We have used focused electron-beam cross-linking to create nanosized hydrogels and thus present a new method with which to bring the attractive biocompatibility associated with macroscopic hydrogels into the submicron length-scale regime. Using amine-terminated poly(ethylene glycol) thin films on silicon substrates, we generate nanohydrogels with lateral dimensions of order 200 nm which can swell by a factor of at least five, depending on the radiative dose. With the focused electron beam, high-density arrays of such nanohydrogels can be flexibly patterned onto silicon surfaces. Significantly, the amine groups remain functional after e-beam exposure, and we show that they can be used to covalently bind proteins and other molecules. We use bovine serum albumin to amplify the number of amine groups, and we further demonstrate that different proteins can be covalently bound to different hydrogel pads on the same substrate to create multifunctional surfaces useful in emerging bio/proteomic and sensor technologies.
Inspired
by the cell membrane surface as well as the ocular tissue,
a novel and clinically applicable antifouling silicone hydrogel contact
lens material was developed. The unique chemical and biological features
on the surface on a silicone hydrogel base substrate were achieved
by a cross-linked polymer layer composed of 2-methacryloyloxyethyl
phosphorylcholine (MPC), which was considered important for optimal
on-eye performance. The effects of the polymer layer on adsorption
of biomolecules, such as lipid and proteins, and adhesion of cells
and bacteria were evaluated and compared with several conventional
silicone hydrogel contact lens materials. The MPC polymer layer provided
significant resistance to lipid deposition as visually demonstrated
by the three-dimensional confocal images of whole contact lenses.
Also, fibroblast cell adhesion was decreased to a 1% level compared
with that on the conventional silicone hydrogel contact lenses. The
movement of the cells on the surface of the MPC polymer-modified lens
material was greater compared with other silicone hydrogel contact
lenses indicating that lubrication of the contact lenses on ocular
tissue might be improved. The superior hydrophilic nature of the MPC
polymer layer provides improved surface properties compared to the
underlying silicone hydrogel base substrate.
Key words: fractography, very-high-cycle fatigue, crack initiation Abstract: Very-High-Cycle Fatigue (VHCF) is the phenomenon of fatigue damage and failure of metallic materials or structures subjected to 10 8 cycles of fatigue loading and beyond. This paper attempts to investigate the VHCF behavior and mechanism of a high strength low alloy steel (main composition: C-1% and Cr-1.5%; quenched at 1108K and tempered at 453K). The fractography of fatigue failure was observed by optical microscopy and scanning electron microscopy. The observations reveal that, for the number of cycles to fatigue failure between 10 6 and 4×10 8 cycles, fatigue cracks almost initiated in the interior of specimen and originated at non-metallic inclusions. An "optical dark area" (ODA) around initiation site is observed when fatigue initiation from interior. ODA size increases with the decrease of fatigue stress, and becomes more roundness. Fracture mechanics analysis gives the stress intensity factor of ODA, which is nearly equivalent to the corresponding fatigue threshold of the test material. The results indicate that the fatigue life of specimens with crack origin at the interior of specimen is longer than that with crack origin at specimen surface. The experimental results and the fatigue mechanism were further analyzed in terms of fracture mechanics and fracture physics, suggesting that the primary propagation of fatigue crack within the fish-eye local region is the main characteristics of VHCF.
The calculation of the nonlinear time-response of structures such as RC (reinforced concrete) frames to base excitation such as earthquake waves is vital to ensure the safety of structures. Of course the response changes significantly with the applied base excitation. The usual approaches to compare the different earthquake waves are based on non-localized spectra, such as response spectra and power spectra, which do not contain any time information. However these non-localized spectra often do not explain the large difference between structural responses, and are not able to reflect all of the characteristics of the earthquake waves. Local spectra, which can be easily obtained by the wavelet transform, calculate the energy distribution of the waves in the time-frequency domain. Using the wavelet transform it is easy to see the differences in the energy distribution via the local spectra of each wave, and therefore to understand the very different structural responses. Hence the time-frequency distribution of the wave energy should be taken into account during the selection of earthquake waves to apply to structural models to determine the nonlinear time response.
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