Global ETD Search

111	Rules of Contact Inhibition of Locomotion for Cell-pairs Migrating on Aligned and Suspended Nanofibers Singh, Jugroop Kaur 22 November 2019 (has links) Contact inhibition of locomotion (CIL), a migratory mechanism, first introduced by Abercrombie and Heaysman in 1953 is now a fundamental driving force in developmental, repair and disease biology. Much of what we know of CIL stems from studies done on 2D substrates which are unable to provide the essential biophysical cue of fibrous extracellular matrix curvature. Here we inquired if the same rules are applicable for cells attached to and migrating persistently on suspended and aligned ECM-mimicking nanofibers. Using two elongated cell shapes (spindle attached to one fiber, and parallel attached to two fibers), we quantitate CIL rules for spindle-spindle, parallel-parallel and spindle-parallel collisions. Two approaching spindles do not repolarize upon contact but rather continue to migrate past one another. Contrastingly, approaching parallel cells establish distinct CIL, with only one cell repolarizing upon contact followed by migration of both cells as a cohesive unit in the repolarization direction. Interestingly, for the case of spindle and parallel cell collision, we find the parallel cell to shift the morphology to that of spindle and continue persistent movement without repolarization. To account for effect of cell speed, we also quantitate CIL collisions between daughter and non-dividing cells. While spindle-spindle collisions result in cells still walking by, for parallel-parallel collisions, we capture rare events of a daughter cell pushing the non-dividing cell. With increasing population numbers, we observe formation of cell streams that collapse into spheroids. Single cells are able to invade along fibers from the spheroids and are then subject to same CIL conditions, thus providing a platform with cyclic CIL. The presented coupling of experimental and analytical framework provides new insights in contextually relevant CIL and predictive capabilities in cell migration decision steps. / Master of Science / Contact inhibition of locomotion (CIL) is a migratory process that can lead to a change in migration direction through protrusion inhibition of single cells. First described in 1953, the traditional model of CIL shows that on a 2D substrate, two migrating cells experience a decrease in protrusive behavior upon contacting each other, followed by repolarization, and migration away from one another. However, a cell's extracellular matrix (ECM) is fibrous in nature, and how cells maintain standard CIL rules in fibrous environments remains unclear. Here, using suspended, aligned nanofibers created using a non-electrospinning Spinneret based Tunable Engineered Parameters (STEP) method, we investigate CIL decision steps of two fibroblast cells approaching each other in two shapes: spindle cells attached to single fibers, and parallel cells attached to two fibers. Most spindle cells approaching each other do not switch direction upon contact, but rather continue to migrate past each other, termed a walk past. Contrastingly, approaching parallel cells display unique CIL whereby only one cell repolarizes and reverses its migration direction. Subsequently, both cells remain in contact while migrating in the repolarization direction. Interestingly, we report that both spindle and parallel CIL are also affected by speed post cell division. Altogether, for the first time, we introduce a platform to understand cell shape driven CIL geometrical rules in ECM mimicking environments. Contact inhibition of locomotion rules nanofibers cell collisions spindle parallel
112	Aligned electrospun cellulose scaffolds coated with rhBMP-2 for both in vitro and in vivo bone tissue engineering Zhang, X., Wang, C., Liao, M., Dai, L., Tang, Y., Zhang, H., Coates, Philip D., Sefat, Farshid, Zheng, L., Song, J., Zheng, Z., Zhao, D., Yang, M., Zhang, W., Ji, P. 13 February 2019 (has links) Yes / Physical properties of scaffolds such as nanofibers and aligned structures have been reported to exert profound effects on the growth and differentiation of stem cells due to their homing-effect features and contact guidance. However, the biological function of aligned nanofiber utilized as bone-scaffold has not been rigorously characterized. In the present study, aligned electrospun