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Stimuli Responsive Self-Assembly of Functional Organic NanomaterialsLee, Kwang Soo 07 June 2016 (has links)
No description available.
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A New Class of Biodegradable, Coacervate-Forming, Thermoresponsive Polyesters Based on N-Substituted DiolsSwanson, John Patrick 09 June 2016 (has links)
No description available.
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Surface Modification and Transport Modeling of Micron- and Nano-Sized MaterialsGuardado, Erick Salvador Vasquez 17 August 2013 (has links)
Nanoparticle-based technologies are an emerging field with the promise to impact a wide range of application areas. However, that potential is somewhat married to a host of research questions that remain to be answered. This work explores the surface modification of magnetic nanoparticles in a controlled fashion to produce hybrid nanoparticle (metal/polymer) systems with different morphologies, understand in-situ behavior of stimuli-responsive polymers grafted to a substrate, and obtain better computational methods for particle-tracking and -deposition. Nanoparticle surface modification was performed using ATRP, obtaining homo-, block-co-, and ‘twoaced/biphasic’ polymer structures on the nanoparticle surfaces. Biphasic Janus nanoparticles (JPs) were formed using a magnetic nanoparticle core and an innovative technique combining non-covalent solid protection with sequential controlled radical polymerization to form the two surface-grafted polymer phases. Surface-confined polymerizations were conducted using pH- and thermo-responsive materials. Poly(methacrylic acid) (PMAA) and a series of (aminoalkyl) methacrylate polymers were used as pH responsive polymers. Additionally, poly(N-isopropylacrylamide) (PNIPAM) was selected as the thermo-responsive material for this study. In-situ characterization techniques, including atomic force microscopy (AFM), dynamic light scattering (DLS), and ellipsometry, were used to evaluate the thermo- and pH-responsiveness of these stimuli responsive materials. A new general-oscillator (GENOSC) model was used to determine swelling ratio, thickness, and optical constant changes in the polymer brush as pH was changed in-situ. AFM was used to study morphological changes due to changes in pH and temperature. Nanoparticle temperature responsiveness was investigated using DLS. A related effort involved the use of computational fluid dynamic (CFD) methods to track (micron-sized) particles in certain geometries, including a human lung morphology. Predicted particle transport and deposition was compared to Lagrangian computational approaches and available experimental data. The Eulerian particle phase modeling method developed resulted in the accurate prediction of both near-wall particle tracking and wall deposition. This Eulerian-Eulerian model is a new tool that has potential for particle tracking in physiological morphologies. This combination of experimental and computational research has led to new nano- and micro-particle surface modification methods and particle transport modeling.
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Tuning the aggregation behavior of pH-responsive micelles by copolymerizationWright, D.B., Patterson, J.P., Pitto-Barry, Anaïs, Cotenda, P., Chassenieux, C., Colombani, O., O'Reilly, R.K. 25 February 2015 (has links)
Yes / Amphiphilic diblock copolymers, poly(2-(diethylamino)ethyl methacrylate-co-2-(dimethylamino)ethyl methacrylate)-b-poly(2-(dimethylamino)ethyl methacrylate), P(DEAEMA-co-DMAEMA)-b-PDMAEMA with various amounts of DEAEMA have been synthesized by RAFT polymerization. Their micellization in water has been investigated by scattering measurements over a wide pH range. It appeared that the polymers self-assembled into pH sensitive star like micelles. For a given composition, when the pH is varied the extent of aggregation can be tuned reversibly by orders of magnitude. By varying the copolymer composition in the hydrophobic block, the onset and extent of aggregation were shifted with respect to pH. This class of diblock copolymer offers the possibility to select the range of stimuli-responsiveness that is useful for a given application, which can rarely be achieved with conventional diblock copolymers consisting of homopolymeric blocks. / European Science Foundation (ESF), Engineering and Physical Sciences Research Council (EPSRC), BP (Firm), Birmingham Science City, Advantage West Midlands (AWM), European Regional Development Fund (ERDF)
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Complementary light scattering and synchrotron small-angle X-ray scattering studies of the micelle-to-unimer transition of polysulfobetainesDoncom, K.E.B., Pitto-Barry, Anaïs, Willcock, H., Lu, A., McKenzie, B.E., Kirby, N., O'Reilly, R.K. 19 March 2015 (has links)
