Abstract: Aortic stiffness increases with age and is a robust predictor of cerebrovascular events and cognitive decline including Alzheimer’s disease and other forms of dementia. Recent clinical studies have investigated the association between proximal aortic stiffness and pulsatile energy transmission that has deleterious effects on the cerebrovascular network in order to identify potential therapeutic targets. Aging causes disproportionate stiffening of the aorta compared with the carotid arteries, reducing protective impedance mismatches at their interface, increasing the transmission of destructive pulsatile pressure and energy to the cerebral circulation, and leading to cerebral small vessel disease. Thus, aortic stiffening and high-flow pulsatility are associated with alterations in the microvasculature of the brain, vascular endothelial dysfunction, and white matter damage, which contribute to impaired memory function with advancing age. Previous studies have also shown that silent lacunar infarcts and white matter hyperintensities are strongly associated with arterial stiffness. More and more evidence suggests that vascular etiologies, including aortic stiffness, impedance match, and microvascular damage, are associated with cognitive impairment and the pathogenesis of dementia. The measurement of arterial flow and pressure can help understand pulsatile hemodynamics and its impact on vital organs. Interventions that reduce aortic stiffness, such as improvement of the living environment, management of risk factors, and innovation and development of novel drugs, may reduce the risk for dementia.

Abstract: Current diagnosis and treatment of hypertension are based on office and out-of-office cuff measurements of blood pressure, which is obtrusive and inappropriate for continuous measurement. In contrast, many wearable devices can provide a convenient cuffless measurement of blood pressure that has the potential to track blood pressure change with activities around the clock. Moreover, the huge number of blood pressure readings obtained directly from users’ various smart devices may provide an unprecedented opportunity for digital transformation and precision medicine, which may dramatically change the practice of hypertension management in the future. However, concerns about the accuracy of cuffless blood pressure measurements have been raised [1] and recent hypertension guidelines do not support the use of smartphone/smartwatch-based cuffless blood pressure measurement for routine hypertension diagnosis and treatment [2, 3], why? Quest for More Accurate Blood Pressure Measurement

Abstract: None

Abstract: Aim: The aim of this study was to investigate the presence of fQRS and its association with subclinical systolic and microvascular dysfunction in patients with masked hypertension (MH). Methods: The study population consisted of 95 (mean age 48.9 ± 11.3, 61% males) subjects with MH and 80 age- and gender-matched healthy individuals who served as a control group. Coronary flow reserve (CFR) using transthoracic echocardiography and for left ventricular global longitudinal strain (LVGLS) using speckle-tracking strain imaging were performed. Patients with MH were stratified into two groups according to the presence of fQRS on surface electrocardiogram. Results: Fragmented QRS was more common among MH patients compared with controls (38.9% vs. 6.25%, p < 0.003). CFR was significantly lower in patients with fQRS compared with those without fQRS and controls (p < 0.001). Likewise, LVGLS values were lower in MH patients with fQRS (p < 0.001) compared with subjects without fQRS and controls. Fragmented fQRS was significantly correlated with systolic blood pressure, CFR, and LVGLS. Multivariate analysis showed that the presence of fQRS, number of leads, and CFR were independent predictors of subclinical systolic dysfunction. With ROC cure analysis, number of leads with fQRS ≥4 was the optimal value for predicting the presence of subclinical systolic dysfunction in subjects with MH. Conclusions: Fragmented QRS is more frequent among subjects with MH compared with controls. The presence of fQRS is related with pronounced subclinical left ventricular systolic dysfunction. Furthermore, CFR was significantly reduced in subjects with MH, a finding supposed that microvascular dysfunction to be a mechanistic link.

Abstract: The global health burden presented by hypertension is providing increased motivation for improved means of collection of blood pressure (BP) data. A growing area of research and commercial activity is the use of wearable devices to provide BP data using non-invasive cuffless techniques. The accelerated progress in recent years, particularly relating to connectivity of smartphone technology, has promoted the availability of consumer devices that provide values of BP. The main types of devices are wrist-worn, watch-type devices with sensors that typically record a photoplethysmography (PPG) signal, sometimes also with an electrocardiography (ECG) signal. The general underlying concept of the cuffless BP measurement in most device types is the association of BP and the travel time of the arterial pulse between two locations, determined from the time delay between the ECG and PPG signals. Other methods may involve additional analysis of the PPG waveform features. Experimental data are presented to illustrate the challenges presented by cuffless BP techniques in obtaining reliable BP measurements when the change in BP is caused by different stimuli affecting cardiac and vascular mechanisms. These effects influence the association of the measured and physiological BP change, thus presenting significant challenges and potential limitations in the use of cuffless BP devices for the diagnosis and treatment of hypertension.

Abstract: Severe hypertension has numerous etiologies. When accompanied by bradycardia, the spectrum of differential diagnoses is greatly narrowed and is commonly seen in patients with increased intracranial pressure. However, other etiologies such as bradycardia-induced hypertension are rarely mentioned. Here we report the case of a 73-year-old woman presenting with symptoms of heart failure, severe hypertension, and bradycardia with a 2:1 atrioventricular block. Echocardiography demonstrated increased left ventricular filling secondary to bradycardia and prolonged diastole, leading to greater ventricular stretch, increased contractile force and greater stroke volume (Frank-Starling mechanism), which subsequently caused elevated systolic blood pressure (BP), low diastolic BP and a wide pulse pressure. Treating the bradycardia by pacing led to an immediate and substantial BP reduction, although complete BP normalization had a slower time course and was probably due to the concomitant effect of the antihypertensive treatment initiation. This pathophysiological mechanism has received little attention in the literature. Further, stimulation of sympathetic afferents located in the heart by distension of the cardiac walls as well as the role of vagally innervated cardiopulmonary receptors due to the increased pressure in the heart and the pulmonary artery should also be kept in mind as alternative hypotheses.