ライフサイエンスコーパス: evanescent field

1 within 100 nm of the plasma membrane (in the evanescent field).

2 in push and twist a probe Mie particle in an evanescent field.

3 resence of the gold nanoparticles within the evanescent field.

4 en the sample surface and the UME within the evanescent field.

5 both electric and magnetic components of the evanescent field.

6 e rate of diffusion through the depth of the evanescent field.

7 e to the enhanced intensity of the resonance evanescent field.

8 diffusion coefficient, and the depth of the evanescent field.

9 ample surface, we observe a maximum of these evanescent fields.

10 cting with the external medium through their evanescent fields.

11 l calculations it is also predicted that the evanescent field above the nickel films penetrates deepe

12 des serve as optical transducer for tailored evanescent field absorption analysis.

13 spectroscopy for simultaneous spectroscopic evanescent field absorption and scanning probe measureme

14 concept, the detection of acetone in D2O via evanescent field absorption is demonstrated achieving a

15 Evanescent field absorption measurements indicate a sign

16 s for plasma membranes were investigated via evanescent field absorption spectroscopy of a model anal

17 nts of oil in water using mid-infrared (MIR) evanescent field absorption spectroscopy via fiberoptic

18 taxy (MBE) as waveguide enabling sensing via evanescent field absorption spectroscopy, as demonstrate

19 duced processes at IR waveguide surfaces via evanescent field absorption spectroscopy.

20 elated bulk spectral changes by mid-infrared evanescent field absorption spectroscopy.

21 for liquid-phase chemical sensing utilizing evanescent field absorption spectroscopy.

22 e constant and rate of diffusion through the evanescent field agree with previous results, and all me

23 romolecule such as DNA can extend beyond the evanescent field and analyte interaction results in a la

24 Using alternating evanescent field and epifluorescence illumination, we sh

25 ulates both the accumulation of GLUT4 in the evanescent field and the fraction of this GLUT4 that is

26 obe as an overlap integral of the nanowire's evanescent field and the probe's response function.

27 , it is possible to confine even further the evanescent field, and by varying the angle of incidence,

28 f the two chemical species, the depth of the evanescent field, and the size of the observed area on t

29 ear surface region of a sensor area with the evanescent field, any change of the refractive index of

30 in which a bright flash of strongly decaying evanescent field ( approximately 64 nm exponential decay

31 solated molecules excited either through the evanescent field at the quartz-liquid interface or as a

32 his work demonstrates the feasibility of new evanescent field-based biosensors that can specifically

33 Evanescent field-based fluorescence detection enabled mo

34 ogenerated ferricyanide within the resulting evanescent field, beyond the optical interface, was dete

35 static, moving vertically in and out of the evanescent field but with little lateral motion.

36 in solution diffuse through the depth of the evanescent field, but do not bind to the surface of inte

37 d is illustrated for the example of infrared evanescent field chemical sensors.

38 heres containing gold nanoparticles in their evanescent field combine the light guiding properties of

39 iented membrane probe excited by a polarized evanescent field created by total internal reflection (T

40 ments demonstrated that diffusion out of the evanescent field determined the track lifetimes.

41 spectrum within the penetration depth of the evanescent field due to displacement of water molecules

42 e fluorophore was excited directly or by the evanescent field due to the surface plasmon resonance.

43 interrogating oil-in-water emulsions via the evanescent field emanating from the waveguide surface, a

44 ybridization assay sensor that relies on the evanescent field excitation of fluorescence from surface

45 With total internal reflection fluorescence, evanescent field excitation, supercritical angle fluores

46 The WGM has an evanescent field extending into the capillary core and r

47 The evanescent field extends into the core and is sensitive

48 single, FM1-43-stained synaptic vesicles by evanescent field fluorescence microscopy, and tracked th

49 h high temporal and spatial resolution using evanescent field fluorescence microscopy.

50 s(3,4)P(2)/PtdIns(3,4,5)P(3), as measured by evanescent field fluorescence microscopy.

51 abeling experiments and when visualized with evanescent-field fluorescence microscopy.

