ライフサイエンスコーパス: hypoxemic respiratory failure

1 s usual care in adults with covid-19 related hypoxemic respiratory failure.

2 ients with coronavirus diseases 2019-related hypoxemic respiratory failure.

3 istress syndrome on day 1 and day 2 of acute hypoxemic respiratory failure.

4 (n = 51, 82%) was the main etiology of acute hypoxemic respiratory failure.

5 tients were placed on VV ECMO for refractory hypoxemic respiratory failure.

6 -aged patients and is associated with severe hypoxemic respiratory failure.

7 d conditions and presented with acute severe hypoxemic respiratory failure.

8 Mechanical ventilation was begun for hypoxemic respiratory failure.

9 al fibrosis with decreasing lung volumes and hypoxemic respiratory failure.

10 is established therapy for term infants with hypoxemic respiratory failure.

11 th high hospital mortality for patients with hypoxemic respiratory failure.

12 oxygen therapy alone in patients with acute hypoxemic respiratory failure.

13 aled nitric oxide in premature newborns with hypoxemic respiratory failure.

14 ailure patients, and 86% in 57 patients with hypoxemic respiratory failure.

15 d nitric oxide in the premature newborn with hypoxemic respiratory failure.

16 nt for intensive care in children with acute hypoxemic respiratory failure.

17 ane oxygenation in term neonates with severe hypoxemic respiratory failure.

18 n clinical outcome in neonatal patients with hypoxemic respiratory failure.

19 tric oxide (NO) in four patients with severe hypoxemic respiratory failure.

20 of ventilator support in children with acute hypoxemic respiratory failure.

21 years requiring hospital admission for acute hypoxemic respiratory failure.

22 pitalized adults with COVID-19-related acute hypoxemic respiratory failure.

23 is increasingly used in patients with acute hypoxemic respiratory failure.

24 drome (30.3% vs 8.6%; P = .004) or prolonged hypoxemic respiratory failure (39.4% vs 11.4%; P = .001)

25 All the patients were admitted for hypoxemic respiratory failure; 75% (18 patients) needed

26 lar monocyte and macrophage subsets in acute hypoxemic respiratory failure (AHRF) are poorly understo

27 ndard of care for patients with severe acute hypoxemic respiratory failure (AHRF) caused by COVID-19

28 arch into critically ill patients with acute hypoxemic respiratory failure (AHRF) is growing, how thi

29 extubation readiness in patients with acute hypoxemic respiratory failure (AHRF) may not reflect lun

30 isease-19 (COVID-19) pneumonia induced acute hypoxemic respiratory failure (AHRF), but predictors of

31 o improve oxygenation in children with acute hypoxemic respiratory failure (AHRF), but their roles in

32 s receiving this drug for treatment of acute hypoxemic respiratory failure (AHRF), in order to determ

33 Intubation is a common procedure in acute hypoxemic respiratory failure (AHRF), with minimal evide

34 outcomes of nonintubated patients with acute hypoxemic respiratory failure (AHRF).

35 d patients without hypercapnia who had acute hypoxemic respiratory failure and a ratio of the partial

36 r the treatment of large patients with acute hypoxemic respiratory failure and asymmetric lung diseas

37 MERS-CoV causes severe acute hypoxemic respiratory failure and considerable extrapulm

38 s recommended as initial treatment for acute hypoxemic respiratory failure and is widely applied in p

39 genation in near-term and term newborns with hypoxemic respiratory failure and persistent pulmonary h

40 support in near-term and term newborns with hypoxemic respiratory failure and persistent pulmonary h

41 brane oxygenation is needed in neonates with hypoxemic respiratory failure and pulmonary hypertension

42 severe end of this spectrum may present with hypoxemic respiratory failure and pulmonary infiltrates,

43 ng noninvasive ventilation for de novo acute hypoxemic respiratory failure, and a high expired tidal

44 sing for making advances in pneumonia, acute hypoxemic respiratory failure, and acute respiratory dis

45 nger, required assisted ventilation, and had hypoxemic respiratory failure as defined by an oxygenati

46 l of nonintubated patients with COVID-19 and hypoxemic respiratory failure, daily APP of 6 hours show

47 y reveals diffuse bilateral infiltrates, and hypoxemic respiratory failure develops despite appropria

48 apy in children aged 1 to 4 years with acute hypoxemic respiratory failure did not significantly redu

49 h-flow nasal cannula is widely used in acute hypoxemic respiratory failure due to coronavirus disease

50 sk of endotracheal intubation in adults with hypoxemic respiratory failure due to covid-19 but probab

51 espiratory support among patients with acute hypoxemic respiratory failure due to COVID-19 pneumonia.

52 Among patients with acute hypoxemic respiratory failure due to COVID-19, an initia

53 ompared with usual care in adults with acute hypoxemic respiratory failure due to COVID-19.

54 Among patients with hypoxemic respiratory failure following abdominal surger

55 was designed to include patients with acute hypoxemic respiratory failure from all causes.

