Valve in valve implantation of the CoreValve Evolut R in degenerated surgical aortic valves

Background: The new CoreValve Evolut R has an improved design to minimize paravalvular leak­age and allows repositioning of the valve. For patients with degenerated bioprosthetic aortic valves, transcatheter aortic valve implantation (TAVI) represents a less invasive option. Herein reported are valve-in-valve (ViV) implantations of this new valve. Methods: A total of 26 patients (mean age 79.4 ± 6.1 years, 17 males and 9 females) were treated for severe prosthesis stenosis (n = 9), severe regurgitation (n = 8) or severe combination of stenosis and regurgitation (n = 9). All patients underwent transthoracic echocardiography before and after ViV implantation. Results: Valve-in-valve implantation of a CoreValve Evolut R was performed successfully in all pa­tients. The mean transaortic gradient for stenotic valves determined by transthoracic echocardiography was reduced significantly from 37.5 ± 15.3 mmHg in patients with prosthesis stenosis to 16.3 ± 8.2 mmHg (p < 0.001). In all cases with severe prosthesis regurgitation, regurgitation was reduced to none or mild. All-cause mortality after 30 days was 0%. Conclusions: It was concluded that CoreValve Evolut R is well suited for ViV implantation

Charakterisierung negativ inotroper Substanzen nach Myokardischämie

Kardialen Strukturen, wie dem koronaren oder endokardialen Endothel, dem Myokard und auch dem Perikard werden unter physiologischen und pathophysiologischen Bedingungen zunehmend autokrine oder parakrine Funktionen zugesprochen. Es ist gut belegt, dass das Herz durch Freisetzung von löslichen Mediatoren nach Myokardischämie einen entscheidenden Anteil an der postischämischen Regulation der Vasomotion hat. Allerdings weniger bekannt ist die Bedeutung einer Mediator-vermittelten kardialen Autoregulation bei postischämischen Veränderungen der Myokardkontraktilität. In dieser Arbeit wird eine neue negativ inotrope Substanz(en) (NIS) beschrieben, die nach myokardialer Ischämie aus isolierten Herzen freigesetzt wird und die an sequentiell perfundierten Herzen, die als Bioassay eingesetzt werden, einen deutlichen kardiodepressiven Effekt hervorruft. In isolierten Feld-stimulierten Rattenkardiomyozyten reduziert NIS dosisabhängig die systolische Zellverkürzung und den Ca2+-Transienten (Konfokale Laser Scan Mikroskopie). Der negativ inotrope Effekt setzt sowohl in isolierten Herzen als auch Kardiomyozyten schnell ein und ist reversibel. Katecholamine maskieren und überspielen den negativ inotropen Effekt in Abhängigkeit von der Ischämiedauer. Voltage clamp Untersuchungen auf Einzelzellebene zeigten, dass NIS den Ca2+-Einstrom Ica über die L-Typ Ca2+-Kanäle reduziert. Somit scheint NIS die Myokardkontraktilität und Zellverkürzung über eine Verminderung der intrazellulären systolischen Ca2+-Konzentrationen durch Blockade der L-Typ Ca2+-Kanäle zu reduzieren und nicht etwa über eine Ca2+-Desensitivierung. Derzeit ist noch nicht geklärt, über welchen Mechanismus NIS den Ca2+-Einstrom blockiert. Da weder die Gewebsspiegel von cGMP und cAMP noch die PKA Aktivität durch NIS moduliert werden, ist es unwahrscheinlich, dass eine Dephosphorylierung von Untereinheiten des L-Typ Ca2+-Kanals der Funktionsweise von NIS zu Grunde liegt. Die Ergebnisse legen nahe, dass NIS direkt mit dem Ca2+-Kanal interagiert, z.B. durch Bindung an ein Kanalprotein. Die chemische Struktur von NIS ist derzeit noch ungeklärt, allerdings gibt es Hinweise, dass es sich nicht um ein Protein handelt. Die Substanz(en) ist stabil, Hitze-resistent (56°) und ein dialysierbares Molekül mit einem geringen Molekulargewicht (< 0.5 kDa). Die kardiodepressorische Substanz(en) wird nicht vom Koronarendothel freigesetzt. Eine abschließende Bewertung, ob NIS durch Aggravation der kontraktilen Dysfunktion myokardschädigend oder durch Senkung des myokardialen Sauerstoffverbrauches kardioprotektiv wirkt, ist derzeit noch nicht möglich.Autocrine and paracrine functions are increasingly being attributed under physiological and pathophysiological conditions to cardiac structures such as the coronary or endocardial endothelium, the myocardium, and the pericardium as well. Reliable evidence exists to confirm that the heart, through the release of soluble mediators after myocardial ischemia, plays a decisive role in post-ischemic regulation of vasomotion. Less well-known, however, is the significance of mediator-effected cardiac autoregulation in cases of post-ischemic changes of myocardial contractility. This study describes a new negative inotropic substance or substances, NIS, released from isolated hearts after myocardial ischemia. NIS elicits marked cardiodepressive effects on sequentially perfused hearts used as bioassays. In isolated field-stimulated rat cardiomyocytes, NIS reduces, as a function of dose, systolic cell shortening and Ca2+ transients (as detected by confocal laser-scan microscopy). The negative inotropic effect occurs quickly both in isolated hearts as well as in cardiomyocytes, and is reversible. Catecholamines counteract the negative inotropic effect, as a function of ischemia duration. Voltage-clamp investigations on the single-cell level have disclosed that NIS reduces Ca2+ inflow Ica via L-type Ca2+ channels. NIS appears to decrease myocardial contractility and cell shortening through reduction of intracellular systolic Ca2+ concentration, by blockade of L-type Ca2+ channels: and not, say, by Ca2+ desensitization. It has not yet been definitely established by which mechanism NIS blocks Ca2+ inflow. Since NIS modulates neither the tissue level of cGMP and cAMP, nor PKA activity, it is improbable that NIS acts by dephosphorization of sub-units of the L-type Ca2+ channel. The results of this study imply that NIS directly interacts with the Ca2+ channel, perhaps by binding to a channel protein. Although the chemical structure of NIS has not yet been elucidated, there are indications that it is not a protein. The substance(s) is/are stable, heat resistant (up to 56°C), and dialyzable as a molecule with low molecular weight (< 0.5 kDa). It is not yet possible to provide conclusive evaluation of whether NIS acts to damage the myocardium by aggravation of the contractile dysfunction, or whether it exerts cardioprotective action by diminishing myocardial oxygen consumption

