ライフサイエンスコーパス: microcapillary

1 erimental cell and sap in the pressure probe microcapillary.

2 reases from the wall to the axis for a given microcapillary.

3 from the ambient and can move in constricted microcapillary.

4 ssure cell consists of a single fused silica microcapillary.

5 morphology and a volumetric perfusion map of microcapillaries.

6 Tear samples were collected in 5-microL microcapillaries.

7 mitive capillary plexus into large and small microcapillaries.

8 Here we experimentally demonstrate that a microcapillary acting as a thermal diffusion column can

9 lting in the formation of vascular tubes and microcapillary anastomoses.

10 nzyme highly expressed on the plasma face of microcapillaries and especially strongly expressed in th

11 moscopy can visualize live perfusion through microcapillaries and structural changes at the level of

12 ctra are recorded from the liquid inside the microcapillary and are evaluated with respect to the tem

13 , SML-FSHS required only a bare fused silica microcapillary and simple pressure control rather than c

14 apitate-stalked glandular trichomes by glass microcapillaries, and inflorescence samples air-dried fo

15 cysts initiated in the proximity of damaged microcapillaries, and the absence of an inflammatory res

16 Flies feed on liquid food from a microcapillary, and consumption is measured by tracking

17 ith the reduction of the inner diameter of a microcapillary, and the risetime also increases from the

18 on-nanotube-coated glass fiber embedded in a microcapillary are assembled and characterized.

19 Here, we characterize a glass microcapillary-based injection system and demonstrate co

20 sion by enhancing yeast sequestration within microcapillary beds (such as within the brain) during he

21 cally split solvent-gradient flows into four microcapillary C18 columns.

22 te single-crystal scintillators grown inside microcapillary channels as small as 20 um.

23 ched in astrocyte foot-processes adjacent to microcapillaries; clusters in perivascular regions of th

24 passing a large volume of sample through the microcapillaries coated with capture antibody.

25 QP5 on sweat secretion rate was confirmed by microcapillary collections of sweat from defined regions

26 erface revolves around the use of a fritless microcapillary column and precolumn application of elect

27 d blood cell to flow through extremely small microcapillaries depends on the viscoelastic properties

28 Using a microcapillary device, we fabricated double emulsions th

29 lects the blood via four integrated 2.74 muL microcapillaries, each depositing the blood on a prepunc

30 were evaluated: ultraviolet (UV) absorbance, microcapillary electrophoresis (MCE), and fluorescence-b

31 Planar microcapillary electrophoresis (microCE) devices were fa

32 PMMA microcapillary electrophoresis (muCE) devices made with

33 thermore, we introduced the applicability of microcapillary electrophoresis for high-throughput (<1.5

34 sis system, a high-throughput, multichannel, microcapillary electrophoresis instrument.

35 Current research on microcapillary electrophoresis materials is focused on t

36 th the use of several internal standards and microcapillary electrophoresis of input RNA, two rounds

37 o hTfR expressing cell lines and human brain microcapillary endothelia expressing high levels of endo

38 We hypothesize that transduction of brain microcapillary endothelium (BME) with recombinant viral

39 A novel thermocycling machine based on a microcapillary equipped with bidirectional pressure-driv

40 g high and low speed cosedimentation assays, microcapillary falling ball viscometry, and electron mic

41 and a miniaturised immunoassay platform, the Microcapillary Film (MCF).

42 cterization of optical heating in controlled microcapillary flow, verified by computational fluid dyn

43 Furthermore, when developed in a microcapillary format, this assay is capable of screenin

44 ion of a multiphase microfluidic system to a microcapillary gel electrophoresis (muCGE) architecture

45 Sodium dodecyl sulfate microcapillary gel electrophoresis (SDS micro-CGE) and m

46 from the affinity columns were identified by microcapillary high pressure liquid chromatography tande

47 ed, and phosphorylation sites were mapped by microcapillary high-pressure liquid chromatography tande

48 de sequence analysis has been achieved using microcapillary HPLC columns, with integrated nanoelectro

49 a of the respective peptides are acquired by microcapillary HPLC on an LTQ-orbitrap mass spectrometer

50 ntial reverse-phase HPLC and sequenced using microcapillary HPLC-triple quadruple mass spectrometry.

