Unravelling the mechanisms of cardiac fibrosis will lead to the discovery of therapeutic target candidates for various cardiac diseases. FIBRO-TARGETS brings together eleven European expert teams from six different countries both from public research institutes and European biotechs. This is the second EU funding in heart failure for Inserm; the first one was launched last February: HOMAGE (for Heart OMics in AGEing – which aims to validate specific biomarkers of heart failure). All 11 partners convened in Amsterdam on September 3rd, for the kickoff of the FIBRO-TARGETS project.
Beyond and in addition to a diseased heart muscle, myocardial interstitial fibrosis (MIF) is one of the key mechanisms of cardiac remodelling. Cardiac fibrosis contributes to cardiac tissue stiffness. It results from the excessive accumulation of proteins that make up the extracellular matrix. As a consequence, diastolic and systolic cardiac functions are altered which, over time, results in symptomatic heart failure (HF), with breathlessness, fluid congestion, oedema and fatigue. Heart failure is a serious disease since it is often irreversible. It is estimated that more than 6.5 million people suffer from heart failure in Europe. It is the leading cause of hospitalization for patients over the age of 65. The incidence is increasing at an alarming rate because of an aging population and the burden of cardiovascular risk factors (diabetes, obesity and high blood pressure). Early interventions targeting key mechanisms, including myocardial interstitial fibrosis, could slow down progression to heart failure.
Using the large amount of data amassed by the FIBRO-TARGETS consortium, myocardial interstitial fibrosis was identified as a major therapeutic target for the prevention and treatment of heart failure. The FIBRO-TARGETS project therefore aims to accurately identify the main mechanisms involved in MIF and to define therapeutic approaches that target these mechanisms. Cardiac fibroblasts (specific cells in cardiac muscle) make up between 60 – 70 % of all cardiac cells and are the main source of the extracellular matrix proteins responsible for fibrosis. Since these mechanisms have been identified, direct intervention can be performed on fibroblast proliferation and on the composition of extracellular matrix using molecules with potential therapeutic benefits: preventing, repairing or slowing down cardiac remodelling.
"In addition, until now, the only means of quantifying fibrosis was a biopsy, an invasive and inaccurate method used to estimate the total degree of cardiac fibrosis. Over the last ten years, cardiac imaging has allowed to perform accurate anatomic and functional assessments of the myocardium (the muscular tissue of the heart). Relevant to this project, it is also possible to describe mechanistic phenotypes, including myocardial interstitial fibrosis, using circulating biomarkers" explains Professor Faiez Zannad, researcher at Inserm unit U1116, Centre d'Investigation Clinique P. Drouin Inserm 9501 in Nancy, and coordinator of the FIBRO-TARGETS and HOMAGE projects.
The FIBRO-TARGETS project objectives are first to confirm the main biological mechanisms involved in myocardial interstitial fibrosis. The next step will be to experimentally validate new molecules and targeted therapeutic strategies that aim to improve the quality of the cellular matrix and limit myocardial interstitial fibrosis. This will allow to propose potential clinical scénarios with the objective to treat heart failure. Finally, the targets could be used as biomarkers to predict, monitor and describe the response to myocardial interstitial fibrosis treatments.
To meet these objectives, the European researchers will undertake experimental physiological and pharmacological studies, as well as molecular biology and pharmaceutical chemistry studies, in an attempt to clarify the mechanisms involved in cardiac interstitial fibrosis using existing in-vitro and in vivo models, and/or models developed during the project. They will also validate the relevance of new therapeutic approaches developed during the project. The second step is a translational research aiming at stratifying patients that are most likely to respond to an anti-fibrotic targeted therapy, eventually leading to a personalized pharmacotherapy. Patients will be classified into groups according to profiles determined using imaging and circulating markers describing the new proposed targets.
The FIBRO-TARGETS project results will help resolve one of the 21st century's major health problems that affects elderly people in particular.
The 11 partners in the FIBRO-TARGETS project: http://www.fibrotargets.eu (online at the end of September)
1. Coordinator: Inserm, France: http://www.inserm.fr/
2. Inserm Transfert, France: http://www.inserm-transfert.fr/en/
3. Fundación para la Investigación Médica Aplicada (FIMA), Spain: http://www.cima.es
4. University college Dublin (UCD), Ireland: http://www.ucd.ie/
5. Maastricht University (UM), Netherlands: http://www.maastrichtuniversity.nl/
6. Hannover Medical School (MHH), Germany: http://www.mh-hannover.de/
7. Medical University of Vienna (MUW), Austria: http://www.meduniwien.ac.at/homepage/
8. Greenpharma S.A.S. (GP), France: http://www.greenpharma.com/
9. FIRALIS S.A.S. (FIR), France: http://www.firalis.com/
10. Innovative Technologies in Biological Systems S.L. (INNO), Spain: http://www.innoprot.com
11. Navarrabiomed - Fundación Miguel Servet (FMS-NB), Spain: http://www.navarrabiomed.es
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