Renal and hepatic function of patients with severe tricuspid regurgitation undergoing inferior caval valve implantation

Due to progressive abdominal-venous congestion severe tricuspid regurgitation (TR) is a common cause of cardiorenal and cardiohepatic syndrome. We initiated the TRICAVAL study to compare interventional valve implantation into the inferior vena cava (CAVI) versus optimal medical therapy (OMT) in severe TR. In the present subanalysis, we aimed to evaluate the effects of CAVI on clinical signs of congestion, renal and hepatic function. TRICAVAL was an investigator-initiated, randomized trial. Twenty-eight patients with severe TR were randomized to OMT or CAVI using an Edwards Sapien XT valve. Probands who completed the 3-month follow-up (CAVI [n = 8], OMT [n = 10]) were evaluated by medical history, clinical examination, and laboratory testing at baseline, 3 and 12 months. After 3 months, the CAVI group exhibited a significant reduction of body weight (from 80.7 [69.0-87.7] kg to 75.5 [63.8-84.6] kg, p < 0.05) and abdominal circumference (from 101.5 +/- 13.8 cm to 96.3 +/- 15.4 cm, p <= 0.01) and a trend to lower doses of diuretics compared to OMT. Renal and hepatic function parameters did not change significantly. Within a short-term follow-up, CAVI led to an improvement of clinical signs of venous congestion and a non-significant reduction of diuretic doses compared to OMT

Impact of inferior caval valve implantation on severity of tricuspid regurgitation and right heart function

