Electron micrograph image

FIGURE 17.27 (a) Electron micrograph images of foot structures of terminal cisternae. (b, c) Foot structures appear as trapezoids and diamonds on the surface of the membrane. 

FIGURE 7.11 A scanning electron micrograph image of an ISM cross section. 

Fig. 11 Electron micrograph image of an ultramicrotome-cut thin section of a layer of paint, seen parallel to the orientation of adcular pigment particles and to the surface of the layer.

Fig. 65 Electron micrograph images of two samples of Pigment Yellow 83 of different particle sizes.

Figure 3. Electron micrograph image of an E. coli thin section showing a thick capsule.

Lys and Glu residues at the e and g sites are blue and red, respectively the buried, offset Asn residues at a are green. Adapted from Pandya et al (2000). (B) Negative-stain transmission electron micrograph image for fibers assembled from the sticky ended building blocks. Adapted from MacPhee and Woolfson (2004). 

Fig. 19. (A) Electron micrograph image of isolated myosin filaments and actin...

Figure 1 Electron micrograph of an artificial viral envelope. In a unilamellar lipid bilayer of a diameter of approximately 200 nm are surface glycoproteins of the respiratory syncytial virus (RSV) inserted as described in detail by Chander Schreier [7] (electron micrographic image by G. Erdos, EM Core Laboratory, University of Florida, Gainesville, EL).

Fig. 3.2 Unique trifoliolate structure of proline-/S-naphthylamidase.l7) Electron micrographic images of negatively stained molecules are rotationary averaged after superimposition of images each with 120° rotation from the others. Scale bar, 3 nm. (Reproduced with permission from K. Takahashi, FEBS Leu., 280, 298 (1991)).

FIGURE 11.9 Electron micrograph images of mobile colloids collected in a series of column studies, deposited on polycarbonate filters, and then (a) metal (AuPd) or (b) carbon coated prior to imaging and EDS analysis with (c) a field-emission SEM. 

Characterisation of metal oxide materials is similar to that of organic polymers, which includes surface area analyses and electron micrograph images. In addition... 

FIGURE 20.17 (A) X-ray diffraction spectra and (B) cross-sectional scanning electron micrograph image of 160 nm Ta(Al)N(C) film on a patterned silicon wafer. (From AUen, R, Juppo, M., Ritala, M., Sajavaara, T., Keinonen, J., and Leskela, M., J. Electrochem. Soc., 148, G566, 2001.)... 

Figure 20 Left High-resolution transmission electron micrograph image of a single PtMo (3 1) nanoparticle on the edge of a carbon black primary particle (111) and (100) fades are clearly resolved. Right Distribution Pt (light) and Mo (dark) atoms in an fee cubo-octahedral particle containing 1806 Pt atoms and 600 Mo atoms from classical Monte Carlo simulation at 550 K.

Figure 3.93. Scanning electron micrograph image of a photonic band-gap crystal obtained by TP induced crosslinking radical polymerization of acrylates in the presence of poly(styrene-co-acrylonitrile) as binder and an amino substituted distyrylbenzene as TP active initiator using a pulsed laser (730-nm excitation wavelength, 0.45-mW laser power, 50-mm/s scan speed, writing 9 layers of 1-mm spaced parallel rods with a layer spacing of 1 mm). (From Ref. [133] with permission of the Technical Association of Photopolymers, Japan.)...

The best known polyene-protein complexes are, of course, rhodopsin and bacte-riorhodopsin. The model for the long wavelength shifts of the retinal-lysine Schiff bases have already been discussed in Chapter 5. A detailed electron micrograph image analysis is available for bacteriorhodopsin, which shows seven he-... 

Figure 30. High-resolution transmission electron micrograph image of a Q-PbS-sensitized microporous Ti02 electrode.

Figure 14.9 Freeze-fracture transmission electron micrograph images of a latex film prepared at 36°C from a surfrtctant-free PBMA latex (

Recently, stearic acid has been used to coat the surface of ibuprofen-containing microspheres [84]. In these preparations, stearic acid only partially delayed the release of ibuprofen when microspheres were suspended in a variety of buffer conditions. A scanning electron micrograph image of representative stearic acid microspheres that contain ibuprofen is shown in Figure 2. 

Figure 2. Scanning electron micrograph image of stearic acid microspheres prepared by immersion in pH 8.0 sodium phosphate buffer at 37°C according to Waters Pavlakis [84].

Thermal inkjet spray freeze-drying was used to produce inhalable particles of terbutaline sulfate (37). Scanning electron micrograph images proved that the particles are spherical, highly porous and suitable for aerosolization from a capsule-based dry-powder device. There is no need for additional experiments. 

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