Microplastics are increasingly found in human bodies, driven by everyday plastic use such as milk bottles. This research examines why consumers continue choosing plastic and identifies systemic barriers to reusable options. By improving affordability, convenience, and incentives, sustainable choices can become the default rather than the exception.

This research examines how real-world microplastics and nanoplastics affect human brain immune cells. Using plastics from everyday consumer items, it shows rapid cellular stress and mitochondrial damage linked to neurodegenerative disease. The findings suggest current laboratory studies may underestimate the true health risks of chronic plastic exposure.

This research reveals Heterobilharzia americana as a widespread, underdiagnosed parasitic threat to dogs in the US Southwest. Testing showed nearly 25% infection rates, often linked to river exposure. The Drake Project raises awareness and seeks prevention strategies to protect dogs from this deadly waterborne parasite.

PCBs, toxic “forever chemicals” found in older school buildings, accumulate in body fat and trigger harmful inflammation. This research shows that PCB-exposed fat cells recruit excessive immune cells, creating an uncontrolled inflammatory response that contributes to obesity and diabetes. Understanding this mechanism opens pathways for treatments targeting fat–immune cell communication.

My research tackles PFAS (polyfluoroalkyl substances) or “forever chemicals,” found in everyday products and linked to serious health risks. Blood testing shows 95% contamination rates. The project identifies specialised bacteria capable of breaking PFAS down nearly completely within days, offering a promising biological solution to reduce environmental and human exposure to these persistent toxic chemicals.