Aims: Severe tricuspid regurgitation (TR) is a common finding in heart failure patients and associated with increased mortality. New interventional therapeutic options are needed as many heart failure patients are unfit for surgery. The TRICAVAL study compared valve implantation into the inferior vena cava (CAVI) with optimal medical therapy (OMT) in patients with severe TR. Here, we report details on the impact of CAVI on TR severity as well as right heart function and morphology. Methods and results: We randomized 28 patients with severe TR to CAVI (n = 14) with transfemoral implantation of an Edwards Sapien XT valve into the inferior vena cava or OMT (n = 14). Inclusion and exclusion criteria were based on anatomical and clinical parameters. Echocardiographic measurements were performed at baseline, at the first postoperative day and one, three, and twelve months after randomization. As proof of concept of an effective sealing of the inferior vena cava, we detected a significant decrease in systolic hepatic vein reflux volume (11.0 [6.2-21.9] mL vs 3.5 [0.6-8.5] mL,P = .016) and hepatic vein diameter (11.5 [10.0-14.8] mm vs 10.0 [9.3-11.8] mm,P = .034) at thirty-day follow-up. However, CAVI had no significant impact on TR, cardiac function, and morphology. Conclusions: Caval valve implantation significantly reduced systolic reflux into the hepatic veins but was not associated with an improvement in cardiac function, morphology, or TR severity

PRAS40 suppresses atherogenesis through inhibition of mTORC1-dependent pro-inflammatory signaling in endothelial cells

Endothelial pro-inflammatory activation plays a pivotal role in atherosclerosis, and many pro-inflammatory and atherogenic signals converge upon mechanistic target of rapamycin (mTOR). Inhibitors of mTOR complex 1 (mTORC1) reduced atherosclerosis in preclinical studies, but side effects including insulin resistance and dyslipidemia limit their clinical use in this context. Therefore, we investigated PRAS40, a cell type-specific endogenous modulator of mTORC1, as alternative target. Indeed, we previously found PRAS40 gene therapy to improve metabolic profile; however, its function in endothelial cells and its role in atherosclerosis remain unknown. Here we show that PRAS40 negatively regulates endothelial mTORC1 and pro-inflammatory signaling. Knockdown of PRAS40 in endothelial cells promoted TNFα-induced mTORC1 signaling, proliferation, upregulation of inflammatory markers and monocyte recruitment. In contrast, PRAS40-overexpression blocked mTORC1 and all measures of pro-inflammatory signaling. These effects were mimicked by pharmacological mTORC1-inhibition with torin1. In an in vivo model of atherogenic remodeling, mice with induced endothelium-specific PRAS40 deficiency showed enhanced endothelial pro-inflammatory activation as well as increased neointimal hyperplasia and atherosclerotic lesion formation. These data indicate that PRAS40 suppresses atherosclerosis via inhibition of endothelial mTORC1-mediated pro-inflammatory signaling. In conjunction with its favourable effects on metabolic homeostasis, this renders PRAS40 a potential target for the treatment of atherosclerosis

Initial interaction of citrate-coated iron oxide nanoparticles with the glycocalyx of THP-1 monocytes assessed by real-time magnetic particle spectroscopy and electron microscopy

Interaction with biological material can alter physicochemical parameters of magnetic nanoparticles and might thereby change their magnetic behavior with potentially important implications for various nanoparticle applications. Little is known about changes of the magnetic behavior that occur during the initial phase of cell binding and uptake. We investigate the magnetic behavior of very small superparamagnetic iron-oxide nanoparticles (VSOP) during initial contact with THP-1 monocytes. We combine real-time magnetic particle spectroscopy (MPS), a fast and sensitive method for specific detection of magnetic nanoparticles in biological specimen with high-pressure-freezing/freeze-substitution transmission electron microscopy (HPF/FS-TEM), enabling us to generate snapshots of the interaction of VSOP with the cellular glycocalyx. MPS reveals significant changes of the dynamic magnetic behavior within seconds after VSOP injection into monocyte suspensions that correlate with the formation of nanoparticle clusters in the glycocalyx. The combination of real-time MPS and HPF/FS-TEM provides an ideal platform to analyze magnetic behaviors of nanoparticles upon interaction with cells and tissues

Comparison of Data-Driven Thermal Building Models for Model Predictive Control

Energy flexible buildings in combination with demand response will play a key role in the future smart grid. To implement control strategies, which enable demand response, like model predictive control, thermal building models are necessary. Therefore, three lumped capacitance models, are compared with a k-Nearest Neighbor regression model. All models show accurate prediction results, if the operating condition of the building is similar during parameter identification or rather during training and the validation period. Parameter identification of lumped capacitance models is a time-consuming task. Especially for complex lumped capacitance models, the search space for certain parameters has to be reduced to avoid local minima. The investigated k-Nearest Neighbor algorithm has the advantage of easy implementation, very fast training and minimal effort for parameter identification in combination with accurate predictions. But its seasonal dependency is very strong, which can be easily overcome with periodically data update, as it is an instance-based learning algorithm

