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The Diagnostics and Surveillance theme of the CDT will focus on the development and testing of rapid diagnostic tests, digital health and improved surveillance systems
Early detection and diagnosis of AMR is critical to antimicrobial stewardship, public-healthsurveillance and to prevent transmission. However, there remain many critical engineeringchallenges. For example, to determine antimicrobial resistance and susceptibility, current “gold-standard” methods often rely on bacterial culture in centralised laboratories requiring 36- to 72-hour turnaround times after sample collection. This is too slow for effective antibiotic stewardship inemergency settings or during short clinic visits. Lateral flow tests are emerging as an important toolfor public health, but many lack the sensitivity to detect early-stage infections, as well as the digitalconnectivity to link data into healthcare systems. Moreover, relatively little is known about theinterconnectedness of AMR in animals and the environment (e.g., wastewater), since most AMRstudies focus on cases in humans based on electronic patient records in hospitals.
There is anurgent need for new engineering solutions to tackle these challenges. These should cover the generation of rapid ultra-sensitive tests to detect AMR in a variety of decentralised settings (e.g.,GP surgeries, care homes, self-testing in the home, point-of-pen and wastewater surveillance),and also the need for improved surveillance of outbreaks bringing together siloed data setsbetween humans, animals and the environment using a One Health approach.
Research Theme Contacts:
Prof. Rachel McKendry & Dr.Mike Thomas
Example PhD Project
- Quantum sensors to detect AMR in wastewater.
Student UG/PGT background
Engineering, physical sciences
Project Details:
Wastewater-based epidemiology is emerging as a powerful tool to track AMR inpopulations, with the advantage of capturing the true burden of illness, including symptomaticand asymptomatic cases as well as hard-to-reach demographics. However, wastewater-basedepidemiology is notoriously challenging due to the complexity of the samples, the heavy dilutionof pathogens (down to few copies per litre) and the long times required for centralised laboratorytesting. In this PhD project, we will explore the use of a novel ultra-sensitive quantum sensor forrapid near-source testing and sentinel AMR surveillance. We will harness our recentbreakthrough in quantum nanodiamonds in a dipstick format. The PhD research will involve thedesign of primers to AMR targets of interest (e.g., E. coli or specific resistance genes),optimisation of surface capture chemistries and assays, sample collection and extraction,multiplexing, prototype development, data capture, a pilot field study and benchmarking to PCR
External Engagement
UK Health Security Agency
Project Impact
Use in national surveillance programmes, NHS, water companies.
Student Career Destination
UKHSA, SMEs, water management, NHS, academia.