Phospholipid Nanoparticles: A Novel Colloid for Blood Volume Replacement, Reanimation, and Organ Protection in Hemorrhagic Shock.

: Exsanguination is a leading cause of preventable death in military and civilian settings due to extensive blood loss and hemorrhagic shock, which trigger systemic effects such as impaired tissue perfusion, hypoxia, inflammation, and multi-organ dysfunction. Standard resuscitation restores blood volume but fails to address critical aspects of hemorrhagic shock, including inflammation, coagulopathy, and reperfusion injury. To address these limitations, novel phospholipid nanoparticle (PNP)-based resuscitative fluids, VBI-S and VBI-1, were developed to modulate nitric oxide (NO) levels, improving hemodynamic stability, tissue oxygenation, and reducing inflammatory injury.

Describing acute coronary syndrome symptom information on social media platforms.

Background: Social media is a common source of health-related information. However, more clarity regarding ACS symptom information posted on social media is needed.

Objectives: The objective was to describe ACS symptom information on social media platforms, including Twitter (now named X), Instagram, and TikTok.

Selective nitric oxide redistribution by phospholipid nanoparticles: A novel strategy to mitigate massive nitric oxide release and prevent reperfusion injury in septic shock.

Nitric oxide plays a critical role in regulating vascular tone, but excessive nitric oxide release during septic shock results in hypotension due to excessive vasodilation and the formation of toxic free radicals. VBI-S is a phospholipid nanoparticle based fluid composed of lipid bilayers formed primarily by phosphatidylcholine and micelles of soybean oil encapsulated by a monolayer of phosphatidylcholine. These nanoparticles offer a novel solution by absorbing and redistributing nitric oxide and nitrite, potentially mitigating the harmful effects of excessive nitric oxide in sepsis.

Similar Strength and Power Adaptations between Two Different Velocity-Based Training Regimens in Collegiate Female Volleyball Players.

This study investigated the effects of two different velocity-based training (VBT) regimens on muscular adaptations. Fifteen female college volleyball players were randomly assigned into either progressive velocity-based training (PVBT) or optimum training load (OTL). Both groups trained three times a week for seven weeks.

Validation of volume and mass assessments for human fetal heart imaging by 4-dimensional spatiotemporal image correlation echocardiography: in vitro balloon model experiments.

Objective: This study was designed to validate a slow-sweep real-time 4-dimensional (4D) spatiotemporal image correlation method for producing quantitatively accurate dynamic fetal heart images using an in vitro pulsatile balloon model and apparatus.

Methods: To model fetal heart chambers, asymmetric double-walled finger stalls (tips of surgical latex gloves) were used and attached to a laboratory-designed circuit that allowed calibrated changes in the inner balloon volume as well as an intermediate gel mass interposed between the 2 layers. The water-submerged model was attached to a small-volume pulsatile pump to produce phasic changes in volume within the inner balloon at a fixed rate.

Fetal ventricular mass determination on three-dimensional echocardiography: studies in normal fetuses and validation experiments.

Background: Estimation of ventricular volume and mass is important for baseline and serial evaluation of fetuses with normal or abnormal hearts. Direct measurement of chamber wall volumes and mass can be made without geometric assumptions by 3D fetal echocardiography. Our goals were to determine the feasibility of using fast nongated 3D echocardiography for fetal volumetric and mass assessments, to validate the accuracy of the ultrasound system and the measurement technique, and if satisfactory, to develop normal values for fetal ventricular mass during the second and third trimesters.