52 ly developed magnetically assisted transport evanescent field fluoroassays (MATEFFs), takes advantage

53 IA approach, Magnetically-Assisted Transport Evanescent Field Fluoroimmunoassays (MATEFFs), which see

54 s involved granules that were present in the evanescent field for at least 12 s.

55 s involved granules that were present in the evanescent field for no more than 0.3 s, indicating that

56 y-coated membranes were illuminated with the evanescent field from a totally internally reflected las

57 In this method, the evanescent field from an internally reflected excitation

58 E penetrates into the exponentially decaying evanescent field in close vicinity (a few micrometer) to

59 The decay of evanescent field intensity beyond a dielectric interface

60 le angles, and corrected for angle-dependent evanescent field intensity using "reference" images acqu

61 tes using total internal reflection where an evanescent field interacts with bound antibody immobiliz

62 opy experiments the penetration depth of the evanescent field into the stratum corneum is comparable

63 The evanescent field is made accessible through the use of a

64 erformed at the SPR sensor surface where the evanescent field is the strongest.

65 An evanescent field is used to excite cleaved AMC and the r

66 single-molecule level by imaging within the evanescent field layer using total internal reflection f

67 erfaces were monitored by imaging within the evanescent field layer using total internal reflection f

68 t various pHs and ionic strengths within the evanescent-field layer (EFL) at a water/fused-silica int

69 nic strengths within the 180-nanometer-thick evanescent-field layer at a fused-silica surface.

70 wide range of incident angles with different evanescent-field layer thicknesses, the fluorescence int

71 wide range of incident angles with different evanescent-field layer thicknesses, the fluorescence int

72 te interface can be fluorescently excited by evanescent field light polarized either perpendicular or

73 r beam epitaxy for use in mid-infrared (MIR) evanescent field liquid sensing.

74 Evanescent field microscopy has shown that, during exocy

75 We have used evanescent field microscopy to image Annexin 2-GFP in li

76 Using two-color evanescent field microscopy, we imaged the lipid probe F

77 single granules in live cells were imaged by evanescent field microscopy.

78 The cell surface was imaged by evanescent field microscopy.

79 proteins in different colors, and two-color evanescent-field microscopy was used to view single gran

80 ough quantitative analysis and modeling that evanescent fields must be precisely matched between FRET

81 In order to exploit the whole evanescent field of BSW, extended three-dimensional hydr

82 e to a change of its average position in the evanescent field of excitation and can be associated wit

83 anoscale object that subsequently enters the evanescent field of the cavity perturbs the system from

84 eled biological complexes are excited by the evanescent field of the guided light.

85 s formed at the antinodes of a standing-wave evanescent field on a nanophotonic waveguide.

86 e-, orientation-, and polarization-dependent evanescent fields on the surfaces of A431 cancer cells a

87 recovery, bleach time, bleach intensity, and evanescent field penetration depth; the model included i

88 f plasmon waves in biological samples, these evanescent fields reflect the changes in EGFR kinase dom

89 300-nm region measurably illuminated by the evanescent field resulting from total internal reflectio

90 biosensors are advantageous combinations of evanescent field sensing and optical phase difference me

91 range reveal a substantial potential of MIR evanescent field sensing devices for on-line in situ env

92 he polymer coating is performed by utilizing evanescent field spectroscopy in the fingerprint range (

93 ses optical gradient forces generated in the evanescent field surrounding hybrid photonic-plasmonic s

94 zing the enhanced sensitivity of superchiral evanescent fields to mesoscale chiral structure.

95 IR) detector elements-serving as on-chip MIR evanescent field transducers in combination with tunable

96 single atoms falling through the resonator's evanescent field, we determine the coherent coupling rat

97 senting BCECF translational diffusion in the evanescent field, were in the range 2.2-4.8 ms (0.2-1 ms

98 y and tracked them in three dimensions in an evanescent field where the nanoparticles appeared bright

99 Here we demonstrate a superlens for electric evanescent fields with low losses using perovskites in t

100 eviously derived models for diffusion in the evanescent field within the nanostructure, the diffusion