Visualizing hemodynamics: innovative graphical displays and imaging techniques in anesthesia and critical care

• Published in: Critical care (London, England) Vol. 29; no. 1; p. 3
• Main Authors: Michard, Frederic, Wong, Adrian, Kanoore Edul, Vanina
• Format: Journal Article
• Language: English
• Published: London BioMed Central 03.01.2025; BioMed Central Ltd; Springer Nature B.V
• Subjects: Algorithms; Anesthesia; Blood pressure; Clinical outcomes; Critical care; Critical Care Medicine; Diagnostic imaging; Echocardiography; Emergency Medicine; Heart rate; Hemodynamic monitoring; Hemodynamics; Image processing; Imaging in Critical Care; Innovations; Intensive; Machine learning; Magnetic resonance imaging; Medical personnel; Medicine; Medicine & Public Health; Methods; Oxygen saturation; Patients; Physiology; Point of care testing; Pulmonary arteries; Review; Sepsis; Shock (Circulatory); Technological change; Technology application; Trends; Ultrasonic imaging; Visualization (Computers); Workloads; United Kingdom; Echocardiography; Visual decision support; Speckle tracking; Videomicroscopy; Hemodynamic monitoring; Machine learning
• ISSN: 1364-8535; 1466-609X; 1364-8535; 1466-609X; 1366-609X
• DOI: 10.1186/s13054-024-05239-w

The advancements in cardiovascular imaging over the past two decades have been significant. The miniaturization of ultrasound devices has greatly contributed to their widespread adoption in operating rooms and intensive care units. The integration of AI-enabled tools has further transformed the field by simplifying echocardiographic evaluations and enhancing the reproducibility of hemodynamic measurements, even for less experienced operators. Speckle tracking echocardiography offers a direct, visual, and quantitative assessment of myocardial shortening, serving as a compelling alternative to traditional methods for evaluating right and left ventricular systolic function. In critically ill patients, sublingual microcirculation imaging has revealed a high prevalence of microvascular alterations, which are markers of disease severity. The use of handheld vital microscopes enables the quantification of several key parameters, including vessel density, perfusion, red blood cell velocity, and the perfused vascular density. Such metrics are useful for evaluating microcirculatory health. The development of automated software marks a significant advance toward real-time bedside microvascular assessment. These advancements could eventually allow shock resuscitation to be tailored based on microvascular responses. In parallel with imaging advances, cardiac output monitors have evolved significantly. Once cumbersome devices displaying basic numerical data in tabular form, they now feature sleek, touch-screen interfaces integrated with visual decision-support tools. These tools synthesize hemodynamic data into intuitive graphical formats, allowing clinicians to quickly grasp the determinants of circulatory shock. This visual clarity supports more efficient and accurate decision-making, which may ultimately lead to improved patient care and outcomes.