Glutaraldehyde crosslinked gelatin/hydroxyapatite nanocomposite scaffold,engineered via compound techniques

In this study, a scaffold was designed to be used in bone tissue repair and the effect of glutaraldehyde (GA) concentration as crosslinking agent was investigated. To mimic the mineral and organic component of natural bone, hydroxyapatite (HAp) and gelatin (GEL) were used as the main components of this composite. Nanopowders of HAp were synthesized and also used together with GEL to engineer a three‐dimensional nanocomposite scaffold. The results show that GEL/HAp nanocomposite is porous with three‐dimensional interconnected structure, pore sizes ranging from 300 to 500 μm, and about 85% porosity. In addition, increasing GA concentration provokes the enhancement of compressive strength until 1 w/v% GA solution followed by a reduction to 2.5%, whereas it causes work fracture to decrease. It was concluded that optimum concentration for crosslinking GEL matrix for this purpose is 1 w/v% GA solution. A specific combination of commonly used techniques applied to engineer a scaffold with almost ideal properties intended for the bone tissue engineering is introduced. In addition, scaffolds that are prepared via this compound process has the potential to be used in the solid free form applications and so being formed in any dimension and geometry relevant to the defect size and shape. POLYM. COMPOS., 31:2112–2120, 2010. © 2010 Society of Plastics Engineers     

Preparation,characterization and mechanical properties of controlled porous gelatin/hydroxyapatite nanocomposite through layer solvent casting combined with freeze-drying and lamination techniques

In this present study, to mimic the mineral and organic component of natural bone, hydroxyapatite (HA) and gelatin (GEL) nanocomposite was prepared via layer solvent casting combined with freeze-drying and lamination techniques. Glutaraldehyde (GA) was used as cross-linking agent. The synthesized nanocrystalline hydroxyapatite and nanocomposite samples were characterized by the commonly used bulk techniques. The results showed that GEL/HA nanocomposite were porous with 3-dimension interconnected microstructure, pore sizes were 100 μm to 1 mm, porosity were 75% to 93% and HA particles are dispersed evenly among gelatin fibers. It was also found that increasing initial GEL concentration and HA content enhance the elastic modulus (E) and reduce toughness and affect pore size and morphology. Finally, the stress–strain behavior in compression was very similar to natural spongy bone where the compressive modulus obtained was about 180 MPa.     

Enhancement of fracture toughness in bioactive glass-based nanocomposites with nanocrystalline forsterite as advanced biomaterials for bone tissue engineering applications

In this research, the replacement effects of bioactive glass (BG) by nanocrystalline forsterite (NF) on the biomineralization, microstructural and mechanical properties of BG-based nanocomposites were investigated. The hybrid nanocomposites with different NF contents (0, 10, 20, and 30 wt%) were prepared from the nanopowders by means of conventional cold pressing method. Surprisingly, the addition of NF provided redundant mechanisms to improve the toughness of the BG matrix without deteriorating its biomineralization properties. In addition, the resulting enhancement in the fracture toughness, observed for the first time in highly bioactive BG/NF nanocomposites, indicated the potential of the prepared nanocomposites as advanced biomaterials for load-bearing bone tissue engineering applications.     

A kinetic study on the electrophoretic deposition of hydroxyapatite–titania nanocomposite based on a statistical approach

In the present study, the electrophoretic deposition (EPD) process of hydroxyapatite–titania nanocomposite was kinetically described by the use of response surface methodology (RSM). The electrostatic interaction between particles in ethanol based suspensions was determined by Zeta potential and particle size analyses. After successful electrophoretic deposition from hydroxyapatite–titania suspensions with 0, 10 and 20 wt% of titania nanoparticles, it was shown that Baldisserri model can well reproduce the experimental data among the other semi-empirical kinetic equations. The as-deposited hydroxyapatite–titania nanocomposites were characterized employing SEM, AFM, XRD, and FT-IR analyses. Then, the effects of deposition voltage, deposition time and wt% TiO₂ on the kinetic of EPD at two time intervals (10–60 s and 60–300 s) were identified and quantified via RSM based on a central composite design (CCD). According to the results obtained from the statistical analysis, it was found that the deposition rate decreases by an increase in wt% TiO₂ and time. Also, a transition in deposition mechanism from linear to parabolic mode was observed and two second order polynomial equations were fitted to the response (deposit weight) at each time intervals.     

