Most humans in modern societies are cardio-metabolically stressed and therefore suffer adverse cardiovascular and metabolic effects. Our cardio metabolic centre is already contributing strongly with the support of the British Heart Foundation and many other important funding agencies.
<p>Most humans in modern societies are cardio-metabolically stressed and therefore suffer adverse cardiovascular and metabolic effects depending on exposure, genetics, lifestyle and ageing. Significantly, 80% of people who develop the metabolic problem of diabetes die because of the cardiovascular complications caused by their diabetes. The complications are aggressive types of cardiovascular disease which increasingly feature in middle age and are more difficult to treat than cardiovascular disease in the absence of diabetes.</p> <p>As well as premature death, the complications lead to disabilities, reduced ability to work and reduced quality of life. The heart is impacted but the important vascular component means that implications span the whole body, ranging from intolerance to physical exercise, lower limb ulceration, accelerated arthritis, impaired auditory and visual acuity, renal failure, sexual dysfunction and dementia. The scale of this problem is truly enormous and strongly anticipated to increase in the UK and globally. For UK finances, the burden is 10% of the NHS budget and set to increase. Critically, current treatment options are limited and largely fail to address the problem.</p> <p>If the cardiovascular complications of diabetes are to be solved, short and long-term scientific progress is required alongside educational, health service and public health efforts. Our cardio metabolic centre is already contributing strongly with the support of the British Heart Foundation and many other important funding agencies. Teamwork is central to how we operate.</p> <p>Through this approach we are solving puzzles at the crux of the disease problem and seeing the ways in which these newly-discovered mechanisms are modulated in diabetes: how blood vessels control insulin sensitivity and respond when insulin sensitivity changes, how endothelium detects blood flow and achieves proportionate response, how blood clots are assembled and regulated and how beneficial responses to physical exercise arise. In patients we have shown the benefits of magnetic resonance imaging (MRI) for diagnosis of cardiovascular disease, the benefits of invasive coronary strategy in non-ST-segment myocardial infarction, the benefits of vitamin D in improving left ventricular function and the increased benefits of beta-blockers in diabetes.</p>
<p>To submit an application in this research area please complete an <a href="https://studentservices.leeds.ac.uk/pls/banprod/bwskalog_uol.P_DispLoginNon">online application form</a> and submit this alongside a research proposal, a full academic CV, degree transcripts (or marks so far if still studying) and degree certificates. If English is not your first language, you must provide evidence that you meet the Faculty’s minimum <a href="https://medicinehealth.leeds.ac.uk/faculty-graduate-school/doc/entry-requirements-1">English language requirements</a>.</p> <p><em>We welcome applications from all suitably-qualified candidates, but UK black and minority ethnic (BME) researchers are currently under-represented in our Postgraduate Research community, and we would therefore particularly encourage applications from UK BME candidates. All scholarships will be awarded on the basis of merit.</em></p>
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