ライフサイエンスコーパス: inert gas

1 which reversibly loses NO on purging with an inert gas.

2 gas can also be measured using dilution with inert gas.

3 d by in-situ bubble formation from dissolved inert gas.

4 and the extent is similar between oxygen and inert gases.

5 tion triggered by exposures to high pressure inert gases.

6 nient to carry out without the protection of inert gases.

7 real-time analysis of several impurities in inert gases.

8 emperature without the special protection of inert gases.

9 nd thus, would be more favorable solvent for inert gases.

10 esthetized swine received an infusion of six inert gases.

11 idated by comparative measurements using the inert gas [11C]CH4 in four greyhounds.

12 ; P = 0.04), indicating partial excretion of inert gas across small pulmonary arteries.

13 tment of polymer substrates by a reactive or inert gas aiming at a specific surface functionalization

14 aqueous reaction mixture via purging with an inert gas, allowing for the preparation of pure chlorine

15 ly exposing epitaxial graphene to controlled inert gases and ambient humidity conditions, while measu

16 iltration, the filtrate is blown dry with an inert gas, and the dried porphyrinogen can be dissolved

17 treated sample exhibits high sensitivity to inert gases (Ar, N(2)), presenting a refractive index se

18 us solvents and liquid water in solvation of inert gases are not principally due to the hydrogen-bond

19 ertain, and it is unclear whether oxygen and inert gases are similarly affected.

20 nd closed through heat treatments in air and inert gas at various temperatures.

21 was monitored in the presence and absence of inert gases at normal and elevated pressures and under b

22 he reaction autoclave in a glovebox under an inert gas atmosphere is no longer necessary.

23 anotubes that are undergoing collisions with inert gas atoms or small molecules.

24 from the intact complex by colliding it into inert gas atoms such as argon or xenon.

25 re monitoring, next-generation imaging using inert gas-based magnetic resonance and other technologie

26 w index (indocyanine green), cardiac output (inert gas breathing), and systemic and leg vascular cond

27 ealed an association between swelling due to inert gas bubble nucleation and growth and radiation-ind

28 acuumised extraction cell, (3) holding in an inert gas buffer tank, (4) pasteurisation, (5) and refri

29 ed to less than 1 ppb from nitrogen or other inert gas by passing through an oxygen trap.

30 dily and only slowly desorbs under a flow of inert gas (complete desorption time~6 h).

31 Experimentally, inert gas condensation (IGC) is commonly employed to pre

32 ased vapor-phase synthesis methods including inert gas condensation, spark discharge generation, and

33 However, the multiple inert gas elimination technique (MIGET) shows insignific

34 gas exchange shunt measured by the multiple inert gas elimination technique (MIGET).

35 nation may be underestimated by the multiple inert gas elimination technique (MIGET).

36 tension, in random order, using the multiple inert gas elimination technique (MIGET).

37 Multiple inert gas elimination technique study showed that the tr

38 To test this we used the multiple inert gas elimination technique to study eight women and

39 gas exchange, the latter using the multiple inert gas elimination technique.

40 evaluated by blood gas analysis and multiple inert gas elimination technique.

41 smatching was analyzed by using the multiple inert gas elimination technique.

42 ution (VA/Q) was analyzed using the multiple inert gas elimination technique.

43 of VA and Q were determined by the multiple inert gas elimination technique.

44 onchoconstriction measured with the multiple inert gases elimination technique is frequently bimodal.

45 e black phosphorus channels passivated in an inert gas environment, without any prior exposure to air

46 tinum nanocrystals with clean surfaces in an inert gas environment.

47 Inert gas exchange in tissue has been almost exclusively

48 ly reversible and independent of the type of inert gas exposure.

49 ve been prepared from an aluminum flux under inert gas flow.

50 A simple, rapid extraction under inert gas followed promptly by LC-MS analysis minimized

51 Inert gas fusion (IGF) analysis provided data for the O,

52 he O, N, and H impurities were determined by inert gas fusion analysis.

53 es, from polymer AM to injection moulding to inert-gas heat treatment.

54 The inert gases helium and xenon are effective neuroprotecta

55 An auxiliary inert gas (hot N(2)) was used to enhance the drying proc

56 The partial pressure of a given inert gas in mixed-venous blood flowing back to the lung

57 ir underwater results in increased dissolved inert gas in tissues and organs.