Graft copolymerization of acrylic acid on to styrene butadiene rubber (SBR) to improve morphology and mechanical properties of SBR/polyurethane blend

Graft copolymerization of acrylic acid (AA) on to styrene butadiene rubber (SBR) is carried out via free radical polymerization using benzoyl peroxide (BPO) as initiator. Graft yield (GY) and graft efficiency (GE) measurements reveal that the optimum grafting is achieved when 100 wt % of AA and 3 wt % of BPO are used for a reaction time of 6 h at 60 °C. The execution of the grafting process is confirmed through ATR‐IR spectroscopy and DMTA analysis. Tan δ thermograms indicate that the graft copolymerization occurs in the styrene segments of the SBR backbone. An in situ polymerized, semicrystalline polyurethane (PU) is then used to prepare a series of SBR‐g‐PAA/PU blends. It is found that the SBR‐g‐PAA with the highest GY exhibits the best compatibility with PU matrix. One‐phase morphology (SEM), as well as the appearance of only one glass transition (DMTA) verify the homogeneous miscibility of the modified blend compositions. Moreover, the integration of PUs crystalline structure into blends gives rise to elongation‐induced crystallinity as the prominent phenomenon in tensile testing, which proves to synchronously enhance tensile strength, modulus, elongation at break, and toughness. © 2016 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2016 , 133, 43699.     

A new model for the determination of optimum fiber volume fraction under multi-axial loading in polymeric composites

Iranian Polymer Journal - Mechanical properties of composite materials are a function of fiber volume fraction. Based on the existing micromechanical models, the in-plane shear strength of these...     

Reliability Analysis of Fault-Tolerant Bus-Based Interconnection Networks

Multi-processor systems need interconnection networks (INs) in order to make the connection among the processors, memory modules, and nodes. Bus interconnection network is the simplest and least expensive one among all the INs. Therefore, bus network is easily understood and preferred by manufactures for implementation. However, a bus network is inherently a non-fault tolerant and blocking network. To cope with these problems, a solution is to use several buses in parallel on a network. Based on this idea, various schemes can be designed for a bus network: (1) Multiple-bus with full bus-memory connection, (2) Multiple-bus with single bus-memory connection, (3) Multiple-bus with partial bus-memory connection, and (4) Multiple-bus with class-based memory connection. On the other hand, a metric for the efficiency of fault-tolerant systems is its reliability. Although, there is no detailed analysis of the reliability of bus-based networks, this paper presents accurate and complete reliability analysis of bus-based networks to achieve these aims: (1) Determining the most efficient design of bus-based networks in terms of reliability, cost-effectiveness, and blocking issues, (2) Providing new methods for evaluating the performance of bus-based networks.     

Fast and clean functionalization of carbon nanotubes by dielectric barrier discharge plasma in air compared to acid treatment

Multi-walled carbon nanotubes (MWCNTs) have been functionalized by a dielectric barrier discharge plasma in air and compared to those functionalized in HNO₃. The MWCNTs were prepared by chemical vapor deposition of xylene using ferrocene as a catalyst at 850 °C. Air oxidation followed by acid treatment was used to purify the MWCNTs, which were then annealed in helium. The MWCNTs were functionalized in air in a plasma reactor at room temperature. Quantitative analyses of gases evolved during the temperature programmed desorption of the functionalized nanotubes were carried out using Fourier transform infrared spectroscopy and gas chromatography. The influence of plasma parameters, including power in the range of 8-90 W and treatment time in the range of 1-9 min, on the number of the functional groups was investigated. It is shown that the extent of functionalization increases with increasing discharge power, provided that the exposure time of the MWCNTs in the plasma atmosphere does not exceed a certain period of time. Compared to acid treatment, plasma functionalization offers the advantages of much shorter treatment time, and produces less damage.     

How bone marrow-derived human mesenchymal stem cells respond to poorly crystalline apatite coated orthopedic and dental titanium implants

Due to the delayed and weak bone-implant integration in dental and orthopedic devices, there have been several attempts to enhance implant–bone interactions for rapid osseointegration. In this paper, the interactions of human bone marrow-derived stromal (mesenchymal) stem cells (hMSCs) with uncoated and coated titanium alloy implants with poorly crystalline apatite are studied. First the configuration and chemical composition of the apatite coatings and their deposition progress in different experimental conditions are investigated and discussed. Then, hMSCs are cultured on different substrates and cell attachment and proliferation are monitored and evaluated for different time intervals. Although the uncoated and coated substrates indicate good cell attachment, the differences in proliferation and morphology of the cells spread over the coated samples are significant. It is concluded that the coated samples improve the capability for accepting the cells in three-dimensional and slender shapes. The migration of hMSCs on both substrates are discussed. As such cell migration is directly associated to the osteoconduction, the findings confirm the hypothesis of enhancement in bone formation on the surface of biomimetically poorly crystalline apatite coated titanium implants. This in vitro study demonstrates that the coated samples are nontoxic and biocompatible enough for ongoing osteogenic studies in bone or dental defects in animal models in vivo.