56 In patients with acute hypoxemic respiratory failure from COVID-19, prone posit

57 who require mechanical ventilation for acute hypoxemic respiratory failure, further reduction in tida

58 bation.Conclusions: As compared with HFNC in hypoxemic respiratory failure, helmet NIV improves oxyge

59 in ABI patients, including among those with hypoxemic respiratory failure, highlighting potential op

60 ention groups for the COVID-19 patients with hypoxemic respiratory failure; however, more evidence is

61 g the efficiency of clinical trials in acute hypoxemic respiratory failure (HRF) depends on enrichmen

62 ng noninvasive ventilation for de novo acute hypoxemic respiratory failure (i.e., not due to exacerba

63 cillatory ventilation for treatment of acute hypoxemic respiratory failure in children with diffuse a

64 Acute hypoxemic respiratory failure in immunocompromised patie

65 xygen (HFNO) have been recommended for acute hypoxemic respiratory failure in patients with COVID-19.

66 Among adult patients with acute hypoxemic respiratory failure in the ICU, a lower oxygen

67 Patients with acute hypoxemic respiratory failure in the intensive care unit

68 e of high mortality rate among patients with hypoxemic respiratory failure in the intervention arm (8

69 onary diffusion capacity in ICU survivors of hypoxemic respiratory failure included in this one-year

70 In 217 children with acute hypoxemic respiratory failure, initial end-tidal alveola

71 hould be administered in patients with acute hypoxemic respiratory failure is debated.

72 Hypoxemic respiratory failure is one of the leading caus

73 annula (HFNC) therapy in patients with acute hypoxemic respiratory failure is to not delay intubation

74 common reasons for admission to the ICU were hypoxemic respiratory failure leading to mechanical vent

75 iratory failure patients (n = 95), and acute hypoxemic respiratory failure (n = 144).

76 Adult patients with acute hypoxemic respiratory failure (n = 320) due to suspected

77 s used ECLS for 100 adults with severe acute hypoxemic respiratory failure (n = 94): paO2/FiO2 ratio

78 n (NIV) are used for the management of acute hypoxemic respiratory failure.Objectives: Physiological

79 s receiving mechanical ventilation for acute hypoxemic respiratory failure, of a planned sample size

80 ng invasive mechanical ventilation for acute hypoxemic respiratory failure or after thoracic surgery

81 ot in patients with post-extubation failure, hypoxemic respiratory failure, or end-stage cancer.

82 acute respiratory infection had more severe hypoxemic respiratory failure (PaO2/FIO2: 106 [66, 160]

83 ad undergone abdominal surgery and developed hypoxemic respiratory failure (partial oxygen pressure <

84 Among patients with hypoxemic respiratory failure, PEEP remained significant

85 Although pediatric survivors of acute hypoxemic respiratory failure perceive neither a limitat

86 atients with COVID-19 and moderate to severe hypoxemic respiratory failure (ratio of partial pressure

87 admission to the intensive care unit due to hypoxemic respiratory failure requiring mechanical venti

88 e, nonintubated inpatients with COVID-19 and hypoxemic respiratory failure requiring oxygen supplemen

89 tions, was able to support the same level of hypoxemic respiratory failure secondary to acute lung in

90 c signature in children with pediatric acute hypoxemic respiratory failure. Seventy-four immunocompet

91 ents developed inspiratory stridor and acute hypoxemic respiratory failure shortly after the stent wa

92 als but in a higher percent of patients with hypoxemic respiratory failure than reported in these tri

93 stress syndrome (ARDS) is severe, noncardiac hypoxemic respiratory failure that carries a substantial

94 distress syndrome (ARDS) is a form of severe hypoxemic respiratory failure that is characterized by i

95 ALI is a syndrome of acute hypoxemic respiratory failure that is not primarily card

96 -Vt ventilation strategies in ARDS and acute hypoxemic respiratory failure, the posterior probability

97 Objectives: To measure, in patients with hypoxemic respiratory failure, the probability of invasi

98 Among patients with acute hypoxemic respiratory failure, the use of extracorporeal

99 judication in three cohorts of patients with hypoxemic respiratory failure (training, internal valida

100 In patients with nonhypercapnic acute hypoxemic respiratory failure, treatment with high-flow

101 lysis of trials of adult patients with acute hypoxemic respiratory failure, treatment with noninvasiv

102 cardiovascular conditions and intubation for hypoxemic respiratory failure were associated with a hig

103 Patients with acute hypoxemic respiratory failure were enrolled within 48 ho

104 age and within 72 h of intubation for acute hypoxemic respiratory failure, were enrolled.

105 e hospital mortality for patients with acute hypoxemic respiratory failure who failed NPPV was 64%.

106 on, pulmonary hypertension, and severe acute hypoxemic respiratory failure who underwent endotracheal

107 t of eosinophilic lung disease develop acute hypoxemic respiratory failure with a rapid response to t

108 ritical illness syndrome consisting of acute hypoxemic respiratory failure with bilateral pulmonary i

109 apy in children aged 1 to 4 years with acute hypoxemic respiratory failure without bronchiolitis is u