Publication
The development of innovative bioanalytical technologies that enable the discovery of new therapeutics or the creation of systems for rapid, accurate and parallel analyses has gained an extraordinary interest in the biomedical sector in the last 10-15 years. Since proteins are the key-targets for such essential discoveries and developments, a particular emphasis has been placed on proteomics (study of proteins), including the investigation of protein structures, changes of protein expression upon treatment of cellular systems, the role of post-translational protein modifications on cell signaling events and the validation of selected proteins as disease-specific markers or pharmaceutical targets. These studies usually aim at using crude biological samples as the starting materials, which typically contain a large variety of proteins at concentrations covering a wide dynamic range and where the low abundant proteins are often the biologically most relevant. Therefore, the challenge is to create analytical tools which are able to cope with this large protein concentration range and which provide sufficiently high sensitivity to measure low abundant analytes in the presence of a high abundant protein matrix. The information that is expected from such technologies may soon exert a drastic change on the pace of medical research and considerably impact on the care of patients. As protein microarrays offer a powerful tool for the rapid, parallel analysis of complex samples and only require a minimal amount of reagents, they are currently one of the hot topics of life sciences, which strive to provide such analytical solutions. One of the current limiting factors in the field of protein microarrays for achieving the required analytical sensitivity is the amount of proteins that can be immobilized on the proteomic chip surface. Polymer brushes, which consist of an arrangement of polymer chains that are attached by one end to a substrate in a stretched, well-defined chain conformation, can increase the surface area available for protein binding, and thus act as a new category of 3D protein microarray substrates. With the advent of surface-initiated controlled polymerization techniques, extremely precise control over the thickness, composition, architecture and grafting density can be achieved, which allow to finely tune the properties of the polymer brush. In addition, these polymer chains may contain, natively or after specific post-polymerization reaction of their side chains, a high density of functional groups that can react with proteins. The different approaches available for the preparation of such surface-tethered polymer chains, the strategies allowing control over their architecture and properties as well as examples of applications related to protein binding are presented in Chapter 1. This Thesis describes the use of polymer brushes to create a new type of 3D proteomic chips, with the ultimate goal to improve the protein binding capacity compar