The role of 3D imaging in the follow-up of patients with repaired tetralogy of Fallot.

OBJECTIVE: The patients with repaired Tetralogy of Fallot (rToF) are a growing population due to the improvement of surgical management in neonatal age. However, the significant pulmonary regurgitation, consequent to the repair, is the most frequent sequelae and leads to a progressive right ventricle dilation over time. The latter, in turn, is responsible for the possible dysfunction of right and/or left ventricle and an increased risk of dangerous ventricular arrhythmias. Therefore, right ventricle monitoring is necessary for rToF patients and a 3D method is required due to its three anatomical and functional subunits. Magnetic resonance imaging (MRI) has become the 3D modality of choice in the evaluation of both cardiac anatomy and ventricular volumes in rToF patients since it is able to evaluate both the pathophysiology and anatomy, it is free of radiation and, when strictly necessary, it uses a non-iodinated contrast agent. Cardiac CT should be considered in the evaluation of the sequelae in rToF only in selected cases, given that it implies a radiation dose and iodinated contrast, in addition to not evaluating the pathophysiology as MRI.

Epicardial Fat Thickness and Primary Aldosteronism.

Primary aldosteronism (PA) is associated with increased cardiovascular risk and left ventricle (LV) changes. Given its peculiar biomolecular and anatomic properties, excessive epicardial fat, the heart-specific visceral fat depot, can affect LV morphology. Whether epicardial fat can be associated with aldosterone and LV mass (LVM) in patients with PA is unknown. We performed ultrasound measurement of the epicardial fat thickness (EAT) in 79 consecutive newly diagnosed patients with PA, 59 affected by bilateral adrenal hyperplasia (IHA), 20 aldosterone-producing adenoma (APA), and 30 patients with essential hypertension (low renin hypertension) (EH). The 3 groups did not differ by age, sex distribution, body mass index (BMI), waist circumference (WC), or blood pressure values. EAT showed a trend of increase in both APA and IHA groups when compared to patients with EH (8.3±1.8 vs. 7.9±1.3 vs. 7.8±2 mm, respectively). EAT was significantly correlated with indexed LVM in the IHA group (r=0.35, p<005), better than BMI or WC were. Interestingly, EAT was highly associated with plasma aldosterone concentrations (PAC) and PAC/plasma renin activity (PRA) (PAC/PRA) in the APA group (p=0.58, p=0.37, p<0.01, for both), whereas BMI and WC were not. EAT was also correlated with PRA in the IHA group (p=-0.28, p<0.05). Our study indicates a novel and interesting interaction of EAT with PA, independent of obesity, abdominal fat and blood pressure control. EAT can locally affect LVM, at least in patients with IHA. Further studies in larger population will be required to confirm these findings.

Pneumonia, thrombosis and vascular disease.

SUMMARY: An enhanced risk of cardiovascular mortality has been observed after pneumonia. Epidemiological studies have shown that respiratory tract infections are associated with an increased risk of thrombotic-related vascular disease such as myocardial infarction, ischemic stroke and venous thrombosis. Myocardial infarction and stroke have been detected essentially in the early phase of the disease (i.e. within 48 h from hospital admission), with an incidence ranging from as low as 1% to as high as 11%. Age, previous cardiovascular events and high pneumonia severity index were independent predictors of myocardial infarction; clinical predictors of stroke were not identified. Deep venous thrombosis and pulmonary embolism may also occur after pneumonia but incidence and clinical predictors must be defined. The biological plausibility of such an association may be deduced by experimental and clinical studies, showing that lung infection is complicated by platelet aggregation and clotting system activation, as documented by up-regulation of tissue factor and down-regulation of activated protein C. The effect of antithrombotic drugs has been examined in experimental and clinical studies but results are still inconclusive.

Modern cardiovascular risk management in clinical practice

Este artículo revisa la creciente importancia de la morbilidad y mortalidad asociadas a la enfermedad cardiovascular, con especial interés en la implementación de estrategias preventivas que pueden limitar la carga que supone la enfermedad cardiovascular. En concreto, las líneas de actuación serían: 1) Realizar una evaluación más completa del riesgo cardiovascular global, especialmente en los pacientes de alto riesgo basal; 2) Alcanzar una reducción del riesgo mediante una intervención terapéutica integral sobre los diferentes componentes del riesgo cardiovascular; 3) Mejorar aquellas estrategias dirigidas a conseguir una reducción del riesgo cardiovascular global a largo plazo, especialmente en los pacientes de alto riesgo, y homogeneizar las recomendaciones de las guías para el manejo del riesgo cardiovascular. La carga sanitaria que supone la enfermedad cardiovascular puede reducirse de forma efectiva mediante la adopción de una mejora en la identificación del paciente riesgo, la estratificación de dicho riesgo y el tratamiento individualizado en las distintas fases del continuo cardiovascular (AU)

In this article we address the issue of the continuing growing burden of morbidity and mortality associated to cardiovascular disease, by focusing on how this could be limited by implementing cardiovascular disease prevention strategies. In particular, we propose to: 1) performing a more comprehensive evaluation of total CV risk, especially in patients at high baseline risk profile; 2) achieving a risk reduction through a global therapeutic interventionon the different components of CV risk; 3) improving strategies aimed at global CV risk reduction in future years, especially in patients at high risk, and implementing armonization of guidelines for risk management. The burden of CV disease can be effectively reduced by adopting a more comprehensive approach to identification, risk stratification and treatment of individuals along the cardiovascular continuum (AU)

Leopard syndrome.

The L.E.O.P.A.R.D. syndrome is an autosomal, dominant disorder with characteristic features that include: multiple lentigines, café au lait spots, electrocardiographic conduction abnormalities, ocular hypertelorism, obstructive cardiomyopathy, pulmonary stenosis, abnormal (male) genitalia, retardation of growth, and deafness. Patients do not usually present all the clinical features traditionally associated with the disorder. Indeed, several features are not present until late in life and do not become clinically manifest until puberty. It has been observed that this syndrome is caused by a "missense" mutation in PTPN11, a gene encoding the protein tyrosine phosphatase SHP-2 located on chromosome 12q22. A diagnosis of LEOPARD syndrome may be established exclusively on the basis of clinical criteria. In our case, the patient was diagnosed with the syndrome late in his life when he was already exhibiting all its distinctive clinical features. We have reported the case of a LEOPARD syndrome patient exhibiting extremely elongated vertebral and basilar arteries previously undescribed in the literature.