T1 Mapping of Diffuse Myocardial Fibrosis in Congenital Heart Disease

Overview

Diffuse fibrosis (or scarring) of the heart muscle is found in a variety of congenital heart diseases and in cardiomyopathies (heart muscle disease), and is considered a mediator of decreased cardiac function. The detection and quantification of diffuse myocardial fibrosis has recently become feasible non-invasively, using cardiac magnetic resonance (CMR), applying a new technique labeled T1 mapping. With this technique, the part of the heart tissue which is not made up of muscle cells (extracellular volume) can be quantified, as long as the individual's hematocrit (cellular volume in the blood) is known. The extracellular volume in the heart tissue is regarded as a quantifiable marker for the extent of diffuse myocardial fibrosis. In the proposed study this new T1 mapping technique shall be applied in patients with different forms of congenital heart disease (n=130), cardiomyopathies (n=40) and in control subjects (n=30). The additional scan time due to participation in the study will be approximately 5-10 minutes, without changing the clinical protocol. The main objective is to study the presence and extent of myocardial fibrosis by T1 mapping CMR in pediatric patients with congenital heart disease and cardiomyopathies, in comparison to cardiovascularly healthy controls.

A better understanding of the mechanisms by which the heart muscle fails in pediatric heart disease may result in novel therapies directed at preventing rather than treating ventricular failure. The most likely mediator candidate for cardiac demise in congenital heart disease as well as the cardiomyopathies is diffuse myocardial fibrosis and non-favorable chronic biventricular remodeling. As such, fibrosis may be a marker, if not a mediator, preceding the onset of actual echocardiographic and clinical deterioration, opening opportunities for more timely and targeted treatment. Chronic stressors of myocardial function (hypoxemia, abnormal afterload or preload) appear to promote fibrosis. In some groups of patients, a genetically upregulated collagen metabolism seems to play a role. In adult patients with dilated cardiomyopathy the extent of myocardial fibrosis is predictive of outcome. With cardiac magnetic resonance imaging, the characterization of myocardial tissue is possible. Whereas standard late gadolinium enhancement (LGE) CMR can only identify patchy scars neighboring healthy tissue, quantification of diffuse myocardial fibrosis in the living has become feasible with the T1 mapping technique. Both techniques (T1 mapping and LGE) are based on the principle that MR contrast medium (gadolinium) is trapped in between collagen fibres and is retained in areas of fibrosis while it is quickly washed out of healthy myocardium. As gadolinium is a T1 shortening agent, the fibrosed tissue with its 'trapped' gadolinium has a shorter T1 time than healthy tissue. T1 mapping measures the T1 time constant, which has been shown to correlate with the degree of fibrosis. In a refined approach of this technique, which we will use, it is now possible to quantify the extracellular space (equivalent to the degree of fibrosis) by T1 mapping. This method has been validated against the current gold standard of surgical myocardial biopsy.