Stimulus-responsive Injectable Polysaccharide Scaffolds for Soft Tissue Engineering Prepared by O/W High Internal Phase Emulsion

This thesis describes work on the development of several novel stimuli-responsive porous hydrogels prepared from oil-in-water (o/w) high internal phase emulsion (HIPE) as injectable scaffolds for soft tissue engineering. Firstly, by copolymerising glycidyl methacrylate (GMA) derivatised dextran and N-isopropylacrylamide (NIPAAm) in the aqueous phase of a toluene-in-water HIPE, thermo-responsive polyHIPE hydrogels were obtained. The temperature depended modulus of these porous hydrogels, as revealed by oscillatory mechanical measurements, indicated improvements of the mechanical properties of these hydrogels when heated from room temperature to human body temperature, as the polyNIPAAm copolymer segments starts to phase separate from the aqueous phase and causes the hydrogel to form a more compact structure within the aqueous phase of the polyHIPE. Secondly ion responsive methacrylate modified alginate polyHIPE hydrogels were prepared. The physical dimensions, pore and pore throat sizes as well as water uptakes of these ion responsive hydrogels can be controllably decreased in the presence of Ca2+ ions and are fully recovered after disruption of the ionic crosslinking using a chelating agent (sodium citrate). These ion-responsive polyHIPE hydrogels also possess good mechanical properties (modulus up to 20 kPa). Both of these polyHIPE hydrogels could be easily extruded through a hypodermic needle while breaking into small fragments (about 0.5 to 3.0 mm in diameter), but the interconnected porous morphology was maintained after injection as revealed by SEM characterisation. Furthermore, the hydrogel fragments produced during injection can be crosslinked into a coherent scaffold under very mild condition using Ca2+ salts and alginate aqueous solution as the ionically crosslinkable adhesive. In order to increase the pore size of these covalently crosslinked polyHIPE hydrogels and also find a biocompatible nontoxic emulsifier as substitution to traditional surfactants, methyl myristate-in-water and soybean oil-in-water HIPEs solely stabilised by hydroxyapatite (HAp) nanoparticle were prepared. These Pickering- HIPEs were used as template to prepare polyHIPE hydrogels. Dextran-GMA, a water soluble monomer, was polymerised in the continuous phase of the HAp Pickering HIPEs leading to porous hydrogels with a tunable pore size varying from 1.5 μm to 41.0 μm. HAp is a nontoxic biocompatible emulsifier, which potentially provides extra functions, such as promoting hard tissue cell proliferation. HIPE-templated materials whose porous structure is maintained solely by the reversible physical aggregation between thermo-responsive dextran-b-polyNIPAAm block polymer chains in an aqueous environment (for this type of HIPE templated material we coined the name thermo-HIPEs) were prepared. No chemical reaction is required for the solidification of this porous material. This particular feature should provide a safer route to injectable scaffolds as issues of polymerisation/crosslinking chemistry or residual initiator fragments or monomers potentially being cytotoxic do not arise in our case, as all components are purified polymers prior to HIPE formation. Thermo-HIPEs with soybean oil or squalene as dispersed oil phase were prepared. Also in this HIPE system it was possible to replace the original surfactant Triton X405 with colloidal HAp nanoparticles or pH/thermo-responsive polyNIPAAm-co- AA microgel particles. The pore sizes and the mechanical properties of colloidal particles stabilised thermo-HIPEs showed improvement compared with thermo-HIPEs stabilised by Triton X405. In summary new injectable polyHIPEs have been prepared which retain their pore morphology during injection and can be solidified by either a thermal or ion (Ca2+) or chelating ion (Ca2+) stimulus. The materials used are intrinsically biocompatible and thus makes these porous injectable scaffolds excellent candidates for soft tissue engineering

Structure of nanoparticles embedded in micellar polycrystals

We investigate by scattering techniques the structure of water-based soft composite materials comprising a crystal made of Pluronic block-copolymer micelles arranged in a face-centered cubic lattice and a small amount (at most 2% by volume) of silica nanoparticles, of size comparable to that of the micelles. The copolymer is thermosensitive: it is hydrophilic and fully dissolved in water at low temperature (T ~ 0{\deg}C), and self-assembles into micelles at room temperature, where the block-copolymer is amphiphilic. We use contrast matching small-angle neuron scattering experiments to probe independently the structure of the nanoparticles and that of the polymer. We find that the nanoparticles do not perturb the crystalline order. In addition, a structure peak is measured for the silica nanoparticles dispersed in the polycrystalline samples. This implies that the samples are spatially heterogeneous and comprise, without macroscopic phase separation, silica-poor and silica-rich regions. We show that the nanoparticle concentration in the silica-rich regions is about tenfold the average concentration. These regions are grain boundaries between crystallites, where nanoparticles concentrate, as shown by static light scattering and by light microscopy imaging of the samples. We show that the temperature rate at which the sample is prepared strongly influence the segregation of the nanoparticles in the grain-boundaries.Comment: accepted for publication in Langmui

Understanding the role of MAM molecular weight in the production of PMMA/MAM nanocellular polymers

