"SIMULATION MODELING OF CORONARY ARTERY DISEASE: A TOOL FOR CLINICAL DECISION SUPPORT"

Summary

Coronary atherosclerosis (ATS) is a degenerative-inflammatory artery pathology underlying the different clinical manifestations of coronary heart disease (CHD), from stable angina due to constrictive plaque growth obstructing artery lumen, to acute coronary syndrome (ACS), secondary to abrupt lumen occlusion by atherothrombosis at the site of a ruptured or eroded plaque.

Major coronary adverse events (MACE) are known to be related to local factors, the so called "high risk plaque" characterized by large lipid-necrotic core with a thin fibrous cap, intraplaque hemorrhage, rupture, erosion, and to systemic, patient-specific, factors, contributing to the atherogenic genotype/phenotype of the so called "high risk patient", presenting with an abnormally activated thrombogenic and/or inflammatory state or increased plasma levels of atherogenic lipid species.

The huge social and economic impact of CHD in western and developing countries is primarily due to the difficulty to identify and predict, in the clinical context, which "high risk plaque" in which "high risk patient" will cause, independently of stenosis severity, an acute coronary event such as myocardial infarction or sudden coronary death, which are often the first manifestations of CHD in a large proportion of otherwise asymptomatic subjects. Plaque burden, compared to stenosis, is recognized as a better predictor of ACS and coronary CT angiography (CCTA) is considered as the optimal non-invasive coronary imaging modality to assess and quantify plaque burden and to evaluate the functional significance of a stenosis, by computationally estimating fractional flow reserve. Moreover, molecular studies of CHD patients have mostly examined associations with clinical cardiovascular outcomes: associations with coronary ATS assessed by quantitative CCTA may provide insight into the pathophysiological role of several molecular species in plaque formation and growth, and elucidate their potential role as discriminative biomarkers of CHD.

Based on these considerations, aim of this study is to collect and analyze all patient-specific clinical and epidemiological data and patient phenotype and genotype blood-derived molecular information, and to combine them with local high resolution non-invasive CCTA imaging of actual plaque burden as well as, prospectively, of its increase or de novo formation over a clinically relevant timespan. The expected result, following local and systemic data integration and modeling, is to optimize early diagnosis and risk stratification of CHD beyond current clinical models and scores and to help improving primary and secondary prevention of MACE. The overall design of this diagnostic and prognostic framework has been proposed to Horizon 2020 EU Call PHC30 and approved by the European Commission (Grant Agreement PHC30-689068). The Consortium includes major clinical European University Hospitals specialized in CHD imaging and treatment and the project study has obtained the endorsement of the European Society of Cardiovascular Imaging.

Conditions

• Management/Treatment of Coronary Artery Disease

Interventions

DIAGNOSTIC_TEST

CCTA

requested follow up CCTA

Sponsors & Collaborators

• University of Zurich

  collaborator OTHER

• Turku University Hospital

  collaborator OTHER_GOV

• Azienda USL 12 Versilia

  collaborator OTHER

• Federico II University

  collaborator OTHER

• Institut Catala de Salut

  collaborator OTHER_GOV

• National Institute of Cardiology, Warsaw, Poland

  collaborator OTHER

• Fondazione C.N.R./Regione Toscana "G. Monasterio", Pisa, Italy

  lead OTHER_GOV

Study Design

Allocation

NA

Purpose

DIAGNOSTIC

Masking

NONE

Model

SINGLE_GROUP

Eligibility

Min Age

45 Years

Max Age

75 Years

Sex

ALL

Healthy Volunteers

No

Timeline & Regulatory

Start

2016-04-14

Primary Completion

2017-10-30

Completion

2017-12-30