cellulose/CNCs nanocomposite nanofibers (ECCNNs) loaded with bone morphogenic protein-2 (BMP-2) were used for the first time to investigate (1) in vitro osteogenic differentiation of human mesenchymal stem cells (BMSCs) and (2) in vivo collagen assembly direction and cortical bone regeneration. Aligned ECCNNs scaffolds loaded with BMP-2 possess good biological compatibility. The growth orientation of BMSCs followed the underlying aligned nanofibers morphology, accompanied with increased alizarin red stain, ALP activity and calcium content in vitro while, a rabbit calvaria bone defect model was used in an in vivo study. / This work was supported by Natural Science Foundation of China (NSFC) grants (31500789, 51433006, 51473100, 81870758 and 31871464), Chongqing Yuzhong District science and technology plan project grants (20170124), Chongqing Research Program of Basic Research and Frontier Technology (cstc2018jcyjAX0807, cstc2017jcyjBX0019 and cstc2017jcyjAX0020), Temple University Kornberg School of Dentistry research start-up funds, the RCUK China-UK Science Bridges Program through the Medical Research Council and the Engineering and Physical Sciences Research Council and Program for Innovation Team 1015 Building at Institutions of Higher Education (No. 1016 CXTDG201602006) funded by the Chongqing Municipal 1017 Education Commission of China in 2016 Electrospinning Cellulose Cellulose nanocrystals Aligned nanofibers Collagen assembly Cortical bone
113	MECHANICAL CHARACTERIZATION – MONOTONIC MICRO-TENSILE, STRESS RELAXATION, AND STRAIN-CONTROLLED CYCLIC STRESS-STRAIN RESPONSES OF SINGLE ELECTROSPUN PVDF NANOFIBERS Falola, Adekunle Samuel 29 August 2019 (has links) No description available. Mechanical Engineering Materials Science Polymers Single Electrospun Nanofibers Mechanical Characterization Stress Relaxation Micro-Tensile Cyclic Stress-Strain Fatigue of Nanofibers Electrospinning
114	Gas Jet Process for Production of Sub-micron Fibers Benavides, Rafael Esteban 21 May 2013 (has links) No description available. Polymers Polymer Chemistry Chemical Engineering Polymer nanofibers carbon nanofibers sub-micron fibers nonwoven gas jet fibers nanotechnology nanofiber network.
115	Nickel plated carbon nanotubes reinforcing concrete composites: from nano/micro structures to macro mechanical properties Dong, S., Wang, D., Ashour, Ashraf, Han, B., Ou, J. 28 November 2020 (has links) Yes / Owing to their small size, good wettability, uniform dispersion ability and high thermal properties, the nickel-plated carbon nanotubes (Ni-CNTs) with different aspect ratios are used to reinforce reactive powder concrete (RPC) through modifying the nano/micro- structural units of concrete. Incorporating only 0.075 vol% of Ni-CNTs (0.03 vol% of CNTs) can significantly increase mechanical properties of RPC. The enhancement effect on compressive strength caused by the incorporation of Ni-CNTs with aspect ratio of 1000 reaches 26.8%/23.0 MPa, mainly benefiting from the high polymerization C-S-H gels, low porosity, and refined pore structure. The 33.5%/1.92 MPa increases of flexural strength can be attributed to the decrease of large pore, original cracks, molar ratio of CaO to SiO2, and gel water content when Ni-CNTs with aspect ratio of 125 are added. Ni-CNTs with aspect ratio of 1500 have the largest utilization rate of being pulled-out, resulting from the improvement of dispersibility and the pining effect of nickel coating and then leading to the increased toughness. Therefore, incorporating Ni-CNTs can fundamentally modify the nano/micro- scale structural nature of RPC, providing a bottom-up approach for controlling the properties of RPC. / Funding supported from the National Science Foundation of China (51908103 and 51978127) and the China Postdoctoral Science Foundation (2019M651116). Carbon nanotubes Carbon nanofibers Carbon nanofibres Carbon nanotubes and nanofibers Carbon nanotubes and nanofibres Nanocomposites Mechanical properties Microstructural analysis
