ライフサイエンスコーパス: video imaging

1 ntaneously beating myocytes were captured by video imaging.

2 metry with a carbon fibre microelectrode and video imaging.

3 ns and its dynamics can be captured fully by video imaging.

4 nity Ca(2+)-sensitive fluorescent probes and video imaging.

5 ythropoietin (Epo) was measured with digital video imaging.

6 nted and the shell-hash cover estimated from video imaging.

7 in intracellular calcium concentration using video imaging.

8 E clone 3, using fura-2 microfluorimetry and video imaging.

9 were measured with fura-2 based microscopic video imaging.

10 ntration ([Ca(i)]) was measured with digital video imaging.

11 secretion rate in CF specimens, measured by video imaging (4.5+/-0.5 nL/min/gland, n=6), was 2.7-fol

12 The image is then analyzed by the associated video imaging analysis software.

13 Both quantitative video imaging and a new photometric method were utilized

14 Time-lapse video imaging and morphological analyses revealed that a

15 tions, security, night-vision, biomedical or video-imaging and gas sensing, detection technologies pr

16 scent protein from pTracer-CMV using digital video imaging, and successful transfection of TRPC was c

17 Video imaging ( approximately 7500 pixels per frame; 240

18 Simultaneous video imaging (approximately 32x32 mm2) of Di-4-ANEPPS f

19 cemaker activity was recorded via high-speed video imaging at 36.5 degrees C +/- 0.5 degrees C.

20 n of the surgical field with high-resolution video imaging cameras such as the closed-coupled device

21 Time-lapse video imaging compiled from the optical screening images

22 We used a combination of high-resolution video imaging, ECG recordings, and spectral analysis to

23 Advancements in video imaging, endoscope technology, and instrumentation

24 alysis of optical signals was carried out in video imaging experiments using a potentiometric dye in

25 paper, we have used electron microscopy and video imaging fluorescence microscopy to investigate the

26 nts of cone photopigment regeneration with a video imaging fundus reflectometer to determine whether

27 High-speed video imaging has revealed that each current pulse corre

28 strin-releasing peptide were monitored using video imaging in a perfusion chamber.

29 it hearts were studied using high-resolution video imaging in conjunction with ECG recordings and spe

30 previously been implicated in cell adhesion, video imaging in vivo demonstrated that deletion of the

31 meter = 200 mum) fluorescence microscopy and video imaging inside the rodent brain at a depth of 2 mm

32 Cell volume was measured using a video-imaging method.

33 diffusivity of T. pyriformis, determined by video imaging microscopy, was found to exceed molecular

34 mate model was examined by computer-assisted video imaging microscopy.

35 Video imaging monitored fecal pellet evacuation from iso

36 PACAP effects on ECL cells were analyzed by video imaging of [Ca(2+)](i) and histamine release; its

37 ron) were studied using digital fluorescence video imaging of arterial diameter and wall [Ca2+], comb

38 died using simultaneous digital fluorescence video imaging of arterial diameter and wall [Ca2+], comb

39 Here we report the time-lapse video imaging of border cell migration, allowing us to t

40 oosmotic flow in plastic microchannels using video imaging of caged fluorescent dye after it has been

41 Video imaging of colonic wall movements or the selective

42 Live video imaging of Drosophila cardiac tubes revealed that

43 e-sensitive dye was used for high resolution video imaging of electrical waves on the epicardial and

44 Real-time video imaging of fluid droplets secreted from individual

45 optical system is described for simultaneous video imaging of fluorescein tear film breakup and the T

46 (i) was also evaluated by the use of digital video imaging of fura-2 loaded individual T cells.

47 Using digital video imaging of Fura2-AM loaded porcine airway smooth m

48 pendent morphological synaptic plasticity by video imaging of GFP-actin at individual synapses.

49 esolution confocal microscopy and two-photon video imaging of individual haematopoietic cells in the

50 imaging agents, we performed high-frame-rate video imaging of mice during intravenous injection of SW

51 High-resolution video imaging of near-defibrillation-threshold atrial sh

52 individual glands was measured by real-time video imaging of sweat droplet formation under oil.

53 ultaneous electrophysiological recording and video imaging of the cell-attached patch membrane reveal

54 lonic elongation might affect the CMMC using video imaging of the colon, tension and electrophysiolog

55 Our experiments involve high-speed video imaging of the granular stream in the co-moving fr

56 We demonstrate the microscope by video imaging of tubulin and kinesin dynamics in living

57 ring of NE with a diamond microelectrode and video imaging of vascular tone allow real time local mea

58 distal colon using mechanical recordings and video imaging of wall movements.

59 Real-time in vivo video imaging of whole mouse body and tumor vessels was

60 Determination of the curvature of patches by video imaging permitted measurements of the channel acti

61 Video imaging revealed that transit of fecal pellets was

62 Video imaging showed apparent boundaries to migration be

63 lters were quantified by photomicroscopy and video imaging software.

64 nduced in such an area, we used a high-speed video imaging system and a voltage-sensitive dye to quan

65 s quantified by means of a computer-assisted video imaging system.

66 ized arteries from rat were measured using a video-imaging system and conventional microelectrodes, r

67 A dual-camera video-imaging system was used for simultaneous optical r

68 Cell volume regulation was measured using a video-imaging technique.

69 e isolated rat pancreatic beta-cells using a video-imaging technique.

70 We used fluorescent video imaging techniques to study the origin and propaga

71 Fast, multiple-site optical recording and video imaging techniques were combined to visualize the

72 g voltage-sensitive dyes in combination with video-imaging techniques.

73 We used video imaging technology to study the sequence of activa

74 lls from the bullfrog saccule and high-speed video imaging to characterize this sliding adhesion.

75 We use a potentiometric dye and video imaging to record the dynamics of transmembrane po

76 We used video imaging to study the sequence of activation on the

77 We have used video imaging to study the sequence of activation on the

78 Whole cell fluorescent video imaging using rhodamine 123 (R123) was used to mon

79 Video imaging was used to determine the effects of colon

80 oietin modulation of calcium influx, digital video imaging was used to measure calcium influx through

81 In 6 isolated pig hearts, dual-camera video imaging was used to record optically from approxim

82 Using quantitative immunofluorescence and video imaging, we provide the first in vitro reconstitut

83 We used high-resolution video imaging with a fluorescent dye, ECG, frequency and

84 concentration ([Ca2+]i) was determined using video imaging with Fura-2 in a 37 degreesC superfusion c