ライフサイエンスコーパス: optical resolution

1 sample, thereby circumventing the limits of optical resolution.

2 g an intracellular longitudinal modulus with optical resolution.

3 00 different proteins in individual cells at optical resolution.

4 patial structures smaller than the limits of optical resolution.

5 icron structures conveniently used to define optical resolution.

6 better than the expected diffraction-limited optical resolution.

7 ion imaging with a performance comparable to optical resolution.

8 o yield information on local structure below optical resolution.

9 ns of cellular structures with unprecedented optical resolutions.

10 ecific properties at sub-diffraction-limited optical resolutions.

11 ls to identified motor units imaged at lower optical resolution (40x, 1.3 NA).

12 mount embryos and reduces the limitations of optical resolution and noisy signals on single-molecule

13 t Ca indicators is limited by the microscope optical resolution and properties of the indicator.

14 But even in the near-infrared region, optical resolution and sensitivity decrease rapidly with

15 eir coimmunoprecipitation, colocalization at optical resolution, and markedly increased binding affin

16 r approximately 60 nm) did not cause loss of optical resolution, and they enhanced fluorescence appro

17 High optical resolution (approximately160 nm fwhm) was observ

18 By offering the distinct advantage of optical resolution but without the undesirable influence

19 urfaces are usually accompanied by a loss of optical resolution due to refraction of light by particl

20 ideal lithographic line-edge that separates optical resolution effects from materials processing eff

21 approach for obtaining subdiffraction limit optical resolution in all three dimensions.

22 tially large exposed silica sites beyond the optical resolution in C18 stationary phase.

23 letion microscopy, have set new standards of optical resolution in imaging living tissue.

24 t are smaller than or approximately equal to optical resolution in size.

25 een the dominant barrier to achieving higher optical resolution in the fields of microscopy, photolit

26 as developed that is not limited by standard optical resolution, in which a bright flash of strongly

27 intracellular protein structures beyond the optical resolution limit ('super-resolution' imaging) in

28 ver, phase domains are much smaller than the optical resolution limit, likely on the order of the For

29 -rich microdomains with dimensions below the optical resolution limit.

30 molecular motors are significantly below the optical-resolution limit.

31 itization of entire glass slides at near the optical resolution limits of light can occur in 60 s.

32 icroscopy/quantum dot system provided a best-optical-resolution (<50 nm) nano-scale imaging of Vgamma

33 dsorption sites are smaller in size than the optical resolution of a few hundred nanometers.

34 eaching are achieved without sacrificing the optical resolution of a microscope.

35 r cooling may be advantageous to improve the optical resolution of channel gating kinetics.

36 es of strong adsorption sites are within the optical resolution of confocal imaging.

37 tosyl-activated cyclopentene aziridine 2 and optical resolution of racemic 1 with 10-camphorsulfonic

38 sualization of nanodomain Ca(2+) far exceeds optical resolution of spatially distributed Ca(2+) indic

39 pressed considerably weaker levels, although optical resolution of SR-B1 was inadequate.

40 e spot overlap is likely to occur within the optical resolution of the instrument, the observed fewer

41 een scattering centers even smaller than the optical resolution of the microscope are sufficient to p

42 ization of tags, which may be limited by the optical resolution of the microscope, to fluorescence re

43 a multigram scale in > 99% optical purity by optical resolution of the racemate with the camphoric ac

44 The potential for optical resolution of the seven-membered ring is discuss

45 Optical resolution of three closely related TBTQ derivat

46 In particular, optical-resolution PAM (OR-PAM) has pushed the technical

47 Optical-resolution photoacoustic microscopy (OR-PAM) is

48 Optical-resolution photoacoustic microscopy, which provi

49 abilities (high sensitivity, speed-scanning, optical resolution, portability) for point-of-care setti

50 The subdiffraction optical resolution that can be achieved using near-field

51 In addition to bridging the gap in optical resolution, this technique may be useful for bio

52 ocol for imaging cortical structures at high optical resolution through a thinned-skull cranial windo

53 ond number defined by the equator height and optical resolution to represent the measurement accuracy

54 key steps in the sequence were an efficient optical resolution using relatively inexpensive resolvin

55 Optical resolution was accomplished via diastereomeric s

56 Optical resolution was carried out on 2, and each of the

57 by optical tweezers is sufficient to achieve optical resolution well below the diffraction limit usin

58 (CAST), where intact brains can be imaged at optical resolution without labeling by leveraging tissue

59 an teeth using a confocal profiler at a high optical resolution (X-Y, 0.17 microm; Z < 3 nm).