ライフサイエンスコーパス: pulmonary gas exchange

1 al considerations and measurements of global pulmonary gas exchange.

2 e did not significantly improve deteriorated pulmonary gas exchange.

3 both greater ventilation and more efficient pulmonary gas exchange.

4 her arterial oxygen content and an unchanged pulmonary gas exchange.

5 ale methodology for quantitative analysis of pulmonary gas exchange.

6 apparent effects on systemic hemodynamics or pulmonary gas exchange.

7 hemodilution, immunomodulation, and improved pulmonary gas exchange.

8 od flow, left ventricular wall thickening or pulmonary gas exchange.

9 A minimal diffusion barrier is key to the pulmonary gas exchange.

10 0.001 vs control each) and the deteriorated pulmonary gas exchange (12-48 hr: p < 0.05 vs control ea

11 Our objective was to examine pulmonary gas exchange abnormalities and the mechanisms

12 : see text]co(2)]) provides an indication of pulmonary gas exchange abnormalities in chronic obstruct

13 ynamics and is likely to be a consequence of pulmonary gas exchange abnormalities including ventilati

14 ays dysfunction, dynamic hyperinflation, and pulmonary gas exchange abnormalities.

15 We used pulmonary gas exchange and (31) P magnetic resonance spe

16 s, resulting in an apparent matching between pulmonary gas exchange and alveolar ventilation.

17 Pulmonary gas exchange and hemodynamics were monitored f

18 This pathophysiology included decreased pulmonary gas exchange and lung compliance, increased pu

19 This pathophysiology included decreased pulmonary gas exchange and lung compliance, increased pu

20 129Xe magnetic resonance imaging, report on pulmonary gas exchange and pulmonary capillary hemodynam

21 ging (MRI) is capable of regional mapping of pulmonary gas-exchange and has found application in a wi

22 Using pulmonary gas-exchange and intramuscular (31) P magnetic

23 ols (all P < 0.05) and minimal small airway, pulmonary gas exchange, and radiographic parenchymal lun

24 This study investigated hemodynamics and pulmonary gas exchange applying CPAP enhanced with press

25 The primary outcome is the change in pulmonary gas exchange as assessed by the partial pressu

26 ipheral gas exchange - which translates into pulmonary gas exchange - can be sensed.

27 We conclude that NO has net effects on pulmonary gas exchange, depending on the underlying lung

28 Why pulmonary gas exchange deteriorates after administration

29 ne in maximal aerobic capacity and preserves pulmonary gas exchange during acute hypoxic exercise.

30 ostimulation, near-infrared spectroscopy and pulmonary gas exchange during and following exercise.

31 Tetrastarch sustains pulmonary gas exchange during experimental systemic infl

32 igh affinity haemoglobin had no worsening of pulmonary gas exchange during hypoxic exercise but had g

33 of venous admixture (Q VA /QT) that impairs pulmonary gas exchange efficiency (i.e. increases the al

34 Pulmonary gas exchange efficiency was evaluated using th

35 dyspnea, respiratory muscle activation, and pulmonary gas exchange efficiency.

36 respiratory mechanics but without impacts on pulmonary gas exchange efficiency; (2) normal total card

37 alculated shunt and the associated effect on pulmonary gas exchange estimated by MIGET.

38 and (129)Xe MRI for ventilation and regional pulmonary gas exchange evaluation, at the same study vis

39 Women may experience greater pulmonary gas exchange impairment during exercise than m

40 more important in determining whether or not pulmonary gas exchange impairment occurs during exercise

41 how approximately 80 ppm inhaled NO altered pulmonary gas exchange in anesthetized ventilated dogs w

42 y increased during hypoxic exercise, whereas pulmonary gas exchange in HAH subjects was unchanged bet

43 the temporal and spatial characteristics of pulmonary gas exchange in intact and diseased lungs.

44 tion (MV) is used to support ventilation and pulmonary gas exchange in patients during critical illne

45 iction.Objectives: Noninvasive assessment of pulmonary gas exchange in preterm infants with and witho

46 t that the previously reported impairment in pulmonary gas exchange in the HIV+ population involves l

47 These included decreased pulmonary gas exchange, increased pulmonary edema, abnor

48 In a model of severe ARDS, pulmonary gas exchange is improved during total followed

49 Some pulmonary gas exchange is known to occur proximal to the

50 e effects of FS-069 on hemodynamic function, pulmonary gas exchange, left ventricular wall thickening

51 exhaustion with simultaneous measurements of pulmonary gas exchange, minute ventilation, blood lactat

52 Some 12-19% of pulmonary gas exchange occurred within small (1.7 mm in

53 der these experimental conditions, 12-19% of pulmonary gas exchange occurs within the small pulmonary

54 However, variance in pulmonary gas exchange played essentially no role in det

55 Pulmonary gas exchange relies on a rich capillary networ

56 Effective pulmonary gas exchange relies on the free diffusion of g

57 t (QT), leg blood flow (LBF), and muscle and pulmonary gas exchange, the latter using the multiple in

58 sure can increase myocardial work and impair pulmonary gas exchange to a degree that might be clinica

59 ventilated pigs, the prone position improves pulmonary gas exchange to a greater degree in the presen

60 We use our multiscale model for pulmonary gas exchange to quantify the oxygen uptake abn

61 Pulmonary gas exchange variables were determined breath

62 Pulmonary gas exchange was measured breath-by-breath and

63 Pulmonary gas exchange was measured breath-by-breath.

64 Pulmonary gas exchange was measured on a breath-by-breat

65 a dose-dependent fashion, no amelioration in pulmonary gas exchange was observed, as reflected by PaO

66 Heart rate and pulmonary gas exchange were measured during the squat ex

67 njury, may have limited benefit in improving pulmonary gas exchange when diffusion is impaired by sev

68 od flow, left ventricular wall thickening or pulmonary gas exchange when injected intravenously in la

69 d flow, left ventricular wall thickening and pulmonary gas exchange when injected intravenously; and

70 he degree of airway obstruction and improved pulmonary gas exchange, whereas the development of lung