Nanostructured polymer blends with CO2-philic domains can be used to produce nanocellular materials with controlled nucleation. It is well known that this nanostructuration can be induced by the addition of a block copolymer poly(methyl methacrylate)-poly(butyl acrylate)-poly(methyl methacrylate) (MAM) to a poly(methyl methacrylate) (PMMA) matrix. However, the effect of the block copolymer molecular weight on the production of nanocellular materials is still unknown. In this work, this effect is analysed by using three types of MAM triblock copolymers with different molecular weights, and a fixed blend ratio of 90 wt% PMMA and 10 wt% of MAM. Blends were produced by extrusion. As a result of the extrusion process, a non-equilibrium nanostructuration takes place in the blends, and the micelle density increases as MAM molecular weight increases. Micelle formation is proposed to occur as result of two mechanisms: dispersion, controlled by the extrusion parameters and the relative viscosities of the polymers, and self-assembly of MAM molecules in the dispersed domains. On the other hand, in the nanocellular materials produced with these blends, cell size decreases from 200 to 120 nm as MAM molecular weight increases. Cell growth is suggested to be controlled by the intermicelle distance and limited by the cell wall thickness. Furthermore, a theoretical explanation of the mechanisms underlying the limited expansion of PMMA/MAM systems is proposed and discussed

Design rules for self-assembled block copolymer patterns using tiled templates

Directed self-assembly of block copolymers has been used for fabricating various nanoscale patterns, ranging from periodic lines to simple bends. However, assemblies of dense bends, junctions and line segments in a single pattern have not been achieved by using sparse templates, because no systematic template design methods for achieving such complex patterns existed. To direct a complex pattern by using a sparse template, the template needs to encode the key information contained in the final pattern, without being a simple copy of the pattern. Here we develop a set of topographic template tiles consisting of square lattices of posts with a restricted range of geometric features. The block copolymer patterns resulting from all tile arrangements are determined. By combining tiles in different ways, it is possible to predict a relatively simple template that will direct the formation of non-trivial block copolymer patterns, providing a new template design method for a complex block copolymer pattern.Samsung Scholarship FoundationSemiconductor Research CorporationTokyo Electron LimitedTaiwan Semicondcutor Manufacturing CompanyNational Science Foundation (U.S.) (Award DMR1234169

Electrodeposition of mesoporous Ni-rich Ni-Pt films for highly efficient methanol oxidation

The use of soft templates for the electrosynthesis of mesoporous materials has shown tremendous potential in energy and environmental domains. Among all the approaches that have been featured in the literature, block copolymer-templated electrodeposition had robustness and a simple method, but it practically cannot be used for the synthesis of mesoporous materials not based on Pt or Au. Nonetheless, extending and understanding the possibilities and limitations of block copolymer-templated electrodeposition to other materials and substrates is still challenging. Herein, a critical analysis of the role of the solution's primary electroactive components and the applied potential were performed in order to understand their influences on the mesostructure of Ni-rich Ni-Pt mesoporous films. Among all the components, tetrahydrofuran and a platinum (IV) complex were shown to be crucial for the formation of a truly 3D mesoporous network. The electrosynthesized well-ordered mesoporous Ni-rich Ni-Pt deposits exhibit excellent electrocatalytic performance for methanol oxidation in alkaline conditions, improved stability and durability after 1000 cycles, and minimal CO poisoning

Printing studies with conductive inks and exploration of new conducting polymer compositions

In addition to low cost and high volume, continuous production of devices such as transistors and RFID tags, printable electronics show promise in the fabrication of a multiplicity of sensors, displays, photovoltaic arrays, smart cards, etc. Due to flexibility and insensitivity to substrates, the use of organics in printed electronics has opened up a number of new opportunities in novel applications. In the present work, the process capability of flexography and offset lithography for patterning conductive materials was determined using small scale equipment (rotary letterpress and duplicator respectively). Process parameters including: type of substrate, line widths, line gaps, print thickness, directional effects, etc. were investigated. It was thus shown that the high volume printing processes of offset lithography and flexography can be used to obtain functional printed conductive patterns. In order to have greater control over ink composition and physical characteristics than was afforded by commercially available silver metal filled conductive inks, polyaniline (PANI) was synthesized by interfacial polymerization. Printable flexographic inks were formulated therefrom and a PANI ink was used in the flexographic printing of a working gas sensor. The conductivity of these inks was lower than that of silver filled metallic inks. This mitigated their utility in their utility in the printing of functional RFID antennae. Poly (thiophene-2, 5-diyl) (PT) and its derivatives are perhaps the most extensively studied class of conducting polymers and find applications in a variety of organic electronic devices. In the present work, an unprecedented approached to the synthesis and formulation of solution processible polythiophene (PT) compositions was explored. Conducting composites of polythiophene were synthesized by oxidative coupling of bithiophene, catalyzed by Fe3+ bound to the amphiphilic segment of functional block copolymers. Thus, amphiphilic block copolymers such as polystyrene-b-polyethylene oxide (PS-PEO) and polystyrene-b-polyacrylic acid (PS-PAA) complexed with Fe3+ were utilized as templates in the formation of soluble/redispersible prototype inks. The distribution of the conductive phase is, in principle, determined by the morphology of the block copolymer. The composites were characterized by DSC, UV-vis and IR spectroscopy. PT formed in the presence of these amphiphilic block copolymers was oxidised using suitable doping agents. The compositions however failed to exhibit significant conductivity. A number of challenges must be overcome in order to realize the potential economic benefits of using organic polymers in large scale electronic printing applications. The conductivity of inks based on organic conducting polymers can be increased by increasing the overall volume fraction of the conductive entity. The adhesion of the PANI compositions on various substrates could be improved by addition of a binding agent at a level that does not adversely affect the conductivity of the inks. Opportunities afforded by a post treatment/curing step may be considered and explored. Lastly, the ink formulation parameters and printing process variables should be optimized