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LSCM images

Experiment 6. The LSCM image of salt gland impregnated with phenolic compounds... [Pg.119]

Fig. 9 The LSCM images of Equsetum arvense microspores stained with colchicine 10 7 M. The laser excitation wavelength 458 nm. Fig. 9 The LSCM images of Equsetum arvense microspores stained with colchicine 10 7 M. The laser excitation wavelength 458 nm.
Fig. 10 The LSCM images of Hippeastrum hybridum pollen tube stained with colchicine 10" 7 M. The laser excitation wavelength 458 nm. 1. The bright emission is observed in nucleus of vegetative cell of pollen and in the spermium located in the tip of the tube 2. Spermium in the tip of pollen tube. The microtubules contained of tubulin are seen. [Pg.122]

Procedure The fluorescence spectra of the ethanol and water solutions of the allelochemicals 10 5 -10"7 M were recorded with spectrofluorimeter Perkin -Elmer 550 in 1-cm cuvettes. The excitation wavelength was 360 nm. LSCM images were analysed as in section 9.4. [Pg.132]

Figure 4. LSCM images at magnification of (a) 5x, (b) 20x, (c) 150x, and (d) OS profiles for Clear, Disp, and NonDisp coatings after 151 d outdoor exposure. The size scale bars in (a) to (d) represent 100 pm, 50 pm, 5 pm, and respectively. The areas in (d) are compatible to the measuring angular range of 20 specular gloss measurements. Figure 4. LSCM images at magnification of (a) 5x, (b) 20x, (c) 150x, and (d) OS profiles for Clear, Disp, and NonDisp coatings after 151 d outdoor exposure. The size scale bars in (a) to (d) represent 100 pm, 50 pm, 5 pm, and respectively. The areas in (d) are compatible to the measuring angular range of 20 specular gloss measurements.
Fig. 4.22 Friction and height AFM 40 x 40 lm images and confocal microscopy (LSCM) images with different sizes of the fluorescent monolayers TM4 (images a-f in which 20 x 20pm2 metal ion patterns were written by DPN. TM4 SAMs were patterned with Cu2+ (Cu (C104)2, 10 2 M, acetonitrile) (images a-c), or with Ca2 (Ca (C104)2, 10 2 M, acetonitrile) (images d-f)... Fig. 4.22 Friction and height AFM 40 x 40 lm images and confocal microscopy (LSCM) images with different sizes of the fluorescent monolayers TM4 (images a-f in which 20 x 20pm2 metal ion patterns were written by DPN. TM4 SAMs were patterned with Cu2+ (Cu (C104)2, 10 2 M, acetonitrile) (images a-c), or with Ca2 (Ca (C104)2, 10 2 M, acetonitrile) (images d-f)...
Deming et al. [53] used large vesicles based on poly(i.-arginine)6o-btod -poly (L-leucine)2o (Fig. lOg) (labeled with fluoresceine for LSCM imaging) for... [Pg.187]

Fig. 22 (a) Proposed self-assembly of PArgeo-b-PLeu2o vesicles, (b) LSCM image of the vesicles. [Pg.187]

Fig. 4 LSCM images at a depth of 20 ixm from the surface of the phase-separated SBR/PB (50/50) blend film, (a) Reflection LSCM image observed with X = 488nm (b) LSCFM image of the same field as in image (a) observed using k = 364 nm (c) Superposition of the two images, (a) and (b) PB was labeled with anthracene. Reprinted with permission of [18], copyright (2001) American Chemical Society... Fig. 4 LSCM images at a depth of 20 ixm from the surface of the phase-separated SBR/PB (50/50) blend film, (a) Reflection LSCM image observed with X = 488nm (b) LSCFM image of the same field as in image (a) observed using k = 364 nm (c) Superposition of the two images, (a) and (b) PB was labeled with anthracene. Reprinted with permission of [18], copyright (2001) American Chemical Society...
Two-photon induced fluorescence LSCM imaging through the assembled multilayer structure... [Pg.130]

Plate 2. Image formation (upon photoacid generation) within photosensitive polymer films for assembly of multi-layered structures. Two-photon fluorescence LSCM imaging usingfs pulsed near-IR pump allows for 3-D volumetric imaging of the layered structure. [Pg.130]

Figure 16.9 LSCM image of a fetal pig lung demonstrating neural ganglia outside the... Figure 16.9 LSCM image of a fetal pig lung demonstrating neural ganglia outside the...
Fig. 2 Comparisons of scaled structure factors Siqlq ) (proportional to F x) in Eq. (1)) obtained from the 3D LSCM image (unfilled circles), the TLS experiments for the PB/PI wt%/wt% mixture (crosses) and the computer simulations based on the 3D TDGL model (solid line) [14]... Fig. 2 Comparisons of scaled structure factors Siqlq ) (proportional to F x) in Eq. (1)) obtained from the 3D LSCM image (unfilled circles), the TLS experiments for the PB/PI wt%/wt% mixture (crosses) and the computer simulations based on the 3D TDGL model (solid line) [14]...
Figure 16.12 LSCM images of solvent-cast 10 90 PMMA/PS blend film. The bright spots represent PMMA labeled with NBD dye, the dark areas represent PS. The morphologies shown are at the film surface (left), at 3 pm... Figure 16.12 LSCM images of solvent-cast 10 90 PMMA/PS blend film. The bright spots represent PMMA labeled with NBD dye, the dark areas represent PS. The morphologies shown are at the film surface (left), at 3 pm...
Figure 16.13 LSCM image quality improve- the rendered 3D micrographs showing the X-Y-... Figure 16.13 LSCM image quality improve- the rendered 3D micrographs showing the X-Y-...
LSCM image (b) Image after deconvolution Reprinted with permission from Ref. [23] ... [Pg.544]

Figure 16.14 LSCM images of poly(styrene-ran-butadiene) and polybutadiene blend imaged at 20(tm beneath the top surface, using (a) reflecting and (b) fluorescence modes ... Figure 16.14 LSCM images of poly(styrene-ran-butadiene) and polybutadiene blend imaged at 20(tm beneath the top surface, using (a) reflecting and (b) fluorescence modes ...
Figure 16.15 LSCM image of a PS/PMMA blend, demonstrating inorganic QDs as effective tracers for the PS phase in fluorescence imaging of the blend structure. The bright regions represent the PS phase, and the dark... Figure 16.15 LSCM image of a PS/PMMA blend, demonstrating inorganic QDs as effective tracers for the PS phase in fluorescence imaging of the blend structure. The bright regions represent the PS phase, and the dark...
Figure 16.16 LSCM images showing phase-separated morphologies of biopolymeric mixtures of gelatin and maltodextrin confined in emulsion droplets. The effect of confinement size on mesoscale morphologies is shown... Figure 16.16 LSCM images showing phase-separated morphologies of biopolymeric mixtures of gelatin and maltodextrin confined in emulsion droplets. The effect of confinement size on mesoscale morphologies is shown...
Fig. 3 Non-ionic polypeptide vesicles (a) LSCM image (50 pm wide) of a K iooL20 vesicle suspension visualized with fluorescent probes and a Z-direction slice thickness of 490 nm. (b) Proposed packing of chains in vesicle walls, (c) Structure and cartoon of chains. Adapted from [88]... Fig. 3 Non-ionic polypeptide vesicles (a) LSCM image (50 pm wide) of a K iooL20 vesicle suspension visualized with fluorescent probes and a Z-direction slice thickness of 490 nm. (b) Proposed packing of chains in vesicle walls, (c) Structure and cartoon of chains. Adapted from [88]...
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LSCM

LSCM images reconstruction

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