Chemical and Biomolecular Engineering - Theses
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ItemBiologically compatible thin films by click chemistry( 2010)The assembly of materials by the Layer-by-Layer (LbL) method provides a versatile and flexible method of assembling nanoscale structures with tailored composition, thickness, size, shape and functionality. Many conventional methods of assembling materials such as thin films and hollow polymer capsules fall short in achieving versatile, covalently bound multilayers. Combining click chemistry, a highly efficient and specific set of reactions, with the established LbL technique provides a number of advantages for the preparation of thin films and hollow polymer capsules. The click-LbL approach permits the production of stable, tailored and functionalisable materials through the modular assembly of a variety of building blocks. This thesis focuses on developing biologically compatible thin films and capsules by the click- LbL technique. Specifically, this work aims to: (i) investigate the fundamental factors controlling the growth and characteristics of click-LbL films; (ii) develop stable, biocompatible films; (iii) demonstrate that click chemistry is a facile and flexible means of functionalising multilayer films; and (iv) demonstrate that click-LbL films are capable of performing specific roles within biological systems. This will be demonstrated through a fundamental study on the assembly of thin films and capsules through assembly of alkyne- and azide-functional poly(acrylic acid) building blocks by the click-LbL technique. The technique is then extended to the assembly of covalently bonded films comprised solely of poly(ethylene glycol) (PEG) acrylates that limit the adsorption of serum proteins. By functionalising click-LbL films of PEG with a cell adhesion promoting peptide, these films then demonstrate the specific adhesion and growth of cells onto a surface. Multilayer films are also assembled using temperature-responsive PEG methacrylate copolymers and their ability to resist the adsorption of proteins from human serum is tested. Hollow capsules comprised of poly(N-vinyl pyrrolidone), with demonstrated low-cytotoxicity, are then produced by multilayer assembly onto colloidal silica. These capsules are covalently stabilised through a click-functionalised cross-linking agent, which can be cleaved under reducing conditions, to deconstruct capsules. The demonstrated properties of click-LbL films and capsules presented herein, offer potential for chemical engineering, pharmaceutical and in particular, biological applications.