ライフサイエンスコーパス: insufflation

1 nd 157 (39.6%) varices grade II (>5 mm under insufflation).

2 Study 2 developed local AMR data with CO(2) insufflation.

3 raction is triggered by a passive mechanical insufflation.

4 mice to mucoid P. aeruginosa administered by insufflation.

5 rmined in anesthetized rats during abdominal insufflation.

6 lation by chest wall vibration with low flow insufflation.

7 entilation (ITPV); hybrid ITPV; tracheal gas insufflation; acute respiratory distress syndrome (ARDS)

8 Gastric insufflation allows rapid placement of feeding tubes int

9 not support the use of thoracoscopy with CO2 insufflation and conventional ventilation for the repair

10 ssure significantly increases with abdominal insufflation and correlates with laparoscopic insufflati

11 We used a paired t test to compare ICP with insufflation and desufflation.

12 orms that can be distinguished from baseline insufflation and normal peristaltic waves.

13 eak airway pressure was lower (p < .05) with insufflation and vibration than with mechanical ventilat

14 positive pressure ventilation with tracheal insufflation and with external high-frequency chest wall

15 ts: 130 (32.8%) varices grade I (<5 mm under insufflation) and 157 (39.6%) varices grade II (>5 mm un

16 he patient reported chest pain after gastric insufflation, and a second placement attempt was initial

17 aminations require full colonic preparation, insufflation, and data acquisition with the patient in t

18 ts with use of standard bowel cleansing, air insufflation, and helical scanning in supine and prone p

19 aration, stool and fluid tagging, mechanical insufflation, and multidetector-row CT scanners (with 16

20 ventilation, prone positioning, tracheal gas insufflation, and partial liquid ventilation.

21 With alfentanil fewer patients rated the insufflation as most burdensome aspect (56.1% vs. 18.6%;

22 DLT); a few centers use carbon dioxide (CO2) insufflation as part of their management to achieve maxi

23 25 mL/kg tidal volume); and tracheal oxygen insufflation at 0.15 L x kg(-1) x min(-1) delivered with

24 provides an example of volitional nasal drug insufflation by a non-human animal, a behavior canonical

25 inspiratory efforts start after the passive insufflation by mechanical breaths.

26 ntrations from 1.1% to 2.5% mouthward of the insufflation catheter tip.

27 ular acidification induced by peritoneal CO2 insufflation contributes to blunting of the local inflam

28 cs for inhalational treatment and intranasal insufflation delivery of CDPL-GW nanoprobe ameliorated a

29 a simple switch-off pushbutton to eliminate insufflations during swallows prevented swallowing-induc

30 ion, manually assisted cough, and mechanical insufflation-exsufflation.

31 the greatest increase occurs with mechanical insufflation-exsufflation.

32 d on CPAP and CPAP-TGI at 10 and 15 L/min of insufflation flow delivered through a reverse thrust cat

33 In addition we examined the effect that insufflation flow directed toward the mouth (reverse flo

34 Warm, humidified CO(2) insufflation for acute laparoscopic appendicectomy has n

35 m respiratory centers to periodic mechanical insufflations from the ventilator.

36 The impact of pneumoperitoneum and insufflation gases on the immune response is also review

37 n or laparoscopically using CO2 or helium as insufflation gases.

38 lly placed after two attempts in the gastric insufflation group compared with 18 of 25 in the control

39 ITPV, a form of tracheal gas insufflation, has been shown to decrease deadspace venti

40 ared with literature data and those of CO(2) insufflation in our hands.

41 emphysema when administered by intratracheal insufflation into hamsters.

42 The mean ICP increase with 15-mm Hg insufflation is 7.2 (95% CI, 5.4-9.1 [P < .001]) cm H(2)

43 Use of a thin rectal tube for insufflation is adequate.

44 Tracheal gas insufflation is capable of improving oxygenation and ven

45 Conventional CO(2) insufflation leads to desiccation-related peritoneal inf

46 In vitro studies showed that CO2 insufflation lowered tissue pH and peritoneal macrophage

47 nclude breath stacking, manual or mechanical insufflation, manually assisted cough, and mechanical in

48 The beneficial effects of tracheal gas insufflation may be tempered by the long-term effects of

49 During laparoscopic surgery, carbon dioxide insufflation may produce significant hemodynamic and ven

50 CO2 insufflation (n = 5) cut liver blood flow in half; liver

51 s produced in the control and rhAPC group by insufflation of 4 sets of 12 breaths of cotton smoke.

52 ion, a tracheotomy was performed followed by insufflation of 48 breaths of cotton smoke (<40 degrees

53 The insufflation of air within the oral vestibule helps in t

54 markg) was given intravenously 5 min before insufflation of cotton smoke.

