ライフサイエンスコーパス: polarimetry

1 ds with high-precision time-domain terahertz polarimetry.

2 rified MBCHs then were determined by digital polarimetry.

3 age-related macular degeneration (AMD) using polarimetry.

4 al set-up for joint parameter estimation for polarimetry.

5 ted fibers were analyzed with Mueller matrix polarimetry.

6 ture, as judged by both NMR spectroscopy and polarimetry.

7 rovement in detecting earliest glaucoma with polarimetry.

8 the assessment of the RNFL by scanning laser polarimetry.

9 i through optical second harmonic generation polarimetry and in situ TEM electrical testing on single

10 ng scanning laser tomography, scanning laser polarimetry and optical coherence tomography offer more

11 l coherence tomography (OCT), scanning laser polarimetry, and confocal scanning laser ophthalmoscopy.

12 erve fiber layer observation, scanning laser polarimetry, and confocal scanning laser tomography may

13 Here, we introduce two-dimensional polarimetry as means of direct imaging of the valley pse

14 icient of variation 2%-2.9%), scanning laser polarimetry (coefficient of variation 2.6%-4.5%), and co

15 optical coherence tomography, scanning laser polarimetry, confocal scanning laser ophthalmoscopy, pup

16 orrelation between CPA measured with corneal polarimetry (CPA by P(IV) [fourth Purkinje image]) and S

17 iagnostic Technologies, Inc., San Diego, CA) polarimetry data and to evaluate the techniques' ability

18 tion angles are directly calculated from the polarimetry data obtained in a single scan, while other

19 pattern was analyzed by Fourier analysis of polarimetry data.

20 erties of compounds 2-4 were determined from polarimetry, electronic circular dichroism (ECD), and vi

21 , we demonstrate the potential of wide-field polarimetry for rapid inspection of opto-valleytronic de

22 measured by three techniques: scanning laser polarimetry (GDx ECC; Carl Zeiss Meditec, Dublin, CA), c

23 ds regression analysis (MRA), scanning laser polarimetry (GDx enhanced corneal compensation; Glaucoma

24 birefringence was measured by scanning laser polarimetry (GDx VCC; Carl Zeiss Meditec, Inc., Dublin,

25 g Laser Ophthalmoscopy (HRT), Scanning Laser Polarimetry (GDx) and Optical Coherence Tomography (OCT)

26 ng, Heidelberg, Germany), and scanning laser polarimetry (GDx-VCC; Carl Zeiss Meditec, Inc., Dublin,

27 Scanning laser polarimetry, Heidelberg retinal tomography and optical c

28 erature concerning the use of scanning laser polarimetry, Heidelberg retinal tomography and optical c

29 gment birefringence can be determined from a polarimetry image of the Henle fiber layer.

30 ngence of normal eyes were determined from a polarimetry image of the Henle fiber layer.

31 Each polarimetry image was compared with the corresponding au

32 otographs, were quantified in three types of polarimetry images: (1) a depolarized light image result

33 With this polarimetry imaging method, subretinal tissues such as t

34 FL retardance was measured by scanning laser polarimetry in 10-minute intervals for 30 minutes while

35 Using two-photon fluorescence polarimetry in giant unilamellar vesicles and in the pla

36 Here we report imaging circular polarimetry in the near-infrared and Monte Carlo modelli

37 In contrast to polarimetry, in which the polarization state of the exit

38 Polarimetry is a noninvasive method that uses polarised

39 ization phenomenon was investigated by laser polarimetry, mass-tagged pseudo-enantiomers in conjuncti

40 uced in a laboratory--over 340 megagauss--by polarimetry measurements of self-generated laser harmoni

41 times greater than those observed in optical polarimetry measurements, thus allowing picogram quantit

42 Here we report high-resolution imaging and polarimetry of those light echoes, which allow us to set

43 stimuli-responsive polymers, Mueller matrix polarimetry offers an important advantage requiring a fe

44 Two-dimensional NMR spectroscopy and polarimetry provided a deeper understanding of the under

45 X-ray polarimetry provides a unique diagnostic to study the lo

46 e RNFL in certain conditions, it lacks laser polarimetry's ability to detect microtubule changes.

47 opy, X-ray diffraction analysis, and optical polarimetry show that the spherulites are composed of he

48 L measurements acquired using scanning laser polarimetry (SLP) and optical coherence tomography (OCT)

49 ning laser tomography (CSLT), scanning laser polarimetry (SLP) and photographic imaging of the optic

50 s RNFL retardance measured by scanning laser polarimetry (SLP) and T is RNFL thickness measured by op

51 It was hypothesized that scanning laser polarimetry (SLP) compared with OCT might reveal the sta

52 is assumed, the conversion of scanning laser polarimetry (SLP) phase-retardation measurements to RNFL

53 Scanning laser polarimetry (SLP) results can be affected by an atypical

54 Scanning laser polarimetry (SLP) reveals abnormal retardance of birefri

55 ies for glaucoma detection of scanning laser polarimetry (SLP) with enhanced corneal compensation (GD

56 l coherence tomography (OCT), scanning laser polarimetry (SLP), and visual evoked potentials.

57 amine the association between scanning laser polarimetry (SLP), using enhanced (ECC) and variable cor

58 oherence tomography (OCT) and scanning laser polarimetry (SLP).

59 ixed compensation, as used in the commercial polarimetry system.

60 Here we use X-ray polarimetry to determine the resistivity of a sulphur-do

61 optical depolarization rate, allowing tissue polarimetry to guide DESI-MS analysis for rapid MS profi

62 Here we use time-resolved polarimetry to reveal critical nematic fluctuations in u

63 Using Mott polarimetry, we probed the spin degrees of freedom and d

64 Proton NMR spectroscopy and polarimetry were used to measure the rates of deuterium

65 rate a spectroscopic phenomenon, superchiral polarimetry, which can rapidly characterize ligand-induc

66 c disc stereophotographs, and scanning laser polarimetry with enhanced corneal compensation.

67 S, which is based on division-of-focal-plane polarimetry with four parallel linear polarization chann

68 ol participant also underwent scanning laser polarimetry with variable corneal compensation (GDx VCC)

69 The scanning laser polarimetry with variable corneal compensation (GDx VCC)

70 In scanning laser polarimetry with variable corneal compensation (SLP-VCC)