Intravascular Ultrasound

Intravascular ultrasound (IVUS) is a cardiovascular imaging technology using a specially designed catheter with a miniaturized ultrasound probe for the assessment of vascular anatomy with detailed visualization of arterial layers. Over the past two decades, this technology has developed into an indispensable tool for research and clinical practice in cardiovascular medicine, offering the opportunity to gather diagnostic information about the process of atherosclerosis in vivo, and to directly observe the effects of various interventions on the plaque and arterial wall. This book aims to give a comprehensive overview of this rapidly evolving technique from basic principles and instrumentation to research and clinical applications with future perspectives

Radiation and the Stent: Results From Catheter - Based Radiation. And Radioactive Stenting

Angiographic restenosis occurs in up to 60% of cases after balloon angioplasty (BA). Restenosis after BA occurs due to elastic recoil of the artery, vascular remodeling with vessel shrinkage and neointimal hyperplasia. Neointimal hyperplasia develops by migration and proliferation of smooth muscle cells (SMCs) and myofibroblasts after balloon-induced trauma of the arterial wall and by deposition of an extracellular matrix by the SMCs. By preventing elastic recoil and negative remodeling stent implantation has resolved many of the problems created by balloon angioplasty. However, a new problem has been created - that of in-stent restenosis, wh

Temporal dynamics and pathophysiology of the edematous response after acute myocardial infarction: a translational journey

Post-myocardial infarction tissue composition is highly dynamic and can be characterized by cardiac magnetic resonance, which has been used to assess surrogate outcomes and efficacy endpoints in many experimental and clinical studies. However, there is a paucity of studies tracking the temporal dynamics of these processes and analyzing their pathophysiology in a comprehensive manner. The experimental and clinical work contained in this dissertation shows that the degree and extent of post-myocardial infarction tissue composition changes (mainly edema; but also necrosis, hemorrhage and microvascular obstruction) as assessed by cardiac magnetic resonance are variable according to the time from infarction, duration of ischemia, cardioprotective strategies, and the interplay between them. These dynamic changes should be taken into consideration when performing image acquisition. Comparative studies should be performed at similar timings to avoid the bias of these dynamic changes. Thus, and in contrast to the accepted view, it is shown for the first time that myocardial edema in the week after ischemia/reperfusion is a bimodal phenomenon, both in pigs and humans. The initial wave of edema, appearing abruptly upon reperfusion and which is significantly attenuated at 24 hours, is due to the reperfusion process itself. The deferred wave of edema, appearing progressively days after ischemia/reperfusion and reaching a plateau between days 4 to 7, is mainly caused by the tissue healing processes. These findings highlight the need for standardizing experimental and clinical protocols for post-myocardial infarction tissue characterization aiming to quantify edema, myocardial area at risk, infarct size, myocardial salvage, intramyocardial hemorrhage and microvascular obstruction. The timeframe between day 4 and 7 post-infarction seems a good compromise solution according to translational data here presented. However, further studies and expert consensus are needed to stablish more precise recommendations

A Clinician's Contribution to Biomedical Engineering in Experimental Echocardiography

The research of this thesis has been focused on the biomedical engineering aspects of new techniques of echocardiography. In close collaboration with the engineers of the Experimental Echocardiography Department of the Thoraxcentre, Erasmus University, Rotterdam, new methods to measure coronary blood flow and arterial wall elasticity with intravascular ultrasound (IVUS) have been developed. We have also investigated the clinical application of these measurements and have tried to improve traditional techniques based on intracoronary Doppler wires. In another field, we have developed a method to determine the radiation dose delivered in the wall of coronary arteries treated with brachytherapy. in collaboration with the Emory University, Atlanta, GA. This method utilizes 3-dimensional IVUS reconstruction combined with radiotherapy treatment planning. Finally, the tools developed for the recording of the signals of intracoronary Doppler wires have been adapted, during a stay at the Cleveland Clinic Foundation, OK for the study of left ventricular mechanics and the compliance of the large arteries. This has been achieved by simultaneous acquisition of non-invasive pressure (with tonometry) and flow (with transthoracic Doppler echocardiography) signals. The fruits of an old and close collaboration with the Institute Biomedical Technology of the Ghent University can also be found in different chapters. This work is subdivided in five major parts, and a detailed introductory chapter precedes each one