Sequential effects in continued visual search: Using fixation-related potentials to compare distractor processing before and after target detection

To search for a target in a complex environment is an everyday behavior that ends with finding the target. When we search for two identical targets, however, we must continue the search after finding the first target and memorize its location. We used fixation-related potentials to investigate the neural correlates of different stages of the search, that is, before and after finding the first target. Having found the first target influenced subsequent distractor processing. Compared to distractor fixations before the first target fixation, a negative shift was observed for three subsequent distractor fixations. These results suggest that processing a target in continued search modulates the brain's response, either transiently by reflecting temporary working memory processes or permanently by reflecting working memory retention

Macrophage uptake switches on OCT contrast of superparamagnetic nanoparticles for imaging of atherosclerotic plaques

Background: Optical coherence tomography (OCT) is an intravascular, high-resolution imaging technique that is used to characterize atherosclerotic plaques. However, the identification of macrophages as important markers of inflammation and plaque vulnerability remains difficult. Here, we investigate whether the uptake of very small iron oxide particles (VSOP) in macrophages, that cluster in phagolysosomes and allow high-quality magnetic resonance imaging (MRI) of atherosclerotic plaques, and uptake of ferumoxytol nanoparticles enhance detection of macrophages by OCT. Materials and methods: RAW 264.7 macrophage cells were incubated with VSOP (1 and 2 mM Fe) that have been clinically tested and ferumoxytol (8.9 mM Fe) that is approved for iron deficiency treatment and currently investigated as an MRI contrast agent. The light scattering of control macrophages, nanoparticle-labeled macrophages (2,000,000 in 500 mu L) and nanoparticle suspensions was measured in synchronous wavelength scan mode using a fluorescence spectrophotometer. For OCT analyses, pellets of 8,000,000 non-labeled, VSOP-labeled and ferumoxytol-labeled RAW 264.7 macrophages were imaged and analyzed on an OPTIS (TM) OCT imaging system. Results: Incubation with 1 and 2 mM VSOP resulted in uptake of 7.1 +/- 1.5 and 12 +/- 1.5 pg Fe per cell, which increased the backscattering of the macrophages in spectrophotometry 2.5- and 3.6-fold, whereas incubation with 8.9 mM Fe ferumoxytol resulted in uptake of 6.6 +/- 2 pg Fe per cell, which increased the backscattering 1.5-fold at 700 nm. In contrast, backscattering of non-clustered nanoparticles in suspension was negligible. Accordingly, OCT imaging could visualize significantly increased backscattering and signal attenuation of nanoparticle-labeled macrophages in comparison with controls. Conclusion: We conclude that VSOP and, to a lesser extent, ferumoxytol increase light scattering and attenuation when taken up by macrophages and can serve as a multimodal imaging probe for MRI and OCT to improve macrophage detection in atherosclerotic plaques by OCT in the future

No role for epigallocatechin gallate (EGCG)

Consumption of tea is inversely associated with cardiovascular diseases. However, the active compound(s) responsible for the protective effects of tea are unknown. Although many favorable cardiovascular effects in vitro are mediated by epigallocatechin gallate (EGCG), its contribution to the beneficial effects of tea in vivo remains unresolved. In a randomised crossover study, a single dose of 200 mg EGCG was applied in three different formulas (as green tea beverage, green tea extract (GTE), and isolated EGCG) to 50 healthy men. Flow-mediated dilation (FMD) and endothelial-independent nitro-mediated dilation (NMD) was measured before and two hours after ingestion. Plasma levels of tea compounds were determined after each intervention and correlated with FMD. FMD significantly improved after consumption of green tea containing 200 mg EGCG (p < 0.01). However, GTE and EGCG had no significant effect on FMD. NMD did not significantly differ between interventions. EGCG plasma levels were highest after administration of EGCG and lowest after consumption of green tea. Plasma levels of caffeine increased after green tea consumption. The results show that EGCG is most likely not involved in improvement of flow-mediated dilation by green tea. Instead, other tea compounds, metabolites or combinations thereof may play a role