Microparticles are small cell vesicles that are derived from the cell membrane in response to different biological processes. There is growing evidence supporting the association between microparticles and cardiovascular disease, as their pathophysiology commonly includes endothelial damage and chronic inflammation which also promote a prothrombotic state. The direct causal link between the release of the different subtypes of microparticles and their implications on physiological and pathological conditions is still not completely elucidated. However, evidence suggests microparticles released from platelets, leukocytes, and endothelium may help to evaluate vascular health as they have a relevant role in inflammation, endothelial function, and thrombosis. This review aims to provide a short overview of the biogenesis, characteristics, and detection methodology of microparticles with a special focus on their possible implication in cardiovascular settings.
Sympathetic overdrive contributes to the derangement of glucose metabolism evident in clinical conditions, such as obesity, metabolic syndrome, type 2 diabetes, obstructive sleep apnea, and others. Targeting the sympathetic nervous system directly therefore appears as an attractive therapeutic approach to restore impaired glucose metabolism. Indeed, lifestyle interventions, including healthier diets and exercise, have been shown to exert their beneficial effects at least in part by reducing sympathetic nervous system activity. Pharmacologic inhibition of exaggerated central sympathetic outflow has also been demonstrated to beneficially impact on body weight and glucose and lipid metabolism. More recently, catheter-based renal denervation, an intervention applied predominantly to lower elevated blood pressure in patients with resistant hypertension, revealed salutary effects on glucose metabolism. Here, we review the mechanisms that contribute to the beneficial effects of targeting the sympathetic nervous system directly and discuss how these approaches may best be embedded in routine clinical practice.
BACKGROUND:
Recent sham-controlled randomized clinical trials have confirmed the safety and efficacy of catheter-based renal denervation (RDN). Long-term safety and efficacy data beyond 3 years are scarce. Here, we report on outcomes after RDN in a cohort of patients with resistant hypertension with an average of ≈9-year follow-up (FU).
METHODS:
We recruited patients with resistant hypertension who were previously enrolled in various RDN trials applying radiofrequency energy for blood pressure (BP) lowering. All participants had baseline assessments before RDN and repeat assessment at long-term FU including medical history, automated office and ambulatory BP measurement, and routine blood and urine tests. We analyzed changes between baseline and long-term FU.
RESULTS:
A total of 66 participants (mean±SD, 70.0±10.3 years; 76.3% men) completed long-term FU investigations with a mean of 8.8±1.2 years post-procedure. Compared with baseline, ambulatory systolic BP was reduced by −12.1±21.6 (from 145.2 to 133.1) mm Hg (
P
<0.0001) and diastolic BP by −8.8±12.8 (from 81.2 to 72.7) mm Hg (
P
<0.0001). Mean heart rate remained unchanged. At long-term FU, participants were on one less antihypertensive medication compared with baseline (
P
=0.0052). Renal function assessed by eGFR fell within the expected age-associated rate of decline from 71.1 to 61.2 mL/min per 1.73 m
2
. Time above target was reduced significantly from 75.0±25.9% at baseline to 47.3±30.3% at long-term FU (
P
<0.0001).
CONCLUSIONS:
RDN results in a significant and robust reduction in both office and ambulatory systolic and diastolic BP at ≈9-year FU after catheter-based RDN on less medication and without evidence of adverse consequences on renal function.
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