ライフサイエンスコーパス: ventilator-induced lung injury

1 osed as indicators, and possibly drivers, of ventilator-induced lung injury.

2 and NO may contribute to the development of ventilator-induced lung injury.

3 mmatory mediator release, suggesting reduced ventilator-induced lung injury.

4 ncrease CO2 removal and therefore may reduce ventilator-induced lung injury.

5 n, multiple system organ failure, and severe ventilator-induced lung injury.

6 alveolar instability can independently cause ventilator-induced lung injury.

7 he effects of increasing inspiratory time on ventilator-induced lung injury.

8 r vessels may be important in the genesis of ventilator-induced lung injury.

9 severe and more homogeneous distribution of ventilator-induced lung injury.

10 cessive inflammatory response, can result in ventilator-induced lung injury.

11 an IL-1beta-associated complication known as ventilator-induced lung injury.

12 te ventilatory requirements while minimizing ventilator-induced lung injury.

13 volvement of eCypA in the pathophysiology of ventilator-induced lung injury.

14 neity of ventilation, potentially mitigating ventilator-induced lung injury.

15 ributes to the mortality of patients through ventilator-induced lung injury.

16 ary biotrauma, which couldtherefore decrease ventilator-induced lung injury.

17 he physiologic prerequisites for controlling ventilator-induced lung injury.

18 ation strategies aimed at further minimizing ventilator-induced lung injury.

19 and minimize/abolish the harmful effects of ventilator-induced lung injury.

20 me and driving pressure, key determinants of ventilator-induced lung injury.

21 y observed in patients with ARDS by creating ventilator-induced lung injury.

22 ated whether fat feeding protected mice from ventilator-induced lung injury.

23 stress and strain are major determinants of ventilator-induced lung injury.

24 rve as potential biomarkers and mediators of ventilator-induced lung injury.

25 associated with disease-specific features of ventilator-induced lung injury.

26 nsequences of mechanical ventilation such as ventilator-induced lung injury.

27 tory process accompanying early experimental ventilator-induced lung injury.

28 ate acute lung injury by causing a secondary ventilator-induced lung injury.

29 ked OxPAPC protection from interleukin-6 and ventilator-induced lung injury.

30 d alveolar pressure that could contribute to ventilator-induced lung injury.

31 nimal and endothelial cell culture models of ventilator-induced lung injury.

32 reviously verified two-hit model of in vitro ventilator-induced lung injury.

33 ch plays a major role in the pathogenesis of ventilator-induced lung injury.

34 r function, and inflammation associated with ventilator-induced lung injury.

35 in lung mechanics and in the pathogenesis of ventilator-induced lung injury.

36 sion blocked OxPAPC-mediated protection from ventilator-induced lung injury.

37 odels of bleomycin-induced lung fibrosis and ventilator-induced lung injury.

38 repair by confocal microscopy in a model of ventilator-induced lung injury.

39 LT(1) receptor antagonist, largely prevented ventilator-induced lung injury.

40 s and accumulated in lungs from animals with ventilator-induced lung injury.

41 aluronan synthase 3, and was associated with ventilator-induced lung injury.

42 upregulated and contribute to lung edema in ventilator-induced lung injury.

43 expression and activity in a mouse model of ventilator-induced lung injury.

44 plays a role in the inflammatory response of ventilator-induced lung injury.

45 plasma biomarkers as a surrogate outcome for ventilator-induced lung injury.

46 lung injury in a large tidal volume model of ventilator-induced lung injury.

47 the oleic acid injury (0.67 of baseline) or ventilator-induced lung injury (0.79 of baseline) models

48 r the magnitude of blood flow contributes to ventilator-induced lung injury, 14 sets of isolated rabb

49 ompared before and after the introduction of ventilator-induced lung injury alert.