116	Efficient Photocatalytic Degradation of Organic Pollutant in Wastewater by Electrospun Functionally Modified Polyacrylonitrile Nanofibers Membrane Anchoring TiO2 Nanostructured. AlAbduljabbar, Fahad A., Haider, S., Ali, F.A.A., Alghyamah, A.A., Almasry, W.A., Patel, Rajnikant, Mujtaba, Iqbal 28 March 2022 (has links) Yes / In this study, polyacrylonitrile (PAN_P) nanofibers (NFs) were fabricated by electrospinning. The PAN_P NFs membrane was functionalized with diethylenetriamine to prepare a functionalized polyacrylonitrile (PAN_F) NFs membrane. TiO2 nanoparticles (NPs) synthesized in the laboratory were anchored to the surface of the PAN_F NFs membrane by electrospray to prepare a TiO2 NPs coated NFs membrane (PAN_Coa). A second TiO2/PAN_P composite membrane (PAN_Co) was prepared by embedding TiO2 NPs into the PAN_P NFs by electrospinning. The membranes were characterized by microscopic, spectroscopic and X-ray techniques. Scanning electron micrographs (SEM) revealed smooth morphologies for PAN_P and PAN_F NFs membranes and a dense cloud of TiO2 NPs on the surface of PAN_Coa NFs membrane. The attenuated total reflectance in the infrared (ATR-IR) proved the addition of the new amine functionality to the chemical structure of PAN. Transmission electron microscope images (TEM) revealed spherical TiO2 NPs with sizes between 18 and 32 nm. X-ray powder diffraction (XRD) patterns and energy dispersive X-ray spectroscopy (EDX) confirmed the existence of the anatase phase of TiO2. Surface profilometry da-ta showed increased surface roughness for the PAN_F and PAN_Coa NFs membranes. The adsorption-desorption isotherms and hysteresis loops for all NFs membranes followed the IV -isotherm and the H3 -hysteresis loop, corresponding to mesoporous and slit pores, respectively. The photocatalytic activities of PAN_Coa and PAN_Co NFs membranes against methyl orange dye degradation were evaluated and compared with those of bare TiO2 NPs.The higher photocatalytic activity of PAN_Coa membrane (92%, 20 ppm) compared to (PAN_Co) NFs membrane (41.64%, 20 ppm) and bare TiO2 (49.60%, 20 ppm) was attributed to the synergy between adsorption, lower band gap, high surface roughness and surface area. Electrospinning Modified nanofibers Electrospray TiO2/PAN composite TiO2 coated Polyacrylonitrile (PAN) PAN modified nanofibers Photocatalysis Band gap
117	Rapid creation of skin substitutes from human skin cells and biomimetic nanofibers for acute full-thickness wound repair Mahjour, S.B., Fu, X., Yang, X., Fong, J., Sefat, Farshid, Wang, H. January 2015 (has links) Yes / Creation of functional skin substitutes within a clinically acceptable time window is essential for timely repair and management of large wounds such as extensive burns. The aim of this study was to investigate the possibility of fabricating skin substitutes via a bottom-up nanofiber-enabled cell assembly approach and using such substitutes for full-thickness wound repair in nude mice. Following a layer-by-layer (L-b-L) manner, human primary skin cells (fibroblasts and keratinocytes) were rapidly assembled together with electrospun polycaprolactone (PCL)/collagen (3:1 w/w, 8% w/v) nanofibers into 3D constructs, in which fibroblasts and keratinocytes were located in the bottom and upper portion respectively. Following culture, the constructs developed into a skin-like structure with expression of basal keratinocyte markers and deposition of new matrix while exhibited good mechanical strength (as high as 4.0 MPa by 14 days). Treatment of the full-thickness wounds created on the back of nude mice with various grafts (acellular nanofiber meshes, dermal substitutes, skin substitutes and autografts) revealed that 14-day-cultured skin substitutes facilitated a rapid wound closure with complete epithelialization comparable to autografts. Taken together, skin-like substitutes can be formed by L-b-L assembling human skin cells and biomimetic nanofibers and they are effective to heal acute full-thickness wounds in nude mice. Skin tissue engineering Layer-by-layer Wound healing PCL/collagen polyblend nanofibers Human skin cells Biomimetic nanofibers
