Computational Biomedicine at the Exascale (CompBioMed-X)
Computational biomedicine offers many avenues for taking full advantage of emerging exascale computing resources and, as such, will provide a wealth of benefits as a use-case within the wider ExCALIBUR initiative. These benefits will be realised not just via the medical problems elucidated but also through the technical developments implemented to enhance the underlying algorithmic performance and workflows supporting their deployment. Without the technical capacity to effectively utilise resources at such unprecedented scale - either in large monolithic simulations spread over the equivalent of many hundreds of thousands of cores, in coupled code settings, or being launched as massive sets of tasks to enhance drug discovery or probe a human population - the advances in hardware performance and scale cannot be fully capitalised on. This project will seek to identify solutions to these challenges and communicate them throughout the ExCALIBUR community, bringing the field of computational biomedicine and its community of practitioners to join those disciplines that make regular use of high-performance computing and are also seeking to reach the exascale.
This project will deploy applications in three key areas of computational biomedicine: molecular medicine, vascular modelling and cardiac simulation. This scope and diversity of use cases mean that it will appeal strongly to the biomedical community at large. The project will demonstrate how to develop and deploy applications on emerging exascale machines to achieve increasingly high-fidelity descriptions of the human body in health and disease. In the field of molecular modelling, it will develop and deploy complex workflows built from a combination of machine learning and physics-based methods to accelerate the preclinical drug discovery pipeline and for personalised drug treatment. These methods will enable the development of highly selective small molecule therapeutics for cell surface receptors that mediate key physiological responses. Vascular studies will utilise a combination of 1D, 3D models and machine learning to examine blood flow through complex, personalised arterial and venous structures. The project will utilise these in the identification of risk factors in clinical applications such as aneurysm rupture and for the management of ischaemic stroke. Within the cardiac simulation domain, a new GPU accelerated code will be utilised to perform multiscale cardiac electrophysiology simulations. By running large populations based on large clinical datasets such as UK Biobank, the project aims to identify individuals at elevated risk of various forms of heart disease. Coupling heart models to simulations of vascular blood flow will allow assessment of how problems which arise in one part of the body (such as the heart) can cause pathologies on remote regions.
This exchange of knowledge will form a key component of CompBioMedX. Through this focussed effort, it will engage with the broader ExCALIBUR initiative to ensure that it takes advantage of the efforts already underway within the community and in return reciprocate through the advances made with this use case. Many biomedical experts remain unfamiliar with high-performance computing and need to be better informed of its advantages and capabilities. This project will engage pro-actively with medical students early in their career to illustrate the benefits of using modelling and supercomputers and encourage them to exploit them in their own medical research. It will engage in a similar manner with undergraduate bioscience students to establish a culture and practice of using computational methods to inform the experimental work underpinning the basic science that is the first step in the translational pathway from bench to bedside.
Principal Investigator
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