Refining blood sampling in mice
We've developed a minimally invasive method of blood sampling, which allows multiple samples to be taken from the same animal with as little stress as possible.
Exploring our research and other stories from the University community.
We've developed a minimally invasive method of blood sampling, which allows multiple samples to be taken from the same animal with as little stress as possible.
Scanning probe microscopes let us study surfaces at the nanoscale level. But how do they work and why do we need them? Physics researchers tell us more.
Developmental geneticist, Dr Kim Moorwood, explores how the genes behind fetal growth could impact our chances of serious health conditions in later life.
Dr Philippe Blondel from the Department of Physics is uncovering the secrets of the deep and imaging our underwater environments with sound waves.
From navigating avian romance to engaging local communities, Professor Tamás Székely’s research group aims to protect wildlife and preserve biodiversity.
From telecoms to healthcare, fibre optics are an essential tool in photonics research. But how are they made, and what exactly do they do?
Our researchers developed a large-scale computer simulation model that provides a flexible platform for developing models for predicted exposures.
Bath researchers are building model tumours to learn how pancreatic cancer affects nerve cells and find new therapies to target tumour growth and patient pain.
Despite their simple appearance, the maths behind Stokes waves is complex. Researchers from the Department of Mathematical Sciences set out to learn more.
How zebrafish have been used in our research to better understand a human disease gene associated with skin and pigment diseases.