Yes / AB and ABA di- and triblock copolymers where A is the hydrophilic poly(oligoethylene glycol methacrylate) (POEGMA) block and B is a thermo-responsive sulfobetaine block [2-(methacryloyloxy) ethyl] dimethyl-(3-sulfopropyl) ammonium hydroxide (PDMAPS) were synthesised by aqueous RAFT polymerisation with narrow dispersity (ĐM ≤ 1.22), as judged by aqueous SEC analysis. The di- and triblock copolymers self-assembled in salt-free water to form micelles with a PDMAPS core and the self-assembly of these polymers was explored by SLS and TEM analysis. The micelles were shown, by DLS analysis, to undergo a micelle-to-unimer transition at a critical temperature, which was dependent upon the length of the POEGMA block. Increasing the length of the third, POEGMA, block decreased the temperature at which the micelle-to-unimer transition occurred as a result of the increased hydrophilicity of the polymer. The dissociation of the micelles was further studied by SLS and synchrotron SAXS. SAXS analysis revealed that the micelle dissociation began at temperatures below that indicated by DLS analysis and that both micelles and unimers coexist. This highlights the importance of using multiple complementary techniques in the analysis of self-assembled structures. In addition the micelle-to-unimer morphology transition was employed to encapsulate and release a hydrophobic dye, Nile Red, as shown by fluorescence spectroscopy. / Engineering and Physical Sciences Research Council (EPSRC), University of Warwick
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Encapsulation of particles and cells using stimuli-responsive self-rolling polymer filmsZakharchenko, Svetlana 26 May 2014 (has links) (PDF)
This thesis is focused on the design and development of an approach, allowing the fabrication of biocompatible/biodegradable self-rolled polymer tubes, which are sensitive to stimuli at physiological conditions, can be homogenously filled with cells and are able to self-assemble into a complex 3D construct with uniaxially aligned pores. These constructs are aimed to recreate the microstructure of tissues with structural anisotropy, such as of muscles and bones. The approach consists of two steps of self-assembly. As a first step, cells are adsorbed on the top of an unfolded bilayer; triggered rolling results in a parallel encapsulation of cells inside the tubes. As a second step, the formed self-rolled tubes with encapsulated cells can be assembled in a uniaxial tubular scaffold.
Three polymer systems were designed and investigated in the present work in order to allow triggered folding of the bilayer. These systems allow either reversible or irreversible tube formation. The possibility to encapsulate microobjects inside self-rolled polymer tubes was demonstrated on the example of silica particles, yeast cells and mammalian cells. At conditions when bilayer film is unfolded, particles or cells were deposited from their aqueous dispersion on the top of bilayer. An appropriate change of conditions triggers folding of the bilayer and results in encapsulation of particles or cells inside the tubes. One way swelling of an active polymer allows irreversible encapsulation of cells in a way that tubes do not unroll and cells cannot escape. It was demonstrated that encapsulated cells can proliferate and divide inside the tubes for a long period of time. Since used polymers are optically transparent, encapsulated cells can be easily observed using optical and fluorescent microscopy. Reversible swelling of an active polymer provides the possibility to release encapsulated objects.
It was demonstrated that in aqueous media microtubes possessing small amount of negatively charged groups on external walls self-assemble in the presence of oppositely charged microparticles that results in a formation of 3D constructs. In obtained aggregates tubes and therefore pores were well-aligned and the orientation degree was extremely high. Moreover, the approach allows the design of porous materials with complex architectures formed by tubes of different sorts. The assembly of cell-laden microtubes results in a formation of uniaxial tubular scaffold homogeneously filled with cells.
The results presented in this work demonstrate that the proposed approach is of practical interest for biotechnological applications. Self-rolled tubes can be filled with cells during their folding providing the desired homogeneity of filling. Individual tubes of different diameters could be used to investigate cell behaviour in confinement in conditions of structural anisotropy as well as to mimic blood vessels. Due to their directionality tubes could be used to guide the growth of cells that is of interest for regeneration of neuronal tissue. Reversibly foldable films allow triggered capture and release of the cells that could be implemented for controlled cell delivery. In perspective, self-assembled 3D constructs with aligned pores could be used for bottom-up engineering of the scaffolds, mimicking such tissues as cortical bone and skeletal muscle, which are characterized by repeating longitudinal units. Such constructs can be also considered as a good alternative of traditional 2D flat cell culture.