50 The role of sigh breaths in reducing ventilator-induced lung injury among trauma patients at

51 Seven piglets submitted to experimental ventilator-induced lung injury and five healthy controls

52 has led to advances in the understanding of ventilator-induced lung injury and in optimizing the sup

53 led to advances both in our understanding of ventilator-induced lung injury and in optimizing the sup

54 highlights strategies directed at minimizing ventilator-induced lung injury and other new adjunctive

55 including the trade-offs between minimizing ventilator-induced lung injury and the risks from strate

56 observed in vivo in the mouse 2-hit model of ventilator-induced lung injury and were linked to MT sta

57 However, concomitant ventilator-induced lung injury and/or other causes of ac

58 We report the evolution of severe ventilator-induced lung injury associated with lethal sy

59 ils into the lung is an important feature of ventilator-induced lung injury associated with pneumonia

60 EP levels may improve oxygenation and reduce ventilator-induced lung injury but may also cause circul

61 Volutrauma and atelectrauma promote ventilator-induced lung injury, but their relative contr

62 This may lead to ventilator-induced lung injury by altering or depleting

63 Mechanical ventilator strategies that limit ventilator-induced lung injury by avoiding hyperventilat

64 P permits unstable alveoli and may result in ventilator-induced lung injury despite improved oxygenat

65 rts, helping to advance understanding of how ventilator induced lung injury develops.

66 risk for respiratory distress, asynchronies, ventilator-induced lung injury, diaphragmatic injury, an

67 ventilation heterogeneity may contribute to ventilator-induced lung injury during high-frequency osc

68 The potential for ventilator-induced lung injury during high-frequency osc

69 gas exchange and afford lung protection from ventilator-induced lung injury during high-pressure mech

70 ion, the respiratory rate per se may promote ventilator-induced lung injury, dynamic hyperinflation,

71 re unique to the gastric injury, whereas the ventilator-induced lung injury group displayed a unique

72 Ventilator-induced lung injury has substantive impact on

73 In a classic model of ventilator-induced lung injury, high peak pressure (and

74 stigated the impact of two distinct forms of ventilator-induced lung injury, i.e., volutrauma and ate

75 imize or even abolish the harmful effects of ventilator-induced lung injury if used as an alternative

76 e intensity of lung perfusion contributes to ventilator- induced lung injury in this model.

77 mption of a high-fat diet protects mice from ventilator-induced lung injury in a manner independent o

78 Rationale: If the risk of ventilator-induced lung injury in acute respiratory dist

79 exchange, and reduced histologic evidence of ventilator-induced lung injury in an animal model.

80 y be a promising strategy for alleviation of ventilator-induced lung injury in critically ill patient

81 Pressures and volumes needed to induce ventilator-induced lung injury in healthy lungs are far

82 nd strain heterogeneity as local triggers of ventilator-induced lung injury in large-animal lungs sim

83 Hydrogen sulfide reduces ventilator-induced lung injury in mice.

84 strated a markedly dependent distribution of ventilator-induced lung injury in oleic acid-injured sup

85 rway pressure ventilation strategy mitigates ventilator-induced lung injury in patients with severe a

86 Fat-fed mice showed clear attenuation of ventilator-induced lung injury in terms of respiratory m

87 eatly from our previous sheep model of acute ventilator-induced lung injury in which sheep were venti

88 ad assessed interventions likely to decrease ventilator-induced lung injury, including low tidal volu

89 Ventilator-induced lung injury increases proinflammatory

90 riggered mechanism in the protection against ventilator-induced lung injury involves cyclooxygenase 2

91 Ventilator-induced lung injury is a crucial determinant

92 Ventilator-induced lung injury is a life-threatening com

93 The common denominator in most forms of ventilator-induced lung injury is an intense inflammator

94 eir relative contribution to inflammation in ventilator-induced lung injury is not well established.

95 It has been postulated that the mechanism of ventilator-induced lung injury is the result of heteroge

96 igned to 4 hours of ventilation of the left (ventilator-induced lung injury) lung with tidal volume o

97 Ventilator-induced lung injury may arise from heterogene

98 Ventilator-induced lung injury may be caused by overdist

99 We speculate that the mechanism of ventilator-induced lung injury may involve altered alveo

100 Ventilator-induced lung injury may occur in acute respir

101 of hydrogen sulfide were analyzed in a mouse ventilator-induced lung injury model in vivo as well as

102 RM caused a lasting increase of PaO2 in the ventilator-induced lung injury model, but in oleic acid

103 e by 5 mins post-RM in oleic acid injury and ventilator-induced lung injury models.

104 rs among RM methods in oleic acid injury and ventilator-induced lung injury models.

105 cute lung injury: oleic acid injury (n = 4); ventilator-induced lung injury (n = 4); and pneumonia (n

106 injury using lavage and harmful ventilation (ventilator-induced lung injury; n = 7).

