Structural optimisation with damage tolerance constraints

Recent developments in cluster computing and structural optimisation offer the potential for significant improvements in the design of more durable structures, and for producing optimum fatigue life extension rework profiles. The present paper reveals the importance of non-destructive inspection (NDI) and the role it plays in determining optimum structural rework geometries. This finding is important since when performing stress based optimisation the interrelationship of NDI and optimum rework geometries is not immediately apparent. The problems studied also reveal the flatness of the solution space and, unlike stress based optimisation, the existence of multiple maxima. Such solution spaces represent a major challenge for any optimisation procedure. To this end we explore the advantages of using the NIMROD optimisation suite of programs in conjunction with A cluster computer architecture and the highlight the benefit of visualizing the solution space.     

Gelatin scaffolds functionalized by silver nanoparticle‐containing calcium alginate beads for wound care applications

The embedding of silver nanoparticle (nAg)‐containing calcium alginate (CaAlg) beads in gelatin scaffolds was aimed to reduce the burst release and prolong the release of silver (Ag⁺) ions for a long period of time. The reduced sizes of the nAg‐containing CaAlg beads were prepared by an emulsification/external gelation method. The diameter of these beads was ~2 µm. The nAg‐containing CaAlg beads were then embedded into gelatin scaffolds by a freeze‐drying method for evaluating the potential of these scaffolds as wound dressings. The compressive modulus of these scaffolds embedded with nAg‐containing CaAlg beads ranged between 7 and 9 kPa. For release study, the cumulative released amounts of Ag⁺ ions from the nAg‐containing CaAlg beads embedded in gelatin scaffolds were lower than those from the nAg‐containing CaAlg beads. Moreover, the nAg‐containing CaAlg beads embedded in gelatin scaffolds had great antibacterial activity and low cytotoxicity. Thus, these scaffolds had potential for sustaining the release and use in wound care applications, especially chronic wound. Copyright © 2016 John Wiley & Sons, Ltd.     

Nonisothermal bulk crystallization studies of high density polyethylene using light depolarizing microscopy

The quiescent nonisothermal bulk crystallization kinetics of two high-density polyethylene resins were investigated by a modified light-depolarizing microscopy (LDM) technique. The technique allows studies at average cooling rates up to 2500°C/min. The polymer was found to crystallize at a pseudo-isothermal temperature even at these very high cooling rates. The overall bulk crystallization rate increased rapidly as the cooling rate and supercooling increased. Crystallization kinetics was analyzed by Avrami analysis. Avrami exponents near 3 suggested spherical growth geometry and instantaneous nucleation at predetermined sites. Observation of spherulites by optical microscopy together with a number density of spherulites that changed little with increase in cooling rate or supercooling supported this model of crystallization behavior. Analysis of the half-time of crystallization based on the Lauritzen and Hoffman secondary nucleation theory indicated that the regime II-III transition was found to occur at a degree of supercooling of approximately 22°C. © 1998 John Wiley & Sons, Inc. J Polym Sci B: Polym Phys 36: 681–692, 1998     

The effect of frequency and power density on the ultrasonically-enhanced killing of biofilm-sequestered Escherichia coli

Infection on implanted medical devices is a critical concern because the bacteria are recalcitrant to antibiotic therapy; currently the only way to eliminate the infection is to remove the device. We have found that low-frequency ultrasound renders bacteria more susceptible to antibiotics. The effect of low-intensity ultrasound on the enhancement of antibiotic action against biofilm bacteria was measured by subjecting thick E. coli biofilms for 2 h at 37°C to one of four conditions: (1) incubation in nutrient broth; (2) incubation in nutrient broth with antibiotic; (3) ultrasonication in nutrient broth without antibiotic; and (4) ultrasonication in nutrient broth with antibiotic. Two frequencies (70 and 500 kHz) and several ultrasonic intensities were examined, ranging from 2 to 200 mW/cm². It was determined that low-intensity ultrasound significantly enhanced killing of biofilm E. coli by gentamicin. This enhancement increased with increasing ultrasonic intensity and decreased with increasing frequency. A mathematical model of ultrasonically-enhanced transport in cylindrical pores and channels shows that gentamicin transport increases with ultrasonic intensity and decreases with increasing frequency. However, the magnitude of increased transport is so small that it is difficult to attribute enhanced killing of bacteria to enhanced antibiotic transport through the pores and channels of the biofilm; therefore, other mechanisms must play a role. The use of low-intensity ultrasound in conjunction with antibiotic treatment may prove to be a viable clinical method of eliminating biofilm infections from the surfaces of implanted medical devices.     

