Molecular hybrid positron emission tomography/computed tomography imaging of cardiac angiotensin II type 1 receptors

Molecular imaging in cardiovascular disease: Which methods, which diseases?

Techniques for in vivo assessment of disease-related molecular changes are being developed for all forms of non-invasive cardiovascular imaging. The ability to evaluate tissue molecular or cellular phenotype in patients has the potential to not only improve diagnostic capabilities but to enhance clinical care either by detecting disease at an earlier stage when it is more amenable to therapy, or by guiding most appropriate therapies. These new techniques also can be used in research programs in order to characterize pathophysiology and as a surrogate endpoint for therapeutic efficacy. The most common approach for molecular imaging involves the creation of novel-targeted contrast agents that are designed so that their kinetic properties are different in disease tissues. The main focus of this review is not to describe all the different molecular imaging approaches that have been developed, but rather to describe the status of the field and highlight some of the clinical and research applications that molecular imaging will likely provide meaningful benefit. Specific target areas include assessment of atherosclerotic disease, tissue ischemia, and ventricular and vascular remodeling.

Noninvasive imaging of myocardial extracellular matrix for assessment of fibrosis

PURPOSE OF REVIEW

Myocardial fibrosis is a common feature of many cardiomyopathies, including hypertrophic cardiomyopathy. Myocardial fibrosis has been shown to be reversible and treatable with timely intervention. Although early detection and assessment of fibrosis is crucial, adequate diagnostics are still in development. Recent studies have shown progress on noninvasive imaging methods of fibrosis using cardiovascular magnetic resonance (CMR) and nuclear imaging modalities.

RECENT FINDINGS

T1 mapping and extracellular volume mapping (ECV) combined with CMR imaging are cutting edge methods that have the potential to assess interstitial myocardial fibrosis. Recent findings show that ECV measurement can be correlated to the extent of diffuse fibrosis. Comparatively, molecular imaging targets specific biomarkers in the fibrosis formation pathway and provides enhanced sensitivity for imaging early disease. Biomarkers include molecules involved in angiogenesis, ventricular remodeling, and fibrotic tissue formation, whereas collagen targeted agents can directly identify fibrotic tissue in the heart.

SUMMARY

This review introduces novel methods of fibrosis imaging that utilize properties of extracellular matrix and its biomarkers. Changes in characteristics and cellular biomarkers of the extracellular space can provide significant information regarding fibrosis formation and its role in cardiomyopathy. Ultimately, these findings may improve detection and monitoring of disease and improve efficiency and effectiveness of the treatment.

What can we learn about valvular heart disease from PET/CT?

Valvular heart disease is a major cause of morbidity and mortality, and with an aging population, its prevalence is increasing. Here, we review the evolving use of positron emission tomography/computed tomography in valvular heart disease, with particular focus on calcific aortic stenosis and infective endocarditis. In principle, the activity of any pathological process can be studied, as long as an appropriate radiotracer can be developed. We will review some of the early data using established tracers in the above and other conditions, providing discussion as to the future research and clinical roles of these techniques. Furthermore, we will discuss the potential impact of novel tracers that are currently under development or testing in preclinical models. It is hoped that such advanced imaging might improve the diagnosis, treatment and outlook for patients with valvular heart disease.

Image-guided therapies for myocardial repair: concepts and practical implementation

Cell- and molecule-based therapeutic strategies to support wound healing and regeneration after myocardial infarction (MI) are under development. These emerging therapies aim at sustained preservation of ventricular function by enhancing tissue repair after myocardial ischaemia and reperfusion. Such therapies will benefit from guidance with regard to timing, regional targeting, suitable candidate selection, and effectiveness monitoring. Such guidance is effectively obtained by non-invasive tomographic imaging. Infarct size, tissue characteristics, muscle mass, and chamber geometry can be determined by magnetic resonance imaging and computed tomography. Radionuclide imaging can be used for the tracking of therapeutic agents and for the interrogation of molecular mechanisms such as inflammation, angiogenesis, and extracellular matrix activation. This review article portrays the hypothesis that an integrated approach with an early implementation of structural and molecular tomographic imaging in the development of novel therapies will provide a framework for achieving the goal of improved tissue repair after MI.