107 y develop lung injury that is similar to the ventilator-induced lung injury observed in mechanically

108 nd poorly aerated regions was also higher in ventilator-induced lung injury piglets compared with con

109 oro-2-deoxy-D-glucose uptakes were higher in ventilator-induced lung injury piglets compared with con

110 effects of placental dysfunction, hyperoxia, ventilator-induced lung injury, poor nutrition, abnormal

111 limit or reverse a potentially accelerating ventilator-induced lung injury process.

112 e in children have been targeted at reducing ventilator-induced lung injury, providing treatment adju

113 Ventilator-induced lung injury, pulmonary hypoplasia, an

114 Ventilator-induced lung injury remains a key contributor

115 (ALI) associated with sepsis and iatrogenic ventilator-induced lung injury resulting from mechanical

116 Moreover, studies of ventilator-induced lung injury revealed induction of the

117 Ventilator-induced lung injury risk was compared before

118 e as a direct and easily measured marker for ventilator-induced lung injury risk.

119 n, is associated with known risk factors for ventilator-induced lung injury such as ventilation with

120 use circulatory depression and contribute to ventilator-induced lung injury through alveolar overdist

121 higher [F]fluorodeoxyglucose uptake rate in ventilator-induced lung injury versus control lung (0.01

122 y intervention, which can lead to unintended ventilator induced lung injuries (VILI).

123 c blast (125 kPa) but prior to initiation of ventilator-induced lung injury (VILI) (4 h).

124 ts, but the systemic effects associated with ventilator-induced lung injury (VILI) are unexplored.

125 p44/42 MAPK activation in a murine model of ventilator-induced lung injury (VILI) correlated with in

126 To understand ventilator-induced lung injury (VILI) during positive pr

127 Furthermore, how to minimize ventilator-induced lung injury (VILI) for any given lung

128 We examined the role of TH metabolism during ventilator-induced lung injury (VILI) in mice.

129 hether hypercapnic acidosis protects against ventilator-induced lung injury (VILI) in vivo, we subjec

130 Ventilator-induced lung injury (VILI) is a major cause o

131 Ventilator-induced lung injury (VILI) is a major complic

132 Ventilator-induced lung injury (VILI) is a major complic

133 Ventilator-induced lung injury (VILI) is characterized b

134 Ventilator-induced lung injury (VILI) is currently ascri

135 The onset of ventilator-induced lung injury (VILI) is linked to a num

136 However, MV causes ventilator-induced lung injury (VILI), a condition chara

137 ophil- and platelet-dependent mouse model of ventilator-induced lung injury (VILI), NETs were found i

138 However, this can lead to ventilator-induced lung injury (VILI), which contributes

139 ey factors shown experimentally to influence ventilator-induced lung injury (VILI).

140 Pretreatment with KGF attenuated ventilator-induced lung injury (VILI).

141 power is a crucial concept in understanding ventilator-induced lung injury (VILI).

142 entilation (MV) is life-saving but may evoke ventilator-induced lung injury (VILI).

143 ignal modification during the development of ventilator-induced lung injury (VILI).

144 However, MV can also cause ventilator-induced lung injury (VILI).

145 monitoring of compliance are used to prevent ventilator-induced lung injury (VILI).

146 njure the lung, producing an entity known as ventilator-induced lung injury (VILI).

147 -inflammatory protection in rodent models of ventilator-induced lung injury (VILI).

148 eased pulmonary edema and inflammation after ventilator-induced lung injury (VILI).

149 This "ventilator-induced lung injury vortex" of the shrinking

150 Ventilator-induced lung injury was assessed by gravimetr

151 An in vivo rabbit model of ventilator-induced lung injury was used in which a recru

152 of ventilator care and decrease the risk of ventilator-induced lung injury, we designed and tested a

153 ts alveolar barrier disruption in a model of ventilator-induced lung injury, we examined alveolar bar

154 ONALE: In the original 1974 in vivo study of ventilator-induced lung injury, Webb and Tierney reporte

155 nfirm that unstable alveoli are subjected to ventilator-induced lung injury whereas stable alveoli ar

156 hanically ventilated patients is the risk of ventilator-induced lung injury, which is partially preve

157 Prevention of ventilator-induced lung injury while accomplishing the e

158 nfirm that unstable alveoli are subjected to ventilator-induced lung injury while stable alveoli are

159 rotective strategy, which aims at minimizing ventilator-induced lung injury (with low Vt/high positiv