The synthesis of well-defined polymer nanoparticles will have immediate applications in the biomedical industry as nanocontainers for the controlled delivery and release of water insoluble drugs. The ability to control molecular weight, particle morphology and chemical functionality and to obtain polymeric nanoparticles with narrow molecular weight and particle size distributions is paramount for their application-specific design. Two synthetic approaches were investigated in the synthesis of well-defined polymer nanoparticles, emulsion polymerization and self assembly. The successful implementation of Reversible Addition-Fragmentation Chain Transfer (RAFT) in emulsion polymerization was the first challenge faced when controlling nanoparticle molecular weight and size. Initially we showed that successful ‘living’ emulsion polymerizations of styrene could be carried out using a non-ionic surfactant. The success was achieved when preparing polymers of low molecular weight (5 and 9 K targeted Mn’s with polydispersities (PDIs) below 1.2). Deviation from ideal ‘living’ behavior occurred when targeting Mn’s greater than 20 K (at 100 % conversion). The ‘degassing technique’ was then investigated as an avenue to generate stable polystyrene nanoparticles by emulsion polymerization without the addition of surfactant (residual surfactant can result in detrimental effects on product quality). The polymerization of this emulsion system in the presence of a low reactive RAFT agent was ‘living’ in nature. In the presence of a high reactive RAFT agent the emulsion system showed ‘living’ nature, however, secondary nucleation occurred, which resulted in broad molecular weight distribution (MWD). Thus, the emulsion polymerization approach to preparing well-defined polymer nanoparticles was giving less than desirable results. An alternative method to prepare polymer nanoparticles with controlled chemical composition and morphology is to self assemble pre-synthesized block copolymers in water. This approach has several significant advantages over the emulsion systems: (i) all polymer chains are of near uniform chain length and chemical composition, (ii) the ratio between the hydrophobic and hydrophilic polymers can easily be controlled, (iii) chemical functionality can be located in different morphological regions, (iv) a wide range of 3-dimensional structures apart from spheres can be prepared (i.e. rods and vesicles), and (v) additives such as surfactant, stabilizers and residual monomer usually found after an emulsion polymerization are not required in the self assembly methodology. These advantages justify our shift in strategy. The only disadvantage of the self assembly process is that one cannot reach high weight fractions of polymer in water and is usually limited to below 2 wt-%, where as emulsion polymerizations can allow weight fractions of polymer close to 50 wt-%. Well-defined amphiphilic 4-arm star polyacrylic acid-block-polystyrene (PAA-b-PSTY) copolymers, prepared by RAFT solution polymerization, were dispersed in water to form core-shell micelles, in which the shell consisted of tethered PAA loops. The entropic penalty for having such loops resulted in a less densely packed PSTY core when compared to linear diblock copolymers of the same arm length. The surface of the shell was irregular due to the tethering points, but when cleaved the PAA chains extended to form a regular and relatively uniform corona. Controlling the polymer architecture enabled the synthesis of polymer micelles with tethered PAA loops, which could be opened to form uniform corona when desired. Three-miktoarm star and dendrimers with miktoarms consisting of PSTY, polytert-butyl acrylate (PtBA), polymethyl acrylate (PMA) and PAA were then synthesized using a combination of Atom Transfer Radical Polymerization (ATRP) and Huisgen 1,3-dipolar cycloaddition ‘click’ reactions. In all reactions, the stars and dendrimers were well-defined with PDIs lower than 1.09. This was the first step in the synthesis of well-defined highly ordered polymer structures. The synthesis of such structures demands high level of purity at each synthetic step eliminating the possibility of side reactions, which as of consequence lowers product yields. The synthesis and use of reactive solid supports to remove excess linear polymer to increase the yields of polymeric 3-arm stars and dendrimers was employed. These supports are a cheap approach to scavenge polymeric species with either azido or alkynyl functionality, after which the solid support can be filtered away from the product. These supports aided the synthesis of 3rd generation polymeric dendrons and dendrimers consisting of homopolymer PSTY with either solketals or alcohols at the periphery, diblock PSTY and PtBA, and amphiphilic diblock. The methodology used to construct these structures was a combination of ATRP to produce linear polymers with telechelic functionality, with the subsequent use of this functionality to join the polymers together via ‘click’ reactions. Micellization of the amphiphilic structures in water produced polymer nanoparticles of uniform size. The dendrimer nanoparticles were 18 nm in diameter, consisting of 19 individual dendrimers. The dendrimers most probably have no mutual interpenetration and thus pack uniformly to form the micelles. The dendron nanoparticles were 21 nm with an aggregation number of 43 dendrons per micelle, which suggests they form cone-like structures and self-assemble to form crew-cut micelles. Using a convergent approach polymer structures with unprecedented chemical diversity (hydrophobic or amphiphilic) and complexity (G2 miktoarm dendrimers with a degradable core) consisting of PSTY, PMA, PtBA and PAA were then synthesized with high purity using copper wire as the ‘click’ catalyst.
Identifer | oai:union.ndltd.org:ADTP/253980 |
Creators | Carl Urbani |
Source Sets | Australiasian Digital Theses Program |
Detected Language | English |
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