Materials in contact with the biological milieu (biomaterials) spontaneously and nonspecifically adsorb constituent proteins which may lead to unwanted cell adhesion and responses or hinder device performance. These interactions and their related phenomena lead to complications in ~3% of implant surgeries. Thus, resistance to these nonspecific interactions is critical to the performance of many implanted biomaterials and biosensing surfaces. Further, these interactions have widespread importance to industrial materials in contact with biological environments such as food packaging, and agricultural and nautical surfaces.
Thin film coatings of antifouling polymers are one of the leading methods for reducing nonspecific interactions. Both polymer composition (chemical composition and molecular weight) and polymer grafting density are the principal determinants of coating performance. For applications requiring specific bioactivity, such as selective ligand-analyte interactions for sensors, the polymer coating must remain antifouling and be amenable to functionalization with capture ligands. Tethered polymer coatings can be made by surface initiated polymerization (“graft-from”) which results in higher density coatings, but complex fabrication limits commercialization and capacity of functionalization with capture ligands. Simpler “graft-to” procedures, where pre synthesized polymers are immobilized to a surface, are more amenable to translation but suffer from inferior antifouling properties due to lower density coatings. New fabrication methods are therefore required to improve both graft-to and graft-from coatings.
Herein, the effects of polymer density on material performance are explored and leveraged to produce novel functional surfaces using two classes of polymers, namely amphiphilic and thermoresponsive poly(oligo(ethylene glycol)) methyl ether methacrylate, and zwitterionic, functionalizable poly(carboxybetaine methacrylamide) (pCB), as well as copolymers thereof. Specifically, polymer grafting techniques which exploit grafting density effects on surfaces were developed, leading to surfaces: 1) that are both high-loading and antifouling due to two different grafting densities within bimodal architectures, and (2) with enhanced anti-fouling properties despite being prepared via a “grafting-to” method using shrinkable or expandable substrates. Interestingly, shrinking substrates with antifouling polymers resulted in a novel LSPR biosensor with high translation potential.
Chapter 2 describes the pH controlled, one-pot production of two-layer brushes composed of an antifouling dense layer and a high-loading lower density layer where capture ligand immobilization was improved by 6 times compared to a single high density layer. Towards improving fouling and bioactivity of graft-to surfaces, Chapter 3 describes the first demonstration of Graft-then-Shrink where a stretched polystyrene (PS) substrate coated in a thin gold layer modified with thiol-terminated pCB was thermo-shrunk to one sixth in footprint to increase polymer surface coating content for enhanced antifouling properties and the production of micro/nano gold wrinkles to generate a localized surface plasmon resonance (LSPR) active surface. The low-cost sensors can
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detect biomolecular interactions by tracking changes in absorbance in the visible spectrum using ubiquitous plate readers. In Chapter 4, Graft-then-Shrink was extended to elastomeric materials, where thiol terminated polymers were grafted onto solvent swollen silicone via thiol-maleimide click chemistry, producing strongly antifouling materials.
Taken together, these developments represent significant advances in the preparation and application of antifouling polymer coatings towards the improvement of antifouling surface properties of medical devices and resulted in the development of a novel, low-cost LSPR sensor without the need for specialized equipment. / Thesis / Doctor of Philosophy (PhD) / When a material, such as a medical implant or sensor, is placed in contact with tissues and biological fluids, biomolecules stick to the exposed surfaces through nonspecific interactions. It is important to minimize nonspecific interactions because they can lead to bacterial infections, inflammation, implant failure and loss of device performance. Coatings to minimize nonspecific interactions therefore remain an active area of research. In this thesis, we explored new methods to create biomolecule and cell repellent coatings of long, chainlike molecules known as polymers grafted onto surfaces. Specific types of polymers, known as antifouling, were particularly effective at reducing these interactions.
Although it is important to block nonspecific interactions, many devices require bioactive surfaces through selective interactions. For example, sensors for analysis of blood products require the selective binding of the target ligand with minimal binding of non-target agents. To this end, functionalizable antifouling polymers are often modified with a capture or binding agent corresponding to the target ligand. Polymer coatings which are both antifouling and functionalizable for specific interactions, are called “romantic” because of their selective love of a single interaction. To synthesize these romantic polymer coatings, two main methods have been reported: 1) “grafting-from” where the polymer is grown from the surface, producing a very dense coating, and 2) “grafting-to” where the polymer is synthesized in solution, and then immobilized onto the material surface, which produces coatings of lower density. For antifouling polymer coatings to be as effective as possible, polymers should be tethered densely on the material surface, but to maximize the loading of capture agents, polymer density must be lower to allow for grafting within the layer. Further, the grafting-from method is typically more synthetically challenging hindering commercialization.
To improve the selective bioactivity of graft-to and graft-from coatings as well as antifouling properties of graft-to coatings, we present two methods to improve the specific bioactivity of anti-fouling polymer coatings and the first description of Graft-then-Shrink, a method to enhance the antifouling properties of graft-to coatings for medical implants and label-free in vitro sensors. For graft-from coatings, we produced a hierarchical romantic surface that consists of two polymer layers, the lower of which is dense and antifouling, and the upper of which is low-density and can accommodate high-levels of bioactive agents, resulting in a best of both worlds; the density of the layers is controlled by a novel pH controlled polymerization procedure. A method to improve the less labor intensive “grafting-to” strategy was then devised, called “Graft-then-Shrink” where the antifouling polymers are grafted onto a shrinkable material, and then the material is shrunk, leading to an increase in grafted polymer content over grafting-to alone. This method was successfully applied to a heat shrinkable material and an elastomeric silicone material, a common material for medical devices, for improved antifouling properties. Finally, a method for combining the Graft-then-Shrink technique
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with a novel localized surface plasmon resonance (LSPR) biosensor was found, that provides a simple route to access romantic surfaces on high-sensitivity, easy to fabricate LSPR biosensors. Together, these fabrication methods will simplify and expedite the translation of antifouling and romantic surfaces for medical devices and sensors.
| Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/27974 |
| Date | January 2022 |
| Creators | Jesmer, Alexander |
| Contributors | Wylie, Ryan, Chemical Biology |
| Source Sets | McMaster University |
| Language | English |
| Detected Language | English |
| Type | Thesis |
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