Effectiveness of renal denervation in the treatment of hypertension: a literature review.

BACKGROUND: Catheter-based renal denervation has been studied as a potential therapeutic option to reduce high blood pressure (BP). Preclinical studies in some experimental models have demonstrated an antihypertensive effect of renal denervation but reports from clinical trials have been mixed METHODS: We performed a literature search using combinations of the key terms 'Cardiovascular diseases, Clinical trial, Pre-clinical trials, Resistant hypertension, Renal denervation, Ablation technique, Radiofrequency ablation, Ultrasound ablation, RADIANCE SOLO, SYMPLICITY HTN, SYPRAL HTN'. The databases searched were PubMed and OVID Medline. RESULTS: The initial SYMPLICITY HTN-1 AND HTN-2 clinical trials reported significant decreases in office BP but results from the more robustly designed SYMPLICITY HTN-3 trial, which included sham controls and ambulatory BP monitoring, showed no significant antihypertensive effect. Interest in the use of renal denervation in hypertension was once again sparked by favourable results from the SPYRAL HTN-OFF Med trial CONCLUSION: We provide a thorough, critical analysis of key preclinical and clinical studies investigating the efficacy of catheter-based renal denervation as a treatment for hypertension and highlight future areas for research to allow better translation into clinical practice.

Cardiac MRI in cardiomyopathies.

Heart failure affects 1-2% of the adult population and one of the main contributors to its development is cardiomyopathy. Assessing a patient's risk for adverse events in heart failure is challenging and made more difficult by the heterogenous phenotypic expression of the disease. Cardiac MRI has long been a gold standard measure of myocardial function and anatomy due to its high spatial and temporal resolution. More recently, it has been posited to play a more critical role in the diagnosis and prognosis of cardiomyopathy-related heart failure. Given the limitations of more commonly used imaging modalities, increasing the clinical use of cardiac magnetic resonance imaging could potentially improve the prognosis of specific subgroups of patients at risk of adverse cardiac events.

Lay abstract Heart failure is a condition where the heart is unable to pump out enough blood to meet the body's daily needs. It can affect up to 2% of the adult population. One of the causes of heart failure is an intrinsic disease of the heart muscle, called cardiomyopathy. Assessing a patient's risk for events such as hospitalization and death in heart failure is challenging, and made more difficult by the wide variety of ways a patient can present with heart failure clinically. Cardiac MRI has long been a highly regarded imaging technique for heart function and shape due to the high level of detail it can show. More recently, it has been thought to play a more important role in investigating and predicting the course of cardiomyopathy-related heart failure. Given the limitations of more commonly used measurement techniques, increasing the clinical use of cardiac magnetic resonance imaging would potentially improve the outcomes and quality of life for patients suffering with cardiomyopathy.

Long QT syndrome type 2: mechanism-based therapies.

Long QT syndrome type 2 is a life-threatening disorder of cardiac electrophysiology. It can lead to sudden cardiac death as a result of QT prolongation and can remain undetected until it presents clinically in the form of life-threatening cardiac arrythmias. Current treatment relies on symptom management largely through the use of ß-adrenergic blockade and presently no mechanism-based therapies exist to treat the dysfunction in the hERG channels responsible for the rapid delayed rectifier K+ current which is the pathological source of long QT syndrome type 2. We review the pathophysiology, diagnosis and current management of this life-threatening condition and also analyze some promising potential mechanism-based therapies.

Lay abstract Long QT syndrome is a condition which is characterized by an abnormally lengthened time period of electrical activity in the heart. This abnormality can result in the initiation of heart rhythms which can cause the patient to lose consciousness or cause the patient to enter a heart rhythm which is not conducive to life resulting in sudden cardiac death. In this article we look more closely at a subtype of this disease known as long QT syndrome type 2. We look at how this disease can cause sudden cardiac death, how it is currently managed and how future treatments may be able to work at a genetic and cellular level to reverse the disease-causing mechanisms behind this life-threatening syndrome.