118	Příprava keramických vláken elektrostatickým zvlákňováním / Electrospinning of ceramic fibers Nemčovský, Jakub January 2017 (has links) This diploma thesis focuses on the fabrication of ceramic fibres by electrospinning. The theoretical part of the thesis summarizes the currently available information regarding ceramic fibres, their properties, applications and fabrication. The theoretical part also describes the process of electrospinning as one of the most frequently used methods of nanofibre fabrication, as well as the parametres influencing this process. The experimental part is aimed at the fabrication of ceramic fibres based on titania, pure non-doped zirconia and yttria-doped zirconia by electrospinning and at the characterization of thus fabricated fibres. Ceramic precursors based on propoxide and polyvinylpyrrolidone were subjected to electrospinning. The experimental part of this diploma thesis also describes the influence of precursor composition, process conditions and calcination temperature on the morphology and phase composition of the fibres. Precursors were characterized by viscosity measurements. Thermogravimetric analysis (TGA), Röntgen analysis (RTG) and scanning electron microscopy (SEM) were used to describe the fibres. By performing electrospinning of precursors based on titanium propoxide and subsequent calcination at 500-1300 °C, TiO2 fibres with thickness of 100-2500 nm were fabricated. The phase composition changed with calcination temperature from 500 °C from anatase phase through rutile blend to pure rutile at 900 °C. By performing electrospinning of precursors based on zirconium propoxide and subsequent calcination at 550-1100 °C, 0 – 8 mol% Y2O3 doped ZrO2 fibres with thickness of 50-1000 nm were fabricated. An analysis of fibres based on non-doped ZrO2, calcined at 550 °C showed a composition of predominantly monoclinic phase. An analysis of 3 or 8 mol% Y2O3 doped ZrO2 fibres calcined at 900 °C showed a composition of predominantly tetragonal phase or purely cubic phase, respectively. With the increasing calcination temperature, the morphology of the fibres changed from porous nanostructure to chain-like non-porous structure consisting of micrometer grains of TiO2 or ZrO2. The ZrO2 fibres calcined at 700 °C remained flexible as well as the spun ones, while their fragility increased with the increase in calcination temperature.
119	Incorporation of metal (silver, copper, iron) chalcogenides (oxide, selenide) nanoparticles into poly(methyl methacrylate) fibers for their antibacterial activity Sibokoza, Simon Bonginkosi January 2020 (has links) D. Tech. (Department of Chemistry, Faculty of Applied and Computer Sciences), Vaal University of Technology. / Nanoscience receives a lot of attention in the 21 century and is one of the most advancing technology in our days. It provides many new and advanced technological opportunities. This field involves many disciplines which include chemical, physical, and biological related fields. The advancement of nanoscience makes life to be better and bring about new inventions which can solve many problems in our day to day life. Although there are reservations about the use of these materials in other fields. Some researchers believe that these materials can be a problem to the environment and humanity at large. Therefore, more research needs to be done to fully understand these materials. Polymer science is another field that has been advancing every day. Many problems in our lives require material which have properties from nanomaterials and polymers. The combination of these technologies can leads to new materials which have many possibilities in solving most problems. Some researchers have taken advantage of these two powerful fields and merge them. There has been a lot of work done that involves combination of nanotechnology and polymer science. The current project is an initiative to manufacture nanofibers. These fibers are prepared using polymer solution mixed with metal oxide and metal selenide nanomaterials. The polymer solution is incorporated with nanoparticles and electrospunned to make nanofibers. The electrospinning afford the material prepared to be at nanoscale. The fact that the material formed is at nanoscale opens many possibilities to be used in various fields. The study is about fabrication of polymer nanofibers embedded with metal chalcogenide nanoparticles. The metal oxide and metal selenide nanoparticles were prepared using complexes. These complexes contain both the metal and the chalcogenide of interest. The complexes are prepared from oxygen-based (urea), and selenium-based (diphenyldiselenide) ligands. The urea complexes co-ordinates with metal using oxygen for iron, however in silver complexes both nitrogen and oxygen are used. These complexes allow easy control of reaction parameters, and thermal decomposes to form metal oxide, metal selenide, and metal. The complexes are very stable and decomposes at about 200 °C. These compounds are thermal decomposed to form metal chalcogenides, and