A new diagnostic test developed from research at the Universities of Cambridge and Dundee has been launched with the aim of helping eliminate the disease known as African sleeping sickness.
Artificial bile ducts grown in lab and transplanted into mice could help treat liver disease in children03 Jul 2017
Cambridge scientists have developed a new method for growing and transplanting artificial bile ducts that could in future be used to help treat liver disease in children, reducing the need for liver transplantation.
A common class of chemicals found everywhere from car exhausts, smoke, building materials and furniture to cosmetics and shampoos could increase cancer risk because of their ability to break down the repair mechanisms that prevent faults in our genes, according to a study published today in the journal Cell.
Study identifies hundreds of genes that influence timing of puberty and alter risk of several cancers24 Apr 2017
The largest genomic analysis of puberty timing in men and women conducted to date has identified 389 genetic signals associated with puberty timing, four times the number that were previously known.
A team of scientists who a few years ago identified a major pathway that leads to brain cell death in mice, have now found two drugs that block the pathway and prevent neurodegeneration. The drugs caused minimal side effects in the mice and one is already licensed for use in humans, so is ready for clinical trials.
The University of Cambridge has been announced as one of the centres that will form the UK Dementia Research Institute (UK DRI) alongside Cardiff University, the University of Edinburgh, Imperial College London and King’s College London.
Scientists at the University of Cambridge have succeeded in growing miniature functional models of the lining of the womb (uterus) in culture. These organoids, as they are known, could provide new insights into the early stages of pregnancy and conditions such as endometriosis, a painful condition that affects as many as two million women in the UK.
Scientists have determined the first 3D structures of intact mammalian genomes from individual cells, showing how the DNA from all the chromosomes intricately folds to fit together inside the cell nuclei.