Piperacillin/tazobactam vs. cefepime or carbapenems for the treatment of bloodstream infections due to bacteria producing chromosomal AmpC beta-lactamase: a systematic review and meta-analysis.

Background: The best treatment for bloodstream infections (BSI) due to chromosomal AmpC (c-AmpC) producing Enterobacterales is not clearly defined.

Objectives: To describe the clinical and microbiological outcomes of patients treated with piperacillin/tazobactam, cefepime or carbapenems for bloodstream infections (BSIs) due to c-AmpC beta-lactamase-producing strains.

Data Sources: We searched MEDLINE, the Cochrane Library and EMBASE to screen original reports published up to January 2024.

Perceval sutureless bioprosthesis versus Trifecta sutured bioprosthesis for aortic valve replacement: immediate results of the study.

Introduction: The Perceval sutureless biological prosthesis for aortic valve replacement has been introduced with the rationale for shortening surgical, extracorporeal circulation and aortic cross-clamping times, in order to reduce postoperative complications.

Aim: To evaluate early hemodynamic performance and immediate outcomes of implantation of the Perceval sutureless bioprosthesis in comparison with the St. Jude Trifecta sutured bioprosthesis for aortic valve replacement (Perfecta study).

Glycocalyx Interactions Modulate the Cellular Uptake of Albumin-Coated Nanoparticles.

Albumin-based nanoparticles (ABNPs) represent promising drug carriers in nanomedicine due to their versatility and biocompatibility, but optimizing their effectiveness in drug delivery requires understanding their interactions with and uptake by cells. Notably, albumin interacts with the cellular glycocalyx, a phenomenon particularly studied in endothelial cells. This observation suggests that the glycocalyx could modulate ABNP uptake and therapeutic efficacy, although this possibility remains unrecognized.

Optimization of Cell Membrane Purification for the Preparation and Characterization of Cell Membrane Liposomes.

Cell membrane nanoparticles have attracted increasing interest in nanomedicine because they allow to exploit the complexity of cell membrane interactions for drug delivery. Several methods are used to obtain plasma membrane to generate cell membrane nanoparticles. Here, an optimized method combining nitrogen cavitation in isotonic buffer and sucrose gradient fractionation is presented.