Browsing by Subject "Carbon Nanotubes"
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Item Comparative Proteomics and Biological Effects of Functionalized Carbon Nanotubes in Intestinal Cell Co-culture(Office of the Vice Chancellor for Research, 2011-04-08) Lai, Xianyin; Fang, Meixian; Fears, Sharry; Mitra, Somenath; Ringham, Heather; Witzmann, Frank A.“Carbon nanotubes (CNTs) possess unique electrical, mechanical, and thermal properties, with potential applications in the electronics, catalysts, polymer composites, aerospace, and other industries. CNTs are also being developed for a broad range of applications in biomedicine, including oral drug delivery. Functionalized, water dispersible CNTs (fCNTS) can be expected to enter the digestive tract and exert biological effects on its barrier epithelial cells. To characterize these effects, we developed an in vitro model of the large intestinal tract using a coculture of Caco-2 (75%) and HT29-MTX (25%, mucus secreting) cells, and exposed these cells to functionalized single-walled (SWNT) and multi-walled (MWNT) carbon nanotubes at realistic concentrations (500 pg/mL and 10 µg/mL; 48 h). Protein expression was analyzed using our recently developed label-free quantitative mass spectrometry (LFQMS) platform, IdentiQuantXL™, while typical toxicological endpoint assays were used to characterize various cellular responses. LFQMS identified 5,007 unique protein database entries, from which 4,200 proteins were considered qualified for quantitation. These proteins represented 1,978 protein groups (containing isoforms, splice-variants, etc). Differences in expression were calculated by ANOVA (P<0.001) and post hoc Holm Sidak comparisons (P<0.05). fCNT significantly altered protein expression in a moderate number of proteins, the extent and type of which were fCNT specific. Only 13 proteins were universally altered by all exposures (except 500 pg/mL COOHSWNT which had no effect), and these represent a broad range of cellular functions. Bioinformatic analysis using the Gene Ontology Database and Ingenuity Pathway Analysis revealed statistically significant protein associations with a broad range of functional networks and signaling/metabolic pathways. Again, little overlap between fCNT was observed. None of the exposures was associated with overt toxicity or proinflammatory response. The results suggest that significant biological effects result from fCNT exposure, responses that are specific to CNT-type and dose, but occurring in the absence of toxicity or irritation. Supported by NIEHS RC2ES018810.”Item Fabrication of Submicron Thermosetting Carbon Nanotube-Epoxy Fibers Using Electrospinning(American Society for Composites, 2020-09-20) Aliahmad, Nojan; Wable, Vidya; Biswas, Pias Kumar; Hernadez, Iran; Dalir, Hamid; Agarwal, MangilalRecently epoxy-based nanocomposites are gaining tremendous attention in many structural applications such as those in aerospace, automotive and motorsports. This research represents a new approach to fabricate submicron thermoset epoxy filaments enhanced with carbon nanotubes (CNT), through optimized curing followed by an electrospinning process. The optimized curing process is based on the uniform mixing of CNT with epoxy, and partial curing of the CNT/epoxy mixture with the hardener through a thermal treatment without adding any plasticizers or thermoplastic binders. Later the fibers have been made by electrospinning of the semi-cured mixture. Fig 1 shows the fabrication process of the described filaments. The key goal is to make the thermosetting epoxy without adding any thermoplastic to keep the integrity and quality of the fibers. The diameters of these filaments can be tuned between 100 nm to 500nm. Further, the CNT structure has been aligned inside the filament structure by the presence of the electrostatic field during the electrospinning process results in better stability and smaller diameters for the fibers. The fabricated filaments show that adding a low amount of CNT in the epoxy structure, better structural, electrical and thermal stability, has been achieved.Item Multi-nozzle electrospinning optimization of carbon nanotube/epoxy submicron filaments – A numerical study(American Chemical Society, 2021-08-26) Liyanage, Asel Habarakada; Biswas, Pias Kumar; Cumbo, Eric; Siegel, Amanda P.; Agarwal, Mangilal; Dalir, HamidElectrospinning is the process of spinning a polymer melt or solution through a nozzle in the presence of a high-voltage electric field, which causes it to coalesce into a continuous filament. Diameter of the filament is anywhere from tens of nanometers to a few microns, depending on the materials being spun, viscosity, electric field, and other experimental conditions. This process has gained attention because of its versatility, low cost, and ease of processing for many polymers. Thermosetting reinforced epoxy is particularly challenging because of the variability in viscosity caused by temperature changes and induced by the electrospinning process itself. Nevertheless, our research group previously developed the fabrication and characterization of submicron carbon nanotube (CNT)–epoxy nanocomposite filaments through an electrospinning process via a single nozzle, horizontal spray process. In this study, electric fields and other parameters were simulated using COMSOL Multiphysics® software to understand the induced surface charges that cause the Taylor cone of the CNT-epoxy solution.. Optimization of the simulation results coupled with those of experiments enabled us to achieve stability and fabricate smaller but more uniform diameter fibers with enhanced structural, electrical, and thermal properties. The main challenge addressed in this paper is the use of the COMSOL models to understand the effect of different geometries on the electric field in the presence of multi-nozzle systems.