ライフサイエンスコーパス: lung ventilation

1 nd alveolar flooding at end-expiration (open-lung ventilation).

2 eceptors regulate arterial PCO2 by adjusting lung ventilation.

3 d with adulthood that necessitate control of lung ventilation.

4 twork and contributes to adaptive changes in lung ventilation.

5 cated within the CNS, causing an increase in lung ventilation.

6 neurons is much more effective at increasing lung ventilation.

7 tant than their discharge pattern in driving lung ventilation.

8 can safely undergo thoracic surgery and one-lung ventilation.

9 ic patient and for managing pediatric single lung ventilation.

10 erfusion injury sustained as a result of one-lung ventilation.

11 scussed in relation to the management of one-lung ventilation.

12 equate arterial oxygen tension during single-lung ventilation.

13 included in the absolute indication for one-lung ventilation.

14 use a positive pressure gular pump to assist lung ventilation.

15 nt frequency of 3He) were obtained to depict lung ventilation.

16 tion, we selected strides with no concurrent lung ventilation.

17 )Tc-Technegas for quantification of relative lung ventilation.

18 As respiratory mechanics inherently support lung ventilation, 3D MR Spirometry may open a new way to

19 Full functional residual capacity liquid lung ventilation administered before bypass resulted in

20 ompared to <1 mg (65.2% vs 35.0%, P = 0.05), lung ventilation after injection (65.2% vs 35.0%, P = 0.

21 ent of CFTR function by ELX/TEZ/IVA improves lung ventilation and abnormalities in lung morphology, i

22 c stresses, whereas RTN selectively controls lung ventilation and arterial Pco(2) stability.

23 oring device that is able to assess regional lung ventilation and changes in aeration.

24 regulate tissue acid-base balance by driving lung ventilation and CO(2) excretion-this CO(2)-evoked i

25 BPD) and current lung function phenotypes on lung ventilation and microstructure in preterm-born chil

26 Measurements of regional lung ventilation and microstructure in subjects with chi

27 wing, making them a key target for improving lung ventilation and patient outcomes.

28 effect of ENDS exposure and tobacco smoke on lung ventilation and perfusion by functional MRI and lun

29 caftor-tezacaftor-ivacaftor (ETI) therapy on lung ventilation and perfusion in people with cystic fib

30 delivery systems (ENDS) and tobacco smoke on lung ventilation and perfusion is limited.

31 existing pathology, surgical trauma, single-lung ventilation and postoperative ventilation-perfusion

32 en shown to detect regional abnormalities in lung ventilation and structure in adults with asthma, bu

33 In patients who require one-lung ventilation and who present with a difficult airway

34 with this phenomenon, its impact on regional lung ventilation, and any association with changes in pl

35 condition, obtaining and maintaining single lung ventilation, and maintaining adequate ventilation a

36 Liquid lung ventilation animals received perflubron via the end

37 and half functional residual capacity liquid lung ventilation animals.

38 t bronchoconstriction leads to patchiness in lung ventilation, as well as a computational model that

39 CT was comparable to a direct measurement of lung ventilation at hyperpolarized (3)He MR imaging.

40 ane oxygenation support permits low pressure lung ventilation, avoiding barotrauma to lungs made fria

41 d Hyperpolarized noble gas MRI helps measure lung ventilation, but clinical translation remains limit

42 cal projections, RTN-Phox2b neurons regulate lung ventilation by controlling breathing frequency, ins

43 RTN neurons increase lung ventilation by stimulating multiple aspects of brea

44 Conclusion Quantification of regional lung ventilation by using dynamic (19)F gas washout MR i

45 In contrast, the burst associated with lung ventilation can be generated in the absence of Cl(-

46 Lung ventilation defects identified by using hyperpolari

47 These data suggest that liquid lung ventilation dosing at full functional residual capa

48 focal disease (such as pneumonia) and in one-lung ventilation during anaesthesia for thoracic surgery

49 One-lung ventilation during esophagectomy is associated with

50 ent axial constraint that prevents effective lung ventilation during moderate- and high-speed locomot

51 ry pressure (PEEP) for the management of one-lung ventilation during thoracic surgery.