51 Microcapillary hydrodynamic chromatography (MHDC) is a w

52 usively on endothelial cells of newly formed microcapillaries in the media, whereas microvessels in t

53 mast cell-derived membrane patches decorate microcapillaries in the nasal mucosa of allergic rhiniti

54 Microcapillary injector geometries are being designed to

55 ad, pressure-driven flow from a fluid-filled microcapillary into a lower ionic strength DNA sample re

56 isms of cancer cell extravasation from brain microcapillaries is limited as the underlying cellular a

57 blood vessels with vascular integrity at the microcapillary level that enhances the recruitment hemat

58 graphy, quantifying retinal perfusion at the microcapillary level.

59 cation within complex biological mixtures by microcapillary liquid chromatography and linear ion trap

60 The recovered peptides were analyzed by microcapillary liquid chromatography and tandem mass spe

61 We have developed a novel four-plexed microcapillary liquid chromatography system for automate

62 Using nanoscale microcapillary liquid chromatography tandem mass spectro

63 We also developed a second robust microcapillary liquid chromatography-electrospray ioniza

64 t sensitivity of downstream mass analysis in microcapillary liquid chromatography-mass spectrometry (

65 e the sample introduction step for nanoscale microcapillary liquid chromatography-tandem mass spectro

66 Upon cancer cell arrest in brain microcapillaries, matrix-metalloprotease 9 (MMP9) was ex

67 sportation of these cells through the narrow microcapillary may squeeze and mechanically damage the c

68 crovascular network (AMVN) and a multiplexed microcapillary network (MMCN), and two commercially avai

69 y stromal cells to form complex anastomosing microcapillary networks in vitro on Engelbreth-Holm-Swar

70 herapeutic effect in an ex vivo model of the microcapillary networks.

71 dynamically induced fluid flows through fine microcapillary nozzles for jet printing of patterns and

72 hting the role of %HbF in protecting against microcapillary occlusion independent of other pharmacolo

73 ble red blood cells (RBCs) that are prone to microcapillary occlusion, causing tissue ischemia and or

74 en confined to pumping water across a single microcapillary or microfluidic channels.

75 gated islets were individually isolated in a microcapillary pipet, and the beta-cells were identified

76 rate that dynamic changes of activated brain microcapillaries promote the mandatory first steps of br

77 ell sap collected from S-cells using a glass microcapillary resulted in the release of glucose, indic

78 ctroscopy and amino acid analysis as well as microcapillary reverse phase chromatography electrospray

79 o Ni(2+)- nitrilotriacetic acid resin and by microcapillary reverse-phase high-performance liquid chr

80 Using microcapillary reverse-phase high-performance liquid chr

81 n-exchange chromatography and analyzed using microcapillary reversed-phase LC-MS/MS.

82 n of native and synthetic APF derivatives on microcapillary reversed-phase liquid chromatography (mic

83 g the elution of the labeled peptides from a microcapillary reversed-phase liquid chromatography colu

84 ured ratio of DeltaV/DeltaP (total change in microcapillary sap volume versus corresponding change in

85 critical fluids, are pumped through a heated microcapillary system at elevated pressures.

86 g tandem affinity purification and nanospray microcapillary tandem mass spectrometry.

87 volume limits the use of nonstimulated (NS) microcapillary tear collection in aqueous-deficient (AD)

88 We present a simple microcapillary technique able to generate such series of

89 nel that runs under the perfusion bath and a microcapillary that supplies fluid from this channel up

90 Using precision-translated fabricated microcapillaries, the subcellular content of each cell w

91 linker to magnetic beads that are trapped in microcapillaries to immobilize the target proteins.

92 imations in literature about the risetime in microcapillaries, to the best of our knowledge, this has

93 etime distribution radially in a cylindrical microcapillary tube.

94 e collected from both eyes with the use of a microcapillary tube.

95 tic endothelial cells were cultured in glass microcapillary tubes and examined during abrupt reductio

96 thylsiloxane) microchannels and borosilicate microcapillary tubes.

97 containing cell supernatant was sampled into microcapillaries using a dead volume-reduced world-to-ch

98 CR in volumes of the order of 10 nl in glass microcapillaries using a fluorescence energy transfer as

99 e risetime of electroosmotic flow (EOF) in a microcapillary using recently developed laser induced fl

100 liter volumes of oil entrapped in the tip of microcapillaries, which we call pico gauges.

101 has never been experimentally validated in a microcapillary with inner diameter less than 100 microm.