Pearsonmagnussen6512

Gaining control over the nanoscale assembly of different electrode components in energy storage systems can open the door for design and fabrication of new electrode and device architectures that are not currently feasible. This work presents aqueous layer-by-layer (LbL) self-assembly as a route towards design and fabrication of advanced lithium-ion batteries (LIBs) with unprecedented control over the structure of the electrode at the nanoscale, and with possibilities for various new designs of batteries beyond the conventional planar systems. LbL self-assembly is a greener fabrication route utilizing aqueous dispersions that allow various Li+ intercalating materials assembled in complex 3D porous substrates. The spatial precision of positioning of the electrode components, including ion intercalating phase and electron-conducting phase, is down to nanometer resolution. This capable approach makes a lithium titanate anode delivering a specific capacity of 167 mAh g-1 at 0.1C and having comparable performances to conventional slurry-cast electrodes at current densities up to 100C. It also enables high flexibility in the design and fabrication of the electrodes where various advanced multilayered nanostructures can be tailored for optimal electrode performance by choosing cationic polyelectrolytes with different molecular sizes. A full-cell LIB with excellent mechanical resilience is built on porous insulating foams.

Right ventricular pacing (RVP) induces ventricular asynchrony in patients with normal QRS and increases the risk of heart failure and atrial fibrillation in long term. His bundle pacing (HBP) is a physiological alternative to RVP, and could overcome its drawbacks. Recent studies assessed the feasibility and safety of HBP in expert centers with a vast experience of this technique. These results may not apply to less experienced centers. We aim to evaluate the feasibility and safety of permanent HBP performed by physicians who are new to this technique.

We included all patients who underwent pacemaker implantation with attempt of HBP in three hospitals between September 2017 and January 2020. Indication for HBP was left to operators' discretion. All the operators were new for HBP. His bundle (HB) electrical parameters were recorded at implant, 3- and 12-month follow-up.

HBP was successful in 141 of 170 patients (82.9%); selective HBP was obtained in 96 patients and nonselective HBP in 45. The mean procedure and fluoroscopy durations were 67.0 ± 28.8 min, and 7.3 ± 8.1 min (3.1 ± 4.1 Gy·cm

), respectively. The mean HB paced QRS duration was 106 ± 18 ms. The mean HB capture threshold was 1.29 ± 0.77 V and did not increase at 3- and 12-month follow-up. The ventricular lead revision was required in five patients. Our results showed a rapid technical learning allowing a high procedure success rate (89.8%) after 15 procedures.

HBP performed by operators new to this technique appeared feasible and safe. This should encourage HBP to be performed in patients expected to experience high RVP burden.

HBP performed by operators new to this technique appeared feasible and safe. This should encourage HBP to be performed in patients expected to experience high RVP burden.

We assessed the impact of pre-percutaneous coronary intervention (PCI) bifurcation angle change (BAC) on clinical outcomes.

There are little available data about the impact of BAC in unprotected left main distal bifurcation lesions (ULMD) PCI.

We identified consecutive 300 patients with ULMD underwent complex stenting using drug-eluting stent in three high-volume centers (Tokyo and Milan). We measured the widest BA of ULMD at both end-diastole and end-systole before stenting with two-dimensional quantitative coronary angiographic assessment and calculated the BAC value as a difference of two BA value in each lesion. We divided them into small and large BAC group according to the median BAC value (7.2°). The primary endpoint was target lesion failure (TLF), which was defined as a composite of cardiac death, target lesion revascularization (TLR) and myocardial infarction.

TLF rate at 3-year was significantly higher in the large BAC group than in the small BAC group (adjusted hazard ratio [HR] 5.85; 95% confidence interval [CI], 3.40-10.1; p < .001). TLR rate for left main (LM) to left anterior descending artery (LAD) and ostial left circumflex artery (LCXos) at 3-year were significantly higher in large BAC group than in small BAC group (adjusted HR 5.91; 95% CI, 2.03-17.2; p = .001 and adjusted HR 10.6; 95% CI, 5.20-21.6; p < .001, respectively).

A large BAC before stenting is strongly associated with adverse events after complex stenting for ULMD, mainly driven by repeat PCI for restenosis of the LCXos and of the LM-LAD.

A large BAC before stenting is strongly associated with adverse events after complex stenting for ULMD, mainly driven by repeat PCI for restenosis of the LCXos and of the LM-LAD.The energy conversion efficiency of water electrolysis is determined by the activity of selected catalysts. Ideal catalysts should possess not only porous architecture for high-density assembly of active sites but also a subtle electronic configuration for the optimized activity at each site. find more In this context, the development of stable porous hosting materials that allow the incorporation of various metal elements is highly desirable for both experimental optimization and theoretical comparison/prediction. Herein, MOF-derived spongy nanosheet arrays constructed by assembly of carbon encapsulated hetero-metal doped Ni2 P nanoparticles is presented as a superior bifunctional electrocatalyst for water splitting. This hierarchical structure can be stably retained when secondary metal dopants are introduced, providing a flexible platform for electronic modulation. The catalytic origin of activity enhancement via metal (Fe, Cr, and Mn) doping is deciphered through experimental and theoretical investigations. Combining the advantages in both morphological and electronic structures, the optimized catalyst NiMn-P exhibits remarkable activity in both hydrogen and oxygen evolution in the alkaline media, with an ultrasmall cell voltage of 1.49 V (at 10 mA cm-2 ) and high durability for at least 240 h.