ライフサイエンスコーパス: inner diameter

1 ive path length at 92% of the used capillary inner diameter.

2 rcing the sample through a silica capillary (inner diameter 150-180 microm) at speeds approaching 10

3 Hypertension reduced PA inner diameter (58+/-3 vs. 49+/-3 mum at 60 mmHg in WKY

4 ween a tubular protamine selective membrane (inner diameter, 600 mum) and a Ag/AgCl wire (diameter 40

5 scribed here uses a capillary of much larger inner diameter (75 microm) that has been packed with non

6 fone hollow fibers used, which have a 0.8-mm inner diameter, allow separation of as little as 20 mug

7 Smaller outer and inner diameters and heterogeneous lumen reflectivity wer

8 -orifice plate (137 nozzles of 55 mum in the inner diameter) and a rotating, silicone oil-coated Tefl

9 parameters such as stationary phase, column inner diameter, and column temperature were optimized fo

10 he appearance of a disk with outer diameter, inner diameter, and thickness of 148 +/- 10 A, 78 +/- 9

11 CNpNC pore dimensions (outer diameter 8 nm; inner diameter approximately 2.5 nm) are in the AFM rang

12 is fused silica; inlet and outlet capillary inner diameters are 50 microm to minimize sample dispers

13 of monolithic structures in capillaries with inner diameters as low as 5 microm while retaining the d

14 capillary liquid chromatography columns with inner diameters between 12 and 33 microns were slurry pa

15 of approximately 1000 for capillaries having inner diameters between 15 and 150 microm.

16 We examined straight tubes with inner diameters between 2.5 and 6 mm and shouldered (Col

17 loped utilizing electrophoresis in nanometer inner diameter capillaries and etched electrochemical de

18 ations have been achieved in 770- and 430-nm-inner diameter capillaries.

19 fL have been injected using these nanometer inner diameter capillaries.

20 on of a microinjector at the tip of a 770-nm-inner diameter capillary and the use of electroporation

21 hydrocarbon mixture on a commercial 150 mum inner diameter capillary column packed with 1.7 mum part

22 s injected and concentrated onto a 50-micron-inner diameter capillary column packed with 5-micron rev

23 ice, and a 150 mum outer diameter and 50 mum inner diameter capillary was placed in the well.

24 With the use of a 75 microm inner diameter column coupled to a quadrupole ion trap m

25 % lower than that of a straight tube with an inner diameter corresponding to the narrow part of the s

26 using a novel technique where channels with inner diameters down to 13 microm are integrated with el

27 approximately 10(3)) nanoscale (using column inner diameters down to 15 microm) liquid chromatography

28 orded using an array of four miniature (2-mm inner diameter) electron multipliers.

29 spiratory loading was achieved with a 2.0-mm inner diameter endotracheal tube in the breathing circui

30 in and 10 L/min, the resistances of the 6 mm inner diameter ETT were 3.1 H2O/L/sec and 4.6 cm H20/L/

31 pectively, and the resistances of the 2.5 mm inner diameter ETT were 81.2 H2O/L/sec and 139.4 cm H20/

32 have been prepared in capillaries ranging in inner diameter from 5 to 75 microm using thermally initi

33 A large pore, ranging in inner diameter from 6.0 nm to 8.8 nm, runs through the m

34 with sub-2 mum particles, covering capillary inner diameters from 10 to 75 mum.

35 appropriate for patient use (e.g., a 4.0 mm inner diameter, from 20.7 to 11.3 cm) reduced its resist

36 ,000 theoretical plates in a 60.2 cm, 25 mum inner diameter fused silica capillary.

37 s (S/N approximately 3, 60 muM with a 25 mum inner diameter fused-silica capillary) with good peak sy

38 oadings, decreasing the separation capillary inner diameter has an effect equivalent to increasing sa

39 ding nanometer-scale containers in which the inner diameter (i.d.) and surface chemistry can be syste

40 d for GC-TOFMS, specifically a 20 m, 100 mum inner diameter (i.d.) capillary column with a 0.4 mum fi

41 Using 1.5 microm inner diameter (i.d.) capillary columns, hydrodynamicall

42 6800 bar (100 000 psi) for packed 10-microm-inner diameter (i.d.) columns.

43 low rate from 0.2 to 2 microL/min and column inner diameter (i.d.) from 25 to 75 microm on the relati

44 lefin polymer (COP) capillary column with an inner diameter (i.d.) of 28 mum and using an on-capillar

45 pectrometry (MS) interface featuring a large inner diameter (i.d.) separation capillary, and a detach

46 spectrometer using a 4.5 in. long, 0.042 in. inner diameter (ID) stainless-steel capillary, was thus

47 pheric tumors ranging from 1.8 to 12.6 mm in inner diameter (ID), 6 micropipettes (0.7- or 1.1-mm ID

48 plitless mode on 30- or 60-m-length, 0.25 mm inner diameter (id), and 25 mum film thickness low-polar

49 illary (monoPLOT) columns of varying length, inner diameter (ID), and porous layer thickness.

