Ventricular tachycardia ablation across age groups: Outcomes, trends and demographics. Insights from the National Inpatient Sample Database.

Background: Ventricular tachycardia ablation (VTA) is an important treatment option for ventricular tachycardia, with increasing use across all age groups. However, age-related differences in outcomes remain a concern.

Objective: This study aimed to investigate age-related trends in VTA procedures and their associated adverse events across the United States from 2011 to 2021.

Spanlastic Nano-Vesicles: A Novel Approach to Improve the Dissolution, Bioavailability, and Pharmacokinetic Behavior of Famotidine.

: Drugs exhibiting poor aqueous solubility present a challenge to efficient delivery to the site of action. Spanlastics (a nano, surfactant-based drug delivery system) have emerged as a powerful tool to improve solubility, bioavailability, and delivery to the site of action. This study aimed to better understand factors affecting the physicochemical properties of spanlastics, quantify their effects, and use them to enhance the bioavailability of famotidine (FMT), a model histamine H2 receptor antagonist (BCS class IV).

Understanding Cardiac Anatomy and Imaging to Improve Safety of Procedures: The Femoral Artery and Vein: Part 2.

This paper revisits and shows comprehensive femoral access site anatomy with a combination of images obtained from detailed cadaveric dissection, fluoroscopy, computed tomography, ultrasound, and 3-dimensional printings. Part 2 focuses on the fluoroscopic anatomy, pelvic cavity, and complications. In addition, a file for 3-dimensional printing is provided.

Understanding Cardiac Anatomy and Imaging to Improve Safety of Procedures: The Femoral Artery and Vein: Part 1.

We revisit and show comprehensive femoral access site anatomy with a combination of images obtained from detailed cadaveric dissection, fluoroscopy, computed tomography, ultrasound, and 3-dimensional printings. Part 1 focuses on the femoral triangle, femoral bifurcation, fluoroscopic and/or ultrasonographic anatomy, and branches of the femoral artery. Profound understanding of this region is fundamental to facilitate safe procedures and to avoid unnecessary complications.

A computational model that integrates unrestricted callus growth, mechanobiology, and angiogenesis can predict bone healing in rodents.

We present a computational model that integrates mechanobiological regulations, angiogenesis simulations and models natural callus development to simulate bone fracture healing in rodents. The model inputs include atomic force microscopy values and micro-computed tomography on the first-day post osteotomy, which, combined with detailed finite element modeling, enables scrutinizing mechanical and biological interactions in early bone healing and throughout the healing process. The model detailed mesenchymal stem cell migration patterns, which are essential for tissue transformation and vascularization during healing, indicating the vital role of blood supply in the healing process.