Detection and elimination of disease-causing agents, and early detection of disease markers are two major strategies employed in protecting the human health and wellbeing. In the current project, we addressed both challenges from the materials science point of view. We resorted to fairly recent classes of materials called covalent organic polymers (COPs) and covalent organic frameworks (COFs) and prepared new types of materials whose structures enabled them to function as sensors for bacteria, or as detectors of low-oxygen environment in human cells.
Rapid detection of biological organic matter is essential in prevention of diseases caused by biological agents such as viruses, bacteria and fungi. The primary infections of drug-resistant bacteria alone cause approximately five million deaths annually, making such infections the third leading cause of mortality globally. Moreover, secondary bacterial infections that follow various viral infections, such as Covid-19, are also lethal. Therefore, developing efficient bacteria detection methods is of great scientific, medical, forensic, biodefense, and food safety interest. Conventional methods of bacterial detection involve classical culturing techniques that require several handling steps, or advanced scientific equipment including polymerase chain reaction (PCR) to detect nucleic acids and enzyme-linked immunosorbent assay (ELISA) to monitor antigen-antibody interactions. These methods are highly accurate and specific, but they also face several drawbacks. They are laborious, time-consuming, expensive, require trained operators, and fail to detect microorganisms in real-time or outside the laboratory. Thus, there is a pressing need for inexpensive, easily operable, rapid, label-free and portable detection methods that give a quantitative readout. The objective of our project was, therefore, to develop a polymeric material that is stable in the physiological environment where bacteria are found and is responsive to their presence. Furthermore, we aimed to build a setup based on this material that would enable fast detection and would be easy to operate. Rather than developing a sensor for a particular species of bacterium, we were interested in detecting bacterial cells in aqueous media in general.
When diseases are not caused by a particular agent that could be detected prior to entering the human body, such as a bacterium, detecting disease markers can be of major importance in slowing down the progress of the disease. Hypoxia is a physiological condition defined by inadequate oxygen supply to body tissues. This condition can be seen as a disease marker as it, for instance, allows for early-stage cancer diagnostics while other medical imaging tools require comparably larger sizes of tumors for diagnostics. Furthermore, detecting hypoxia is also relevant in the pathogenesis of the chronic renal disease, progression of rheumatoid arthritis, and blood vessel plaque vulnerability. Current detection of hypoxia relies on expensive imaging tools such as magnetic resonance imaging (MRI). Within the scope of this project, we aimed to develop a fluorescence-based material that could aid in detecting hypoxic conditions in human cells.
