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1                                              Differential interference contrast (DIC) image analysis
2                  Keeping track: By combining differential interference contrast (DIC) image pattern r
3 labeled with dynein-GFP with high resolution differential interference contrast (DIC) images of nucle
4 ch 1- to 3-minute interval, GFP and Nomarski differential interference contrast (DIC) images were acq
5                      We have used time-lapse differential interference contrast (DIC) imaging to obse
6                                   Time-lapse differential interference contrast (DIC) imaging was per
7 nal motion of plasmonic gold nanorod under a differential interference contrast (DIC) microscope.
8  time-lapse acquisition system attached to a differential interference contrast (DIC) microscope.
9 as examined over time (0, 3, 6, 18 hours) by differential interference contrast (DIC) microscopy afte
10                                              Differential interference contrast (DIC) microscopy allo
11                                              Differential interference contrast (DIC) microscopy and
12 nce of plasmonic nanoparticles' contrasts in differential interference contrast (DIC) microscopy has
13                Apoptosis was investigated by differential interference contrast (DIC) microscopy, mic
14 -based detection technique, with the help of differential interference contrast (DIC) microscopy, off
15                                        Using differential interference contrast (DIC) microscopy, we
16 swimming R. sphaeroides was examined by both differential interference contrast (DIC) microscopy, whi
17 licated point spread functions (PSF) such as differential interference contrast (DIC) microscopy.
18  are poorly resolved at other wavelengths in differential interference contrast (DIC) microscopy.
19  fluorescent neural profiles visualized with differential interference contrast (DIC) optics in horiz
20 ) changes in cell wall thickness by Nomarski differential interference contrast (DIC), (2) changes in
21  Using fluorescent speckle microscopy (FSM), differential interference contrast (DIC), and phase cont
22                                     Infrared differential interference contrast (IR DIC) videomicrosc
23 ver a period of 3 days using motion-enhanced differential interference contrast (MEDIC) microscopy, a
24 rity of giant vesicles based on quantitative differential interference contrast (qDIC) microscopy.
25                    Time lapse video enhanced-differential interference contrast analysis of the cellu
26 DIC requires only a microscope equipped with differential interference contrast and a digital camera.
27  post-transection times; and (5) we examined differential interference contrast and confocal images a
28 ion were examined 2 to 6 months later, using differential interference contrast and epifluorescence m
29                                   Time-lapse differential interference contrast and fluorescence imag
30 sion, pause, and retraction), as revealed by differential interference contrast and fluorescence loss
31          Its performance was evaluated using differential interference contrast and fluorescence micr
32 addition, analysis of infected monolayers by differential interference contrast and fluorescence micr
33 nt cells and their nucleoids were studied by differential interference contrast and fluorescence micr
34                         Digitized time-lapse differential interference contrast and immunofluorescenc
35 architecture of the mesoglea, as observed by differential interference contrast and scanning electron
36 en gel, intrinsic fiber structure visible in differential interference contrast images can provide ma
37                                              Differential interference contrast images demonstrated o
38  can be derived automatically from timelapse differential interference contrast images using a Deform
39 ent speckle microscopy (FSM) and correlative differential interference contrast imaging to investigat
40 educed optical contrast under both phase and differential interference contrast imaging.
41      In this last decade, the combination of differential interference contrast infrared video techno
42 were observed in real time by video-enhanced differential interference contrast light microscopy at d
43     We have used time-lapse. video-enhanced, differential interference contrast light microscopy to d
44 dual microtubules in vitro by video-enhanced differential interference contrast light microscopy.
45             These numbers are in accord with differential interference contrast measurements, and the
46 d and used as optical imaging probes under a differential interference contrast microscope for single
47                       Using fluorescence and differential interference contrast microscopies, we moni
48 d nanorods at nonplasmonic wavelengths under differential interference contrast microscopy (DIC).
