Nature reviews. Cardiology
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Constrictive pericarditis can result from a stiff pericardium that prevents satisfactory diastolic filling. The distinction between constrictive pericarditis and other causes of heart failure, such as restrictive cardiomyopathy, is important because pericardiectomy can cure constrictive pericarditis. Diagnosis of constrictive pericarditis is based on characteristic haemodynamic and anatomical features determined using echocardiography, cardiac catheterization, cardiac MRI, and CT. ⋯ Early diagnosis of constrictive pericarditis is, therefore, of paramount clinical importance. An improved understanding of how constrictive pericarditis develops after an initiating event is critical to prevent this diastolic heart failure. In this Review, we discuss the aetiology, pathophysiology, and diagnosis of constrictive pericarditis, with a specific emphasis on how to differentiate this disease from conditions with similar clinical presentations.
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The constant shortage of available organs is a major obstacle and limiting factor in heart transplantation; the discrepancy between the number of donors and potential recipients leads to waiting-list mortality of 10-12% per year in Europe and the USA. If adopted for heart transplantation, donation after circulatory determination of death (DCDD) would be expected to improve the availability of organs substantially for both adults and children. With DCDD, however, hearts to be transplanted undergo a period of warm ischaemia before procurement, which is of particular concern because tissue damage occurs rapidly and might be sufficient to preclude transplantation. ⋯ Development of clinical approaches specifically for DCDD is critical for the exploitation of these organs, because current practices for donor heart procurement, evaluation, and storage have been optimized for conventional donation after brain death, without consideration of warm ischaemia before organ procurement. Establishment of clinical protocols and ethical and legal frameworks for DCDD of other organs is underway. This Review provides a timely evaluation of the potential for DCDD in heart transplantation.
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Experimental and clinical evidence indicating an antiarrhythmic effect of cardiac sympathetic denervation has been available for 100 years. Experimental data show that left cardiac sympathetic denervation (LCSD), in particular, is not only antiarrhythmic, but also antifibrillatory-an effect exquisitely important for any clinical condition associated with a high risk of ventricular fibrillation and sudden cardiac death. ⋯ Evidence also shows that LCSD increases the vagal activity directed to the heart, which has potential implications for the management of heart failure. In this Review, the current and novel clinical indications for LCSD are discussed, particularly in the context of results obtained in patients with channelopathies, such as long QT syndrome and catecholaminergic polymorphic ventricular tachycardia.
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Patients with severe aortic stenosis who are at high surgical risk or not considered to be suitable candidates for surgical aortic valve replacement are increasingly being treated with transcatheter aortic valve replacement (TAVR). Although this novel treatment modality has been proven to be effective in this patient population, serious complications occur in approximately one-third of patients during the month after the procedure. ⋯ Anticipation and early recognition of these complications, followed by prompt management using a wide range of percutaneous or surgical rescue interventions, is vital to patient outcome. Continuous patient assessment and reporting of complications according to standardized definitions, in addition to growing operator experience and upcoming technological refinements, will hopefully reduce the future rate of complications related to this procedure.
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Over the past 2 decades, cardiac troponins (cTn) have emerged as the preferred biomarkers for the noninvasive detection of myocardial injury. In conjunction with typical clinical findings of ischaemia, elevated cTn levels in blood confirm a diagnosis of myocardial infarction. However, neither cTnT or cTnI are exclusively released as a result of ischaemic myocardial cell necrosis, but also with numerous nonischaemic acute and chronic cardiac conditions, such as myopericarditis, toxic injury, or severe cardiac overload. ⋯ However, the clinical conditions leading to cTn release in patients who do not have ACS, and the appropriate diagnostic and therapeutic strategies for these individuals, are largely unknown. Here, we provide an overview of the many causes and the prognostic importance of the release of cTn not related to ACS. We also recommend strategies to discriminate between ischaemic and nonischaemic cTn elevation, and describe the clinical evaluation of these patients.