50 ctor (MCR) consisting of 126 channels (8 mum inner diameter in all channels) that performed online di

51 f-assemble into oligomeric pores of 10-20 nm inner diameter in the membranes of virus-infected and ca

52 proportional to the square of the capillary inner diameter) in the flow range of 20-400 nL/min.

53 s by forming plugs of effluent from a 75 mum inner diameter LC column segmented by an immiscible oil

54 imentally validated in a microcapillary with inner diameter less than 100 microm.

55 re studied in isolated human bronchi with an inner diameter of 1 mm or less.

56 termined in a fused silica capillary with an inner diameter of 10mum and total length of 31.5cm in op

57 COP capillaries (inner diameter of 19-28 mum) were successfully sulfonate

58 MOF (SCU-8) containing channels with a large inner diameter of 2.2 nm and possessing a high surface a

59 which consists of 400 nozzles, each with an inner diameter of 2.5 microm and yielding flow rates of

60 of monolith material for a capillary with an inner diameter of 200 microm.

61 YopM monomers form a hollow cylinder with an inner diameter of 35 A.

62 sphere has an outer diameter of 120 A and an inner diameter of 65 A.

63 les to form double-walled nanotubes, with an inner diameter of 7 nm and outer diameter of 11 nm.

64 silica, or stainless steel tubing having an inner diameter of 75 or 125 microm.

65 ochemical measurements, we have measured the inner diameter of a lipid nanotube using Fick's first la

66 ic field decreases with the reduction of the inner diameter of a microcapillary, and the risetime als

67 l channel is funnel shaped, tapering from an inner diameter of about 30 angstroms at the wider end to

68 formed from a fine glass capillary, with an inner diameter of approximately 100 microm, to direct so

69 nfirmed that EspD formed a structure with an inner diameter of approximately 2.5 nm.

70 ene inside titanate nanotubes with a uniform inner diameter of approximately 5.3 nm.

71 By reducing the inner diameter of chromatography columns from 180 microm

72 ict size constraint to fit inside the 114-mm inner diameter of the BGA-12S gradient coil used in the

73 llary dimensions and how reducing length and inner diameter of the capillary is predicted to give fas

74 terminal region of nucleoprotein defines the inner diameter of the Ebola virus NC, whereas the RNA ge

75 The inner diameter of the ring electrode is fixed by the dia

76 Remarkably, the inner diameter of the T3SS apparatus requires that effec

77 ng solvents, 87-cm-length capillaries having inner diameters of 14.9-74.5 microm were successfully pa

78 nthesis of single-crystal GaN nanotubes with inner diameters of 30-200 nm and wall thicknesses of 5-5

79 Fused-silica capillaries with inner diameters of 33 microns and lengths of 25-50 cm ar

80 Only those tubes with inner diameters of 4 nanometers or more were filled, sug

81 formance limits of capillary IC columns with inner diameters of 400 mum packed with 4 and 7 mum macro

82 lti-walled carbon nanotube nanoreactors with inner diameters of 5-8 nm by a chemical vapor transport

83 Capillaries with inner diameters of 550 microm have successfully been pac

84 Paired observations were made of inner diameters of collateral and normal arteries in the

85 The inner diameters of the two most likely ring models are l

86 d by changing relative dimensions (length or inner diameter) of the coupled columns.

87 .5 and 6 mm and shouldered (Cole) tubes with inner diameter/outer diameter between 2.5/4 and 3.5/5 mm

88 - 5 vs. 54 +/- 4 mum in vehicle; P<0.05) and inner diameter (outward remodeling; 10.6 +/- 0.5 vs. 8.0

89 Capillaries of 25-micron inner diameter packed with base-resistant, polymer-based

90 a thin-walled fused silica capillary with an inner diameter ranging from a few tens to a few hundreds

91 was separated by gradient elution on 50-mum-inner diameter reversed-phase columns at 180 nL/min.

92 ic inlet, consisting of a 10 cm x 127 microm inner diameter stainless steel capillary tube which was

93 ophoresis has utilized an open tube of small inner diameter to reduce peak broadening caused by hydro

94 centric windmill patterns of 500-1200 micron inner diameter to suppress the response to a small spot

95 Droplets are able to slide through a 4 mm (inner diameter) tube with low sliding angles of less tha

96 chain of C60 molecules.With increasing BNNT inner diameter, unusual C60 stacking configurations are

97 ollagen endovascular stent-graft with a 4-mm inner diameter was deployed in the abdominal aorta in ni

98 Thirty tubes with a 3-mm inner diameter were internally coated with pulverized hu

99 Precolumns with suitable inner diameters were found useful for improving the elut

100 etween different columns (same and different inner diameters with different nanoESI emitters), and fo

101 loaded onto packed capillaries of 150-micron inner diameter without a significant loss of separation