The overarching goal of our research is to identify and characterise the protein kinase signalling pathways that control stem cell pluripotency and differentiation and determine how protein kinase signalling is disrupted to cause human developmental disorders. . Read more
The project will be undertaken at the recently funded multidisciplinary Robotics, Control and Artificial Intelligence (MOCAI) research laboratory. Read more
Context of the research activity. Motivations and objectives of the research in this field. Vehicle electrification and autonomous driving require extensive testing for human-vehicle interfaces and human acceptance. Read more
Prediction of human activities is an essential task in practical human-centered robotics applications, such as assisted living, healthcare, human-robot collaboration and entertainment and immersive platforms. Read more
Help shape new policies and regulatory priorities for pollution control and protect human health and the environment from harmful chemical pollution. Read more
The focus of the Nerlov laboratory is combining single cell biology (single cell RNAseq, ATACseq and functional analysis) with advanced mouse genetics to study hematopoietic stem– and progenitor cells in normal development and during ageing. Read more
The focus of the Nerlov laboratory is combining single cell biology (single cell RNAseq, ATACseq and functional analysis) with advanced mouse genetics to study hematopoietic stem– and progenitor cells in normal development and during ageing. Read more
Robots work effectively in factories. For example, in car factories, huge robotic arms pick up car parts and join them to the skeleton of the car, working at less than millimetre and millisecond precision. Read more
Applications are invited for a self-funded, 3 year full-time or 6 year part-time PhD project. The PhD will be based in the Strategy, Enterprise and Innovation Subject Group and will be supervised by. Read more
The purpose of this research project is to model the human brain and develop a memory mechanism based on next-generation Artificial Intelligence (AI) algorithms. Read more
De novo mutations (DNMs) are a significant contributor to human disease, affecting ~1:300 new births. We study the mechanisms by which these spontaneous mutations arise in the first instance, concentrating on the tissue where most originate, the human testis. Read more
De novo mutations (DNMs) are a significant contributor to human disease, affecting ~1:300 new births. We study the mechanisms by which these spontaneous mutations arise in the first instance, concentrating on the tissue where most originate, the human testis. Read more
Errors that occur during cardiac development cause congenital heart defects (CHD). Despite the prevalence of CHD, the developmental processes that ensure the heart forms correctly are still being elucidated. Read more
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