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Encapsulation of particles and cells using stimuli-responsive self-rolling polymer filmsZakharchenko, Svetlana 09 April 2014 (has links)
This thesis is focused on the design and development of an approach, allowing the fabrication of biocompatible/biodegradable self-rolled polymer tubes, which are sensitive to stimuli at physiological conditions, can be homogenously filled with cells and are able to self-assemble into a complex 3D construct with uniaxially aligned pores. These constructs are aimed to recreate the microstructure of tissues with structural anisotropy, such as of muscles and bones. The approach consists of two steps of self-assembly. As a first step, cells are adsorbed on the top of an unfolded bilayer; triggered rolling results in a parallel encapsulation of cells inside the tubes. As a second step, the formed self-rolled tubes with encapsulated cells can be assembled in a uniaxial tubular scaffold.
Three polymer systems were designed and investigated in the present work in order to allow triggered folding of the bilayer. These systems allow either reversible or irreversible tube formation. The possibility to encapsulate microobjects inside self-rolled polymer tubes was demonstrated on the example of silica particles, yeast cells and mammalian cells. At conditions when bilayer film is unfolded, particles or cells were deposited from their aqueous dispersion on the top of bilayer. An appropriate change of conditions triggers folding of the bilayer and results in encapsulation of particles or cells inside the tubes. One way swelling of an active polymer allows irreversible encapsulation of cells in a way that tubes do not unroll and cells cannot escape. It was demonstrated that encapsulated cells can proliferate and divide inside the tubes for a long period of time. Since used polymers are optically transparent, encapsulated cells can be easily observed using optical and fluorescent microscopy. Reversible swelling of an active polymer provides the possibility to release encapsulated objects.
It was demonstrated that in aqueous media microtubes possessing small amount of negatively charged groups on external walls self-assemble in the presence of oppositely charged microparticles that results in a formation of 3D constructs. In obtained aggregates tubes and therefore pores were well-aligned and the orientation degree was extremely high. Moreover, the approach allows the design of porous materials with complex architectures formed by tubes of different sorts. The assembly of cell-laden microtubes results in a formation of uniaxial tubular scaffold homogeneously filled with cells.
The results presented in this work demonstrate that the proposed approach is of practical interest for biotechnological applications. Self-rolled tubes can be filled with cells during their folding providing the desired homogeneity of filling. Individual tubes of different diameters could be used to investigate cell behaviour in confinement in conditions of structural anisotropy as well as to mimic blood vessels. Due to their directionality tubes could be used to guide the growth of cells that is of interest for regeneration of neuronal tissue. Reversibly foldable films allow triggered capture and release of the cells that could be implemented for controlled cell delivery. In perspective, self-assembled 3D constructs with aligned pores could be used for bottom-up engineering of the scaffolds, mimicking such tissues as cortical bone and skeletal muscle, which are characterized by repeating longitudinal units. Such constructs can be also considered as a good alternative of traditional 2D flat cell culture.
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3D and 4D lithography of untethered microrobotsRajabasadi, Fatemeh, Schwarz, Lukas, Medina-Sánchez, Mariana, Schmidt, Oliver G. 16 July 2021 (has links)
In the last decades, additive manufacturing (AM), also called three-dimensional (3D) printing, has advanced micro/nano-fabrication technologies, especially in applications like lightweight engineering, optics, energy, and biomedicine. Among these 3D printing technologies, two-photon polymerization (TPP) offers the highest resolution (even at the nanometric scale), reproducibility and the possibility to create monolithically 3D complex structures with a variety of materials (e.g. organic and inorganic, passive and active). Such active materials change their shape upon an applied stimulus or degrade over time at certain conditions making them dynamic and reconfigurable (also called 4D printing). This is particularly interesting in the field of medical microrobotics as complex functions such as gentle interactions with biological samples, adaptability when moving in small capillaries, controlled cargo-release profiles, and protection of the encapsulated cargoes, are required. Here we review the physics, chemistry and engineering principles of TPP, with some innovations that include the use of micromolding and microfluidics, and explain how this fabrication schemes provide the microrobots with additional features and application opportunities. The possibility to create microrobots using smart materials, nano- and biomaterials, for in situ chemical reactions, biofunctionalization, or imaging is also put into perspective. We categorize the microrobots based on their motility mechanisms, function, and architecture, and finally discuss the future directions of this field of research.