55 positive pressure ventilation with tracheal insufflation of fresh gas (FIO2 of 0.4) flowing at 0.15

56 ted in both strains of mice by intratracheal insufflation of liposome-encapsulated dichloromethylene

57 cant AM depletion in either strain following insufflation of liposome-encapsulated phosphate-buffered

58 to 14.37 +/- 1.69 mug/mL (MCD) 30 min after insufflation of microparticles.

59 ith established anti-MPO autoimmunity, nasal insufflation of MPO409-428 as a therapeutic attenuated a

60 d E. coli after delays of 5 and 10 min after insufflation of organisms into spirometry tubing support

61 Immediately after insufflation of organisms, air withdrawn from the proxim

62 r samples after a delay of 5 or 10 min after insufflation of organisms.

63 traluminal views of the bladder mucosa after insufflation of room air.

64 was increased in inflammatory MNP following insufflation of Th-1 cytokines in vivo and that activity

65 T scanner with supine and prone positioning, insufflation of the colon with air or carbon dioxide, co

66 apacity for nasal tolerance induced by nasal insufflation of the immunodominant nephritogenic MPO pep

67 Prior to fundoplication, insufflation of the stomach resulted in an immediate lea

68 Baseline insufflation of warm humidified air increased ASF volume

69 he difference in maximum pain during colonic insufflation on an 11-point numeric rating scale.

70 l shunt placement to determine the effect of insufflation on ICP.

71 ased by 65% during vibration relative to the insufflation-only value.

72 After colonic air insufflation, patients underwent scanning in the supine

73 After air insufflation per rectum, supine and prone images were ob

74 e increase in ICP correlated with increasing insufflation pressure (P = .04).

75 thin 20% of baseline, and limiting abdominal insufflation pressure of carbon dioxide to 12-15 mmHg ar

76 Linear regression correlated insufflation pressure with ICP.

77 nsufflation and correlates with laparoscopic insufflation pressure.

78 Pain is common during colonic insufflation required for CT colonography.

79 e of sublobar airways to dry air at baseline insufflation resulted in stable measurements of ASF volu

80 rvested from the lungs of mice 4 h after LPS insufflation revealed that the induction of several gene

81 Tracheal gas insufflation (TGI) can be used in combination with press

82 Tracheal gas insufflation (TGI) decreases dead space (V D) and can be

83 Tracheal gas insufflation (TGI) has been recommended as an adjunct to

84 Tracheal gas insufflation (TGI) has been shown to be a useful adjunct

85 Although tracheal gas insufflation (TGI) has proved to be a useful adjunct to

86 during mechanical ventilation, tracheal gas insufflation (TGI) improves CO2 elimination, principally

87 The major benefit of tracheal gas insufflation (TGI) is an increase in CO2 elimination eff

88 d that selective application of tracheal gas insufflation (TGI) will recruit the injured lung without

89 Tracheal gas insufflation (TGI), an adjunctive ventilatory technique,

90 enhancement, gastric mucosal cleansing, and insufflation to achieve optimal mucosal visualization, i

91 To determine the effect of transtracheal insufflation (TTI) on obstructive sleep apnea (OSA), we

92 g was sealed, and stomach cannulated for gas insufflation using a barostat device.

93 ghtness of the repair, CO[Formula: see text] insufflation volume, and OSATS score.

94 Insufflation was maintained for 60 minutes and then the

95 right and proximal colon, study 2 with CO(2) insufflation was performed.

96 ntra-tracheal installation rather than nasal insufflation was used to deliver the plasmids.

97 When gastric insufflation was used, 23 of 25 feeding tubes were succe

98 f study 2, compared with local data of CO(2) insufflation, WE showed a significantly lower AMR in the

99 ing ICAM-1 expression) C57BL/6 mice by nasal insufflation weekly for 4 weeks.

100 Maximum pain scores during insufflation were lower with alfentanil as compared with

101 tterns and polysomnographic responses to air insufflation were studied as TTI was increased from 0 to

102 Usually, three balloon insufflations were performed for 20-45 seconds at 4-6 at

103 atory laryngeal narrowing against ventilator insufflations when inspiratory pressure is increased dur

104 s (as achieved with intravenous injection or insufflation), whereas the therapeutic effects are assoc

105 humidified (98% relative humidity) CO(2) gas insufflation, whereas control participants received stan

106 8 kg) underwent laparoscopic intra-abdominal insufflation with 14 mm Hg CO2 gas for 6 hours, followed

107 Nine patients underwent insufflation with carbon dioxide (CO(2)) at pressures ra

108 Tracheal gas insufflation with chest vibration supports gas exchange

109 oscopic bariatric surgery requires abdominal insufflation with CO2 and an increase in the intraabdomi

110 CT colonography were performed after colonic insufflation with room air.

111 ophageal pressure was lower (p < .05) during insufflation with vibration by 68.5% at baseline resista

112 lveolar hypoventilation that occurred during insufflation with vibration indicates impaired CO2 elimi

113 During insufflation with vibration, mild hypercapnia (PaCO2 58+