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Fibrosis is a common feature of many forms of heart disease. Despite the recognised central role of reactive oxygen species (ROS) in cardiac fibrosis, antioxidant approaches have failed in clinical trials. We have discovered a new mechanism for ROS-mediated fibrosis that is depleted in human heart failure, and will test an innovative therapeutic approach that is imminently translatable given the development by members of our team of a specific peptide blocker effective in blocking this pathway.
Dysfunctional blood vessel growth is an important mechanism of many congenital vascular diseases and other postnatal diseases such as ischemia and cancer. Cerebral cavernous malformations (CCMs) are common vascular disease in brain that cause strokes and seizures in midlife. Due to their location in the brain, CCMs are virtually untreatable, making the development of novel therapies a priority. This proposal aims to understand how the molecular players underlying this brain vascular disease cont ....Dysfunctional blood vessel growth is an important mechanism of many congenital vascular diseases and other postnatal diseases such as ischemia and cancer. Cerebral cavernous malformations (CCMs) are common vascular disease in brain that cause strokes and seizures in midlife. Due to their location in the brain, CCMs are virtually untreatable, making the development of novel therapies a priority. This proposal aims to understand how the molecular players underlying this brain vascular disease control blood vessel function and growth.Read moreRead less