There is no global challenge worth greater investment than improving quality of life. During initial discussions, we identified a wide range of problems that we felt warranted further scientific development: increasing crop yields; sewage filtration; reclamation of rare earth metals. Upon evaluation, the team decided that synthesizing a modular biosensor detection kit would be most influential, due to the potential application to a wide range of diseases and environmental health issues. This affordable, accessible system could tackle multiple issues over a large demographic, making the venture truly worthwhile. Lyme disease, although not at the forefront of discussion, was the inceptive focus of the investigation, as current detection methods can only be applied after debilitating symptoms have manifested. However, upon reviewing data gathered from primary research and conferring with Lyme disease experts, we determined that diagnosis of another spirochetal disease would be more appropriate for our device. When surveying members of the public in Lyme disease hotspots, the results showed a distinct lack of knowledge of both symptoms and prevalence, but more importantly a distrust in self-testing. Furthermore, Dr Tim Brooks, Director of Public Health England Rare and Imported Pathogens Laboratory, identified a very significant issue with implementing our technology to diagnose Lyme disease directly from blood samples. Because of this, our previously secondary focus, leptospirosis, became the primary target for our diagnosis tool.

We are developing our device as a frontline diagnosis kit for leptospirosis infection in developing countries. The adaptable nature of the bio-detector could allow replacement of the expensive antibody-reliant detection systems currently used. We also aim to modify this technology such that it can be used to monitor toxic lead and mercury levels in water supplies.

Our detection system for infectious agents and environmental pollutants will be based on CRISPR/Cas9 technology, relying on conformational changes in an RNA-based sensor that will trigger transcriptional regulation by a dCas9 protein. We plan to produce a modular gene circuit that can detect the presence of either RNA from an infectious agent or metallic ion and output a fluorescent signal. The RNA sensor will be a modified sgRNA containing a motif binding either Borrelia/Leptospira RNA or lead/mercury aptamers. This binding will cause a conformational change such that the dCas9 enzyme may bind upstream of the transcriptional start site of a fluorescent reporter gene inducing transcription. Afterwards, the sensor will be freeze-dried onto a paper scaffold for ease of use.

We hope to create a paper based sensor that will be able to be used in a low-tech, out-of-lab, environment. We hope this will make it available to less economically developed countries as a frontline diagnostic tool and make a real impact in the fight against infectious diseases and pollution.

Through this system, it is possible with small changes to create a simple detection system that is capable of taking single inputs and activating multiple genes.

By modifying the structure of the sgRNA so that the RBP handle is misfolded under normal conditions, the activation of the reporter gene becomes dependent on the refolding of this handle. The handle can be reformed upon the introduction of a specific single stranded RNA that binds, changing the conformation of the sgRNA. This "sRNA" can be tailored to almost any specification. By editing the RBP handle so that it reforms in the presence of sRNA from bacteria, it becomes possible to create a detection kit for bacterial infection.

For our current system, we are aiming to target Leptospirosis, aiding in the diagnosis of this disease. We are also looking into incorporating metal aptamers into the design such that our sensor can detect hazardous levels of heavy metals, creating a portable paper-based water monitor.

Incorporating a metal aptamer in the 5' end of the sgRNA in such a way that it prevents the binding of dCas9 to the sgRNA, allows this metal sensing to occur. When a metal ion binds to the aptamer, the aptamer changes conformation, exposing the previously bound RNA in the 20nt targeting site and dCas9 handle. This de-represses the dCas9 action, allowing the system to activate expression of the reporter gene.