58 s enables the in situ conversion of SF6 , an inert gas, into an active fluorinating species by using

59 based on the fact that when a pulsed flow of inert gas is introduced into the conjunction between a p

60 while for continuous cultures, He (or other inert gases) is used as an internal tracer to accurately

61 ow 1 atm) batch cultures, nitrogen (or other inert gases) is used to repressurize the system to 1 atm

62 econdary plasma generation from the injected inert gas, its radiative characteristics, and shielding

63 By measuring respiratory and inert gas levels in the proximal pulmonary artery (P), a

64 extremely reactive and need to be studied in inert gas matrices at ultralow temperatures (3-15 K).

65 served at low gas phase concentrations or in inert gas matrices.

66 cules have so far only been studied in solid inert gas matrices.

67 gy-ion-beam deposition into a (co-condensed) inert gas matrix and UV laser-induced visible-region pho

68 uss environmental effects of the solid-state inert-gas matrix on the reaction rate.

69 ere taken before (hemodynamics, blood gases, inert gas measurements) and 10 (hemodynamics, blood gase

70 od gases) and 20 (hemodynamics, blood gases, inert gas measurements) minutes after induction of ventr

71 cycle of protein activation is initiated by inert gas-mediated singlet O2 production.

72 to the co-gas N2, since substitution of the inert gas N2 by either Ar or He has no effect on measure

73 rees < theta < 127 degrees ; in contrast, an inert gas, N2, was nonwetting with a smaller range of co

74 n that also uses nitrogen, and for different inert gases, no significant effects upon performance are

75 t requiring the aid of additional catalysts, inert gas, or vacuum.

76 or spatial as well as temporal variations in inert gas partial pressure in tissue.

77 del does not allow for spatial variations in inert gas partial pressure.

78 ctivation of the ions via collisions with an inert gas produces isotopically derivatized fragment ion

79 er echocardiography, pulmonary blood flow by inert gas re-breathing, and vasoactive exchange via the

80 udy was to validate CO measurement using the inert gas rebreathing (IGR) method against other noninva

81 Inert-gas shielding could be an effective mechanism for

82 The scaled particle model of inert gas solubility in liquid water predicts cavity wor

83 omena of cavity formation and association of inert gas solutes.

84 nitric oxide, which is then entrained in an inert gas stream and detected, usually through chemilumi

85 ent distances that the clusters travel in an inert gas stream before they condense in a cooled collec

86 fficiently removed in the form of vapors via inert gas stream flowing through the PSE layer.

87 The lowest solubility inert gases, sulphur hexafluoride (SF(6) ) and ethane we

88 ary gas exchange in canines for O(2) and two inert gases, sulphur hexafluoride and ethane, by measuri

89 understanding of the effects of pressure and inert gas supersaturation on organ function and knowledg

90 gas exchange occurs to a greater extent for inert gases than for oxygen, shunt and its effects on ar

91 uid, droplets of the reaction mixture and an inert gas that maintains a uniform droplet spacing and s

92 nes, and gas lines for venting and supply of inert gas to the fuel tank ullage spaces.

93 ld not be used if an accurate calculation of inert gas transport to tissue is required.

94 ow efficiencies while requiring purging with inert gases, use of additives, and irradiation by high l

95 impulse oscillometry (IOS), multiple breath inert gas washout (MBW), body plethysmography, single-br

96 metry, body plethysmography, multiple-breath inert gas washout (with the tracer gas sulfur hexafluori

97 The multiple-breath inert gas washout parameter acinar ventilation heterogen

98 y control subjects performed multiple-breath inert gas washout, plethysmography, and spirometry.

99 ith EDTA/NaCl/Tris buffer, and spraying with inert gases, were used to reduce the nonspecific adsorpt

100 tion assumes that the partial pressure of an inert gas (which is proportional to the content of that

101 em is a RI sensitive platform able to detect inert gases, which can be more sensitive to detect nonin

102 emove nitrogen and water and fill it with an inert gas with a substantially lower proton affinity.

103 The "inert" gas xenon has been shown to be an effective neuro