Color Change of Electrospun Polystyrene/MEH‐PPV Fibers from Orange to Yellow through Partial Decomposition of MEH Side Groups

The present contribution reports the electrospinning of PS/MEH‐PPV fibers with average diameters ranging from 0.165 to 1.190 µm from solutions of PS/MEH‐PPV (PS/MEH‐PPV = 7.5:1, w/w) in 1,2‐dichloroethane. With the addition of pyridinium formate (PF), a volatile organic salt, to the PS/MEH‐PPV solution, the electrospinnability of the resulting solution is enhanced significantly. Both the fiber diameters and the number of fibers are found to increase, while the number of beads is found to decrease with increasing applied electrical potential, the addition of PF, and increasing aging period of the spinning solution after PF addition. FT‐IR analysis shows that ≈15% of the MEH side groups are removed from the MEH‐PPV component in the fibers obtained from the solution that is left to age for 1 month after PF addition, which corresponds well to the loss of mass of ≈7% as observed by thermogravimetric analysis. As a result, partial decomposition of the MEH side groups should be responsible for the observed yellow emission color of the PS/MEH‐PPV fibers obtained from the same solution.

     

The synthesis of biodegradable polymers with functional side chains

Trifunctional hydroxy-terminated oligomeric polyesters, M_n 500, 1000, and 2000, were prepared by initiating ring-opening copolymerization of δ-valerolactone and ε-caprolactone with glycerol. The prepolymers were converted to crosslinked polyester-urethanes by their reaction with hexane-1,6-diisocyanate in proportions corresponding to 70, 80, 90, and 100% of the hydroxyl content. The moduli of the resulting elastomers varied between 0.12 MPa and 3.83 MPa, and the elongation at break between 60 and 2000%. The residual hydroxyl groups were derivatized by heterogeneous reaction with chloroacetic anhydride or excess hexane-1,6-diisocyanate, and these and further transformations of the functional groups were verified by infrared spectroscopy and electron probe x-ray microanalysis. A second series of hydroxy-substituted elastomers was synthesized by copolymerization of δ-valerolactone, ε-caprolactone, and 4-(t-butyldimethylsilyloxy)-ε-caprolactone, using different amounts of 2,2-bis(caprolacton-4-yl)propane as the crosslinking agent; removal of the t-butyldimethylsilyl group to liberate pendant hydroxyl groups was achieved with acetic acid but not fluoride ion. The hydroxylated polyester (but not the polyesterurethanes) was shown to undergo enzymatic surface erosion in rabbit. The biodegradation data were compared with results previously obtained with low-modulus elastomeric polyesters.     

Probing motions between equivalent RNA domains using magnetic field induced residual dipolar couplings: accounting for correlations between motions and alignment

Approaches developed thus for extracting structural and dynamical information from RDCs have rested on the assumption that motions do not affect molecular alignment. However, it is well established that molecular alignment in ordered media is dependent on conformation, and slowly interconverting conformational substates may exhibit different alignment properties. Neglecting these correlation effects can lead to aberrations in the structural and dynamical analysis of RDCs and diminish the utility of RDCs in probing motions between domains having similar alignment propensities. Here, we introduce a new approach based on measurement of magnetic field induced residual dipolar couplings in nucleic acids which can explicitly take into account such correlations and demonstrate measurements of motions between two "magnetically equivalent" domains in the transactivation response element (TAR) RNA.