49 nuclear localization by video-enhanced color differential interference contrast microscopy (VEC-DIC),
50 ction of emerging HbS polymers using optical differential interference contrast microscopy after lase
51 n vertebrate-cultured cells using time-lapse differential interference contrast microscopy after micr
52 crotubules were visualized by video-enhanced differential interference contrast microscopy and cells
53 analicular membrane structure as observed by differential interference contrast microscopy and F-acti
54 rmined by contrast changes in ribs imaged by differential interference contrast microscopy and fluore
55         We used two-photon imaging, infrared-differential interference contrast microscopy and patch
56 chnique described here, and a combination of differential interference contrast microscopy and von Wi
57  with microvilli and microridges observed by differential interference contrast microscopy and were s
58 DPA) was monitored by Raman spectroscopy and differential interference contrast microscopy during ger
59    However, this model was challenged by the differential interference contrast microscopy observatio
60                                              Differential interference contrast microscopy reveals th
61                             Fluorescence and differential interference contrast microscopy showed pol
62 ht scattering, dynamic light scattering, and differential interference contrast microscopy to confirm
63  dipicolinic acid (DPA) was then measured by differential interference contrast microscopy to monitor
64  from translational motions in the z-axis in differential interference contrast microscopy to result
65 -simultaneous three-dimensional fluorescence/differential interference contrast microscopy was used t
66                         Here, video-enhanced differential interference contrast microscopy was used t
67                                              Differential interference contrast microscopy was used t
68                               For example in differential interference contrast microscopy which play
69                                   Time-lapse differential interference contrast microscopy with quant
70 vanced light microscopy technique, episcopic differential interference contrast microscopy with the s
71 microscopy) and ciliary beat frequency (CBF; differential interference contrast microscopy) with a si
72 nt publications reported, however, that with differential interference contrast microscopy, all midgu
73  easy to identify using video-enhanced color differential interference contrast microscopy, and they
74           Phase-contrast techniques, such as differential interference contrast microscopy, are widel
75                               When viewed by differential interference contrast microscopy, binding o
76                                      We used differential interference contrast microscopy, coupled w
77  nucleated assembly assay and video-enhanced differential interference contrast microscopy, we demons
78  each grating was measured using calibrated, differential interference contrast microscopy.
79 ction, transmission electron microscopy, and differential interference contrast microscopy.
80 e distinct capsular reactions when viewed by differential interference contrast microscopy.
81  embryo are collected in the z axis by using differential interference contrast microscopy.
82 eme fragments as monitored by video-enhanced differential interference contrast microscopy.
83 sin-coated bead motility assay observed with differential interference contrast microscopy.
84 the loss of granule contents as monitored by differential interference contrast microscopy; and the f
85                                              Differential interference contrast optics and image anal
86 r, costly microscope equipment with infrared differential interference contrast optics is not always
87 yofibrillar degeneration were apparent using differential interference contrast video microscopy.
88 y human HbC were studied by bright-field and differential interference contrast video-enhanced micros
89 nsequences of this regulation using infrared differential interference contrast videomicroscopy to me
90             To test this hypothesis, we used differential interference contrast videomicroscopy to vi
91               In the present study, infrared differential interference contrast videomicroscopy was u
92 late cells were studied with phase contrast, differential interference contrast, and epifluorescence
93 out a matrix detectable by phase contrast or differential interference contrast.
94 nd-6)-carboxyfluorescein (BCECF), Fura-2 and differential interference contrast/calcein imaging.
95 ture epi-illuminator, which inserts into the differential interference-contrast (DIC) slider bay of a
96  unstained cells reveal details invisible in differential interference-contrast images.
97                            Using millisecond differential interference-contrast microscopy and analyz
98      Our study demonstrates that millisecond differential interference-contrast microscopy can be a u
99 s were assessed by light (phase-contrast and differential interference-contrast) and transmission (st
100                                              Differential-interference-contrast microscopy demonstrat
101 laments has been visualized by dark-field or differential-interference-contrast microscopy, methods h
102 spore germination and outgrowth, we employed differential interference microscopy and epifluorescence
103 h microscopy methods such as phase contrast, differential interference microscopy, fluorescence and c
104 onal cell bodies are easily visualized using differential interference microscopy.
105 that ethanol-induced inhibition results from differential interference with signal transduction pathw

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