About this Research Topic
Supporting patients with acute respiratory distress syndrome (ARDS), remains a critical challenge in intensive care units (ICUs). Balancing gas exchange while minimizing Ventilator-Induced Lung Injury (VILI) is the main aims of mechanical ventilation. However, an equally crucial aspect lies in advanced monitoring techniques, which provide real-time, patient-specific data to guide decision-making in both invasive and non-invasive ventilation.
This Research Topic aims to collect cutting-edge research focused on the application of advanced monitoring techniques during the management of ARDS. We aim to promote a deeper understanding of the interaction between the patient’s respiratory mechanics and ventilator settings, ultimately contributing to improved patient outcomes.
A key area of interest is the monitoring of respiratory mechanics during mechanical ventilation. In passive patients receiving invasive ventilation, adjusting ventilator settings based on end-inspiratory plateau pressure and maintaining a safe driving pressure is a prudent strategy. In more challenging-to-ventilate patients, esophageal manometry remains the gold standard for fine-tuning ventilator parameters. This technique aids clinicians in setting mechanical ventilation to reduce the risk of VILI, by limiting excessive end-inspiratory alveolar distending pressures and preventing end-expiratory alveolar collapse, thus ensuring optimal lung protection. Additionally, in spontaneously breathing patients, esophageal balloon monitoring is a reliable method for assessing respiratory effort and optimizing the level of ventilatory assistance. In this context, monitoring the electrical activity of the diaphragm (EAdi) using Neurally Adjusted Ventilatory Assist (NAVA) provides invaluable insights into the interaction between patient effort and ventilator support, improving synchronization and minimizing the risk of over-assistance.
Moreover, imaging techniques are becoming increasingly integral in the monitoring of ARDS patients. Techniques such as lung ultrasound, computed tomography (CT) scans, and Electrical Impedance Tomography (EIT) offer non-invasive methods for assessing lung aeration, identifying patterns of overdistension or collapse, and guiding therapeutic interventions. These tools allow for a dynamic, real-time evaluation of the lung, facilitating tailored ventilation strategies based on the unique physiological responses of each patient.
This Research Topic welcomes Original Research articles, Reviews, and Case Studies that focus on the following areas:
• The use of advanced respiratory mechanics monitoring (e.g., esophageal pressure, NAVA) in both invasive and non-invasive mechanical ventilation for ARDS patients.
• The role of lung imaging techniques (ultrasound, CT, EIT) in guiding and optimizing mechanical ventilation.
• Novel insights into the application of these monitoring techniques to enhance patient-ventilator interactions and improve outcomes.
By fostering collaboration and innovation in this field, we hope to gather evidence that will help clinicians make more informed decisions and improve the quality of care for ARDS patients. We invite submissions that explore how these advanced monitoring techniques can mitigate the risks of VILI, optimize respiratory support, and ultimately lead to better outcomes in critically ill patients.
This Research Topic aims to collect cutting-edge research focused on the application of advanced monitoring techniques during the management of ARDS. We aim to promote a deeper understanding of the interaction between the patient’s respiratory mechanics and ventilator settings, ultimately contributing to improved patient outcomes.
A key area of interest is the monitoring of respiratory mechanics during mechanical ventilation. In passive patients receiving invasive ventilation, adjusting ventilator settings based on end-inspiratory plateau pressure and maintaining a safe driving pressure is a prudent strategy. In more challenging-to-ventilate patients, esophageal manometry remains the gold standard for fine-tuning ventilator parameters. This technique aids clinicians in setting mechanical ventilation to reduce the risk of VILI, by limiting excessive end-inspiratory alveolar distending pressures and preventing end-expiratory alveolar collapse, thus ensuring optimal lung protection. Additionally, in spontaneously breathing patients, esophageal balloon monitoring is a reliable method for assessing respiratory effort and optimizing the level of ventilatory assistance. In this context, monitoring the electrical activity of the diaphragm (EAdi) using Neurally Adjusted Ventilatory Assist (NAVA) provides invaluable insights into the interaction between patient effort and ventilator support, improving synchronization and minimizing the risk of over-assistance.
Moreover, imaging techniques are becoming increasingly integral in the monitoring of ARDS patients. Techniques such as lung ultrasound, computed tomography (CT) scans, and Electrical Impedance Tomography (EIT) offer non-invasive methods for assessing lung aeration, identifying patterns of overdistension or collapse, and guiding therapeutic interventions. These tools allow for a dynamic, real-time evaluation of the lung, facilitating tailored ventilation strategies based on the unique physiological responses of each patient.
This Research Topic welcomes Original Research articles, Reviews, and Case Studies that focus on the following areas:
• The use of advanced respiratory mechanics monitoring (e.g., esophageal pressure, NAVA) in both invasive and non-invasive mechanical ventilation for ARDS patients.
• The role of lung imaging techniques (ultrasound, CT, EIT) in guiding and optimizing mechanical ventilation.
• Novel insights into the application of these monitoring techniques to enhance patient-ventilator interactions and improve outcomes.
By fostering collaboration and innovation in this field, we hope to gather evidence that will help clinicians make more informed decisions and improve the quality of care for ARDS patients. We invite submissions that explore how these advanced monitoring techniques can mitigate the risks of VILI, optimize respiratory support, and ultimately lead to better outcomes in critically ill patients.
Keywords: ARDS, Mechanical Ventilation, Innovative Techniques, Monitoring, ICU
Important Note: All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.
