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101 0 $aeng
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181   $ctxt$2rdacontent
182   $cc$2rdamedia
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200 00$aAnnual update in intensive care and emergency medicine 2022 /$fedited by Jean-Louis Vincent
210  1$aCham, Switzerland :$cSpringer,$d[2022]
210  4$d©2022
215   $a1 online resource (398 pages)
225 1 $aAnnual Update in Intensive Care and Emergency Medicine
311 08$aPrint version: Vincent, Jean-Louis Annual Update in Intensive Care and Emergency Medicine 2022 Cham : Springer International Publishing AG,c2022 9783030934323 
320   $aIncludes bibliographical references and index.
327   $aIntro -- Contents -- Abbreviations -- Part I: Sepsis and the Immune Response -- 1: The Role of Mitochondria in the Immune Response in Critical Illness -- 1.1  Introduction -- 1.2  Mitochondrial Machinery That Mediates and Regulates Immune Responses in Critical Illness -- 1.2.1  Metabolic Reprogramming -- 1.2.2  Mitochondrial ROS and mtDNA -- 1.2.3  Succinate and Itaconate -- 1.2.4  Mitochondrial Dynamics -- 1.3  Immunometabolism: The Perfect World Scenario vs. the Critical Illness Scenario -- 1.4  Potential of Mitochondria-Targeting Therapy in Critical Care -- 1.5  Challenges of Applying Mitochondria-Targeting Therapy in Critical Care -- 1.6  Conclusion -- References -- 2: Immunomodulation by Tetracyclines in the Critically Ill: An Emerging Treatment Option? -- 2.1  Introduction -- 2.2  Immunopathogenesis of Sepsis -- 2.3  Immunopathogenesis of ARDS -- 2.4  Mechanisms of Action of Tetracyclines in ARDS -- 2.4.1  In Vivo Models -- 2.4.1.1  Effects on Inflammatory Cytokines and NLRP3 Inflammasome Caspase-1 Signaling -- 2.4.1.2  Effects on MMPs -- 2.4.1.3  Effects on Neutrophil Transmigration -- 2.4.2  Human Data -- 2.5  Mechanisms of Action of Tetracyclines in Sepsis -- 2.5.1  In Vitro Models -- 2.5.1.1  Effects on Cytokine and Chemokine Production -- 2.5.1.2  Effects on Arachidonic Acid Metabolites and NO Production -- 2.5.2  In Vivo Models -- 2.5.2.1  Effects on MAPK Signaling Pathways and Inflammatory Mediators -- 2.5.2.2  Effects on Organ Dysfunction -- 2.5.3  Human Data -- 2.6  Future Research Perspectives -- 2.7  Conclusion -- References -- 3: Hit Early: Blocking Interleukin-1 in the Treatment of COVID-19 Pneumonia -- 3.1  Introduction -- 3.2  Cytokines and Disease Progression in COVID-19 -- 3.3  Contribution of Monocytes and Macrophages in Early Cytokine Response -- 3.4  How Can Early Activation of IL-1 Be Identified?.
327   $a3.5  SAVE Strategy: Early Blockade of IL-1 Guided by Biomarkers -- 3.6  Conclusion -- References -- 4: Hemoadsorption Therapy During ECMO: Emerging Evidence -- 4.1  Introduction -- 4.2  Devices and Implementation -- 4.3  Hemoadsorption in Combination with ECMO -- 4.4  Hemoadsorption in Severe COVID-19 Supported with ECMO -- 4.5  Discussion and Outlook -- 4.6  Conclusion -- References -- Part II: Respiratory Issues -- 5: The Forgotten Circulation and Transpulmonary Pressure Gradients -- 5.1  Introduction -- 5.2  Pulmonary Vessel Anatomy -- 5.3  Pulmonary Vascular Dysfunction -- 5.4  Pulmonary Circulation and Its Components -- 5.4.1  The Transpulmonary Driving Pressure: A Small Gradient with Big Importance -- 5.4.2  Pulmonary Vascular Resistance and 'Closing Pressures' -- 5.5  Measuring the Transpulmonary Pressure Gradient -- 5.6  The Evolving Role of Pulmonary Arterial Compliance -- 5.7  Relevant Clinical Scenarios in Critical Illness -- 5.7.1  Pulmonary Hypertension -- 5.7.2  Right Ventricular Dysfunction -- 5.8  Can Right Ventricular-Pulmonary Arterial (RV-PA) Coupling Shed more Light on the RV-Pulmonary Circuit in Critical Illness? -- 5.9  Conclusion -- References -- 6: Oxygen: Origin, Physiology, Pathophysiology, and Use in the Critically Ill -- 6.1  Introduction -- 6.2  Origin of Oxygen in the Earth's Atmosphere -- 6.3  Measurements and Estimations of Oxygenation -- 6.4  Definition of Hypoxemia, Normoxemia, and Hyperoxemia -- 6.5  Physiology of Oxygen in Humans -- 6.6  Pathophysiology of Oxygen in Humans: Hypoxemia and Effects of Lack of O2 -- 6.7  Pathophysiology of Oxygen in Humans: Hyperoxia, Hyperoxemia, and O2 Toxicity -- 6.8  Effects of Normoxia, Hypoxia and Hyperoxia in Critically Ill Patients -- 6.9  Future Studies -- 6.10  Conclusion -- References -- 7: Nebulized Therapeutics for COVID-19 Pneumonia in Critical Care -- 7.1  Introduction.
327   $a7.2  Nebulized Therapeutics for COVID-19 Pneumonia -- 7.3  Technical Aspects of Nebulized Drug Therapy -- 7.4  Current Clinical Trials on Nebulized COVID-19 Therapeutics in Critical Care -- 7.4.1  Antivirals -- 7.4.1.1  Chloroquine/Hydroxychloroquine -- 7.4.1.2  Remdesivir -- 7.4.1.3  Ivermectin -- 7.4.2  Immunomodulators -- 7.4.2.1  Granulocyte-Monocyte Colony-Stimulating Factor (GM-CSF) -- 7.4.3  Anticoagulants -- 7.4.3.1  Heparin -- 7.4.4  Fibrinolytics -- 7.4.4.1  Tissue Plasminogen Activator (t-PA) -- 7.4.5  Anti-Inflammatory Agents -- 7.4.5.1  Interferon -- 7.4.5.2  Steroids -- 7.4.5.3  Retinoic Acid -- 7.4.6  Mucokinetics/Mucolytics -- 7.