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Towards stimuli-responsive functional nanocomposites : smart tunable plasmonic nanostructures Au-VO2Jean Bosco Kana Kana January 2010 (has links)
<p>The fascinating optical properties of metallic nanostructures, dominated by collective oscillations of free electrons known as plasmons, open new opportunities for the development of devices fabrication based on noble metal nanoparticle composite materials. This thesis demonstrates a low-cost and versatile technique to produce stimuli-responsive ultrafast plasmonic nanostructures with reversible tunable optical properties. Albeit challenging, further control using thermal external stimuli to tune the local environment of gold nanoparticles embedded in VO2 host matrix would be ideal for the design of responsive functional nanocomposites. We prepared Au-VO2 nanocomposite thin films by the inverted cylindrical reactive magnetron sputtering (ICMS) known as hollow cathode magnetron sputtering for the first time and report the reversible tuning of surface plasmon resonance of Au nanoparticles by only adjusting the external temperature stimuli. The structural, morphological, interfacial analysis and optical properties of the optimized nanostructures have been studied. ICMS has been attracting much attention for its enclosed geometry and its ability to deposit on large area, uniform coating of smart nanocomposites at high deposition rate. Before achieving the aforementioned goals, a systematic study and optimization process of VO2 host matrix has been done by studying the influence of deposition parameters on the structural, morphological and optical switching properties of VO2 thin films. A reversible thermal tunability of the optical/dielectric constants of VO2 thin films by spectroscopic ellipsometry has been intensively also studied in order to bring more insights about the shift of the plasmon of gold nanoparticles imbedded in VO2 host matrix.</p>
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Tailoring Surface Properties of Bio-Fibers via Atom Transfer Radical PolymerizationLindqvist, Josefina January 2007 (has links)
The potential use of renewable, bio-based polymers in high-technological applications has attracted great interest due to increased environmental concern. Cellulose is the most abundant biopolymer resource in the world, and it has great potential to be modified to suit new application areas. The development of controlled polymerization techniques, such as atom transfer radical polymerization (ATRP), has made it possible to graft well-defined polymers from cellulose surfaces. In this study, graft-modification of cellulose substrates by ATRP was explored as a tool for tailoring surface properties and for the fabrication of functional cellulose surfaces. Various native and regenerated cellulose substrates were successfully graft-modified to investigate the effect of surface morphology on the grafting reactions. It was found that significantly denser polymer brushes were grafted from the native than from the regenerated cellulose substrates, most likely due to differences in surface area. A method for detaching the grafted polymer from the substrate was developed, based on the selective cleavage of silyl ether bonds with tetrabutylammonium fluoride. The results from the performed kinetic study suggest that the surface-initiated polymerization of methyl methacrylate from cellulose proceeds faster than the concurrent solution polymerization at low monomer conversions, but slows down to match the kinetics of the solution polymerization at higher conversions. Superhydrophobic and self-cleaning bio-fiber surfaces were obtained by grafting of glycidyl methacrylate using a branched graft-on-graft architecture, followed by post-functionalization to obtain fluorinated polymer brushes. AFM analysis showed that the surface had a micro-nano-binary structure. It was also found that superhydrophobic surfaces could be achieved by post-functionalization with an alkyl chain, with no use of fluorine. Thermo-responsive cellulose surfaces have been prepared by graft-modification with the stimuli responsive polymer poly(N-isopropylacrylamide) (PNIPAAm). Brushes of poly(4-vinylpyridine) (P4VP) rendered a pH-responsive cellulose surface. Dual-responsive cellulose surfaces were achieved by grafting block-copolymers of PNIPAAm and P4VP. / QC 20100804
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