metal nanoparticles. The complexes are characterized with FTIR, TGA, and elemental analysis. The metal chalcoginedes (copper oxide, iron oxide, silver oxide, copper selenide, iron selenide, and silver selenide) nanoparticles were prepared using thermal decomposition of a single source (complexes or metal salts). The prepared chalcogenides nanoparticles have good absorption and emission properties consistent with small sizes. These nanoparticles are composed of various phased and stoichiometry. Some metal chalcogenides have a mixture of stoichiometry and phase. The metal chalcogenides nanoparticles are dominated by spheres, and other shapes such as rods. These metal chalcogenides have a particles size in the range of 1-36 nm. The metal chalcogenides nanoparticles were tested against bacteria and fungi. These nanoparticles show highest activity in gram positive compared to gram negative bacteria. Metal oxide nanoparticles show the highest activity compared to metal selenide. All the metal chalcogenides show the highest against fungi. The nanoparticles are able to inhibit the fungi at lowest concentration. The nanoparticles are characterized with various instruments which includes UV-Vis, PL, XRD, and TEM. Nanofibers of poly(methyl methacrylate) (PMMA) incorporated with metal selenide and metal oxide nanoparticles were prepared by electrospinning. The nanofibers incorporated with metal chalcogenide are more thermal stable than PMMA nanofibers. Therefore, incorporation of metal chalcogenides nanoparticles leads to more thermal stability nanofibers. The PMMA are coordinated to the metal oxide and metal selenide through carbonyl oxygen atom. The PMMA incorporated with metal oxide and metal selenide leads to the formation of nanofibers with uneven surface with a diameter in the range of 30 to 200 nm. The prepared fibers are characterized using FTIR, TGA, SEM. Nanoscience Polymer science Nanotechnology Nanofibers Polymer nanofibers Metal chalcogenide nanoparticles Oxide Selenide Antibacterial activity Poly (methyl metacrylate) Dissertations, Academic -- South Africa Nanoparticles Polymers Nanocomposites (Materials) Nanostructured materials
120	Collection of highly aligned electrostrictive graft elastomer nanofibers using electrospinning in a vacuum environment Rao, Vivek S. January 1900 (has links) Master of Science / Department of Mechanical and Nuclear Engineering / Youqi Wang / Electrospinning is one of the most versatile methods used to fabricate nanofibers. Sub micron and nano level fibers can be continuously produced with the help of an external electric field induced on the polymer melt. These nanofibers can be used in a large variety of applications such as biosensors, three dimensional tissue scaffolds, composites, electronic devices, etc. A unique feature of electrospinning is its ability to work with different fiber assemblies. This helps in making application specific changes and also increases the quality and performance of the fibers. PEO (polyethylene oxide) and electrostrictive graft elastomer (an electroactive polymer developed by NASA) were used in our experiments which focus on controlling the shape and alignment of the fibers. Electroactive polymers (EAP’s) are seen as the basis for future artificial muscles because of their ability to deform when external voltage is applied and quickly recover to their original form when the polarity of the applied voltage is reversed. Hence, aligned fibers of the electrostrictive graft elastomer were produced to mimic the alignment in human muscle fibers. Alignment of fibers is the main objective of this research and was facilitated using vacuum technology. The research was basically divided into three phases, starting with checking of the repeatability of the previously developed techniques using polyethylene oxide. Next, the electrostrictive graft elastomer was spun using the electrospinning techniques and was checked for alignment using the Coaxial Electrode method and PLC controlled secondary electric field method. Finally, a vacuum chamber was designed and built with new components and the elastomer was tested for improved alignment in vacuum using the PLC controlled secondary electric field method. Elestrospinning Alignment of nanofibers Chemistry, Polymer (0495) Engineering, Mechanical (0548) Physics, General (0605)

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