ライフサイエンスコーパス: fluorometer

1 as a more expensive ( approximately $30,000) fluorometer.

2 with C8-SCX, C18, and HLB coatings with our fluorometer.

3 ens transmission was measured with an ocular fluorometer.

4 for factor Xa were realized with a scanning fluorometer.

5 orescence was measured using a 96-well plate fluorometer.

6 se of AMC was monitored continuously using a fluorometer.

7 ned in a two-channel semiautomated titrating fluorometer.

8 microscope was adapted for use as a clinical fluorometer.

9 A at concentrations of 10 pM with a standard fluorometer.

10 assay of solubilized product in a multiwell fluorometer.

11 rol of 2% Na-fluorescein with a CytoFluor II fluorometer.

12 d from 3 mL of plasma and quantified using a fluorometer.

13 tinocytes was quantitatively measured with a fluorometer.

14 et DNA and can be detected with an automated fluorometer.

15 by a laboratory-constructed argon ion laser fluorometer.

16 by a maxi Imaging-Pulse-Amplitude-Modulation fluorometer.

17 2)S, with a limit of detection of 54 nM in a fluorometer.

18 , and the rate of change is observed via the fluorometer.

19 d RNA is detected by a sensitive and compact fluorometer.

20 les down to 1.4 mM (10 ppm) using a portable fluorometer.

21 s been verified off-chip by using a standard fluorometer.

22 ical fibers are read-out via a compact phase-fluorometer.

23 both fractions of IIbIIIa were heated in the fluorometer a sigmoidal transition was observed in the r

24 ate without requiring a spectrophotometer or fluorometer, a flow reactor with a redox-responsive need

25 ecays acquired with a standard time-resolved fluorometer, a substantial simplification compared to th

26 PCR workstation with UV sterilization, a DNA fluorometer and a microfluidic electrophoresis system.

27 roscale measurements made with a traditional fluorometer and are 1 order of magnitude larger than val

28 zol)-6'-hydroxybenzothiazole phosphate and a fluorometer, and applied the method to quantitation of C

29 ermeability (P(dc)) was measured by scanning fluorometer at an afternoon (PM) baseline session and ag

30 a spectrofluorometer and a portable handheld fluorometer, but also responded substantially to BoNT A,

31 es performed a reference material (RM)-based fluorometer calibration with commercially available spec

32 The eight-channel fluorometer enables parallel testing of multiple samples

33 le cartridge and a sensitive custom designed fluorometer, enabling compact and simple ASFV detection,

34 luorescently at Ex553 nm/Em570 nm by using a fluorometer equipped with a 50-muL flow through cuvette.

35 ate of Eu3+, measurable with a time-resolved fluorometer even without the aid of enhancement solution

36 of as little as 1.0 ng/ml RNA in a standard fluorometer, filter fluorometer, or fluorescence micropl

37 s assay of enzymatic activity using standard fluorometers, filter fluorometers, or fluorescence micro

38 utomatic cigarette smoke machine fiber-optic fluorometer for real-time monitoring of the reaction pro

39 s depends on the sample emission anisotropy, fluorometer geometry, and optical apertures.

40 m featuring microfluidics and a multichannel fluorometer has been developed.

41 f instruments, such as pulsed emission decay fluorometers, is easily incorporated into the fitted mod

42 of detection was found to be 1 fg/ul by both fluorometer measurement and visual reading.

43 and non-invasively with a custom-built phase fluorometer measurement module.

44 d to the nominal concentration inferred from fluorometer measurements (linear regression slope = 0.98

45 gical responses using a pair of custom-built fluorometers measuring chlorophyll-a variable fluorescen

46 al, multiharmonic Fourier transform lifetime fluorometer (MHF).

47 could easily be visualized using a portable fluorometer or under blue light.

48 ng/ml RNA in a standard fluorometer, filter fluorometer, or fluorescence microplate reader-surpassin

49 activity using standard fluorometers, filter fluorometers, or fluorescence microplate readers using e

50 GFP, imaged by the CCD camera (R(2)=0.85) or fluorometer (R(2)=0.86).

51 nce microscope or in cell suspension using a fluorometer reveal that the roGFP1 probe is in dynamic e

52 tal effects, we constructed a scanning laser fluorometer that can measure both snapshot and finish-li

53 measures chlorophyll a fluorescence using a fluorometer that employes pulsed amplitude modulation (P

54 ed SPME method and a prototype of a portable fluorometer that is capable of quickly quantifying conce

55 es and rate measurements in the stopped flow fluorometer to investigate the possibility that hydratio

56 ddition of CO(2)/HCO(3)(-) in a stopped-flow fluorometer using 2',7'-bis-(2-carboxyethyl)-5-(and -6)-

57 m was evaluated and compared to a commercial fluorometer using photomultiplier detection for detectin

58 a comparable performance of the multichannel fluorometer vis-a-vis the conventional plate reader.

59 A scanning ocular fluorometer was designed to excite phosphorescence with

60 easurement from a pulse amplitude modulation fluorometer, was the best leaf fluorescence parameter to

61 In situ fluorometers were deployed during the Deepwater Horizon

62 )=0.90 between the low cost CCD camera and a fluorometer, which costs 100 times more than a CCD camer