doppler-tipped wire

105 unchanged during NPV, and the improvement in pulmonary blood flow was achieved by an increase in stro

106 Pulmonary blood flow was assessed by fluorescent microsp

107 tional experiments were carried out in which pulmonary blood flow was eliminated.

108 Accessory pulmonary blood flow was included in 18 patients.

109 stitution of IPPV, and in a second subgroup, pulmonary blood flow was measured after an extended peri

110 In one subgroup of patients, pulmonary blood flow was measured again after reinstitut

111 Accessible pulmonary blood flow was measured at each workload with

112 Pulmonary blood flow was measured using the direct Fick

113 relationship between foramen ovale shunt and pulmonary blood flow was noted (r=-0.64; P<0.0001).

114 In the OA-PLV piglets, pulmonary blood flow was preserved over time throughout

115 Regional pulmonary blood flow was studied in 21 piglets in the su

116 In 1-month-old lambs with increased pulmonary blood flow, we have demonstrated early alterat

117 Regional lung water and pulmonary blood flow were assessed by positron emission

118 PVR (PVRI) using Fick principle to calculate pulmonary blood flow, with respiratory mass spectrometry