Cancer medicine experiences currently a strong need for sensitive, robust and affordable diagnostic tools that can sense cellular states early during disease progression. In BioCapture we have addressed this need while harnessing novel molecular capture technology targeting tumor specific markers. Molecularly imprinted polymers (MIPs) and “plastic antibodies” and other smart materials have been developed and used to detect previously inaccessible tumor markers and to discover novel disease biomarkers. The project engaged 11 ESRs full time within a time frame of four years. The research performed was highly interdisciplinary comprising molecular imprinting, materials chemistry, optical sensor technology, proteomics and diagnostics.
The objectives of Bioacapture were to:
• prepare 11 young researchers for a succesfull career in industry and academia.
• develop proteomics capture phases for unstable post-translational modifications (PTMs) and PTM peptide sequence motifs.
• develop imprinted capture phases for lung cancer biomarkers
• develop saccharide specific capture phases.
• develop addressable fluorescent MIPs.
• develop high throughput multiplex assays.
• validate the novel diagnostic tools using clinical samples
• establish long lasting collaborations among polymer/materials, proteomics and clinical researchers.
Main conclusions:
We have progressed beyond expectation towards our goals to develop affinity based tools and reagents. Robust peptide- and PTM- specific capture materials compatible with proteomics work flows and MS have been used to develop assays with a potential diagnostic value. We have also advanced well on a fundamental materials, analytical and cell biology science level. A detailed macroscopic and molecular level characterisation of the imprinted receptors have increased our understanding of the nature of the binding sites and how they are formed. Finally, genetically engineered cell libraries has provided a perfect model system for imitating cancer cells and for probing receptor binding affinity and specificity.