52 ruitment, lateral decubitus and differential lung ventilation enabled the titration of optimum-select

53 management and more interventions during one-lung ventilation for thoracic surgery to prevent periope

54 Liquid lung ventilation has been demonstrated to improve cardio

55 ing basal breathing, negative-pressure (iron-lung) ventilation, heliox breathing, and inspiratory res

56 is and machine-learning algorithm to predict lung ventilation heterogeneity in participants with COPD

57 nts with bronchopleural fistula, independent lung ventilation, high-flow ventilatory modes, physiolog

58 visualization and quantification of regional lung ventilation; however, these techniques require spec

59 perative assessment; (ii) techniques for one-lung ventilation; (iii) anesthetic implications of speci

60 ell negates the costal movements that effect lung ventilation in other air-breathing amniotes.

61 Purpose To quantify regional lung ventilation in patients with chronic obstructive pu

62 Common devices used to achieve one-lung ventilation in patients with difficult airways incl

63 One-lung ventilation in the thoracic surgical patient can be

64 Regional quantification of lung ventilation is indeed feasible and may be a useful

65 We hypothesized that liquid lung ventilation (LLV) would decrease the pulmonary infl

66 ruitment, lateral decubitus and differential lung ventilation may enable the titration and applicatio

67 entering the heart of air-breathing fishes, lung ventilation may supply the myocardium with oxygen a

68 Using a recently reported iron lung ventilation model, we sought to determine the stimu

69 in absolute and relative indications for one-lung ventilation (OLV) should be viewed as antiquated.

70 ans can consider lung isolation, independent lung ventilation, or extracorporeal membrane oxygenation

71 tion and high agreement between the relative lung ventilation percentages obtained using (133)Xe and

72 rrelation and agreement between the relative lung ventilation percentages obtained using these 2 radi

73 tomatic segmentation to extract the relative lung ventilation percentages.

74 Xe gas, functional lung images reporting on lung ventilation, perfusion and diffusion with 3D readou

75 ia and atelectasis as the consequence of one-lung ventilation, perhaps more importantly, also as part

76 It is also recognized that one-lung ventilation presents unique problems for the patien

77 Purpose To assess regional lung ventilation properties using (19)F MRI of inhaled p

78 strong positive correlation in the relative lung ventilation quantified using (133)Xe with that usin

79 e >=1 mg, albumin dissolvent, post-injection lung ventilation, radiologically solid nodules, and anat

80 e imaging that provide measurement of distal lung ventilation reflecting small-airway disease.

81 Cardiopulmonary bypass without liquid lung ventilation resulted in a significant decrease in c

82 Full functional residual capacity liquid lung ventilation resulted in lower pulmonary vascular re

83 us non-invasive monitoring, have made single-lung ventilation safe and easy to perform.

84 Rationale: Open lung ventilation strategies have been recommended in pat

85 Data indicate that adoption of an open-lung ventilation strategy, characterized by sufficient p

86 re importantly, also as part of a protective lung-ventilation strategy to ameliorate mechanical stres

87 ly similar to the bilateral pattern used for lung ventilation, suggesting a new hypothesis that rib m

88 This leads to recon- structed images of lung ventilation that can easily be superimposed with st

89 res provide evidence that diaphragm-assisted lung ventilation was present in theropods and that these

90 Regional lung ventilation was quantified by using volume defect p

91 cause breath-stacking and loss of protective lung ventilation when triggering a second cycle.

92 ic stability during prolonged periods of one-lung ventilation, while optimizing conditions for intrao

93 The physiology and methods of single lung ventilation will be reviewed, including the use of

94 ata comparing the quantification of relative lung ventilation with (99m)Tc-Technegas with that perfor

95 visualization and quantification of regional lung ventilation with high spatial resolution.

96 Measurement of regional lung ventilation with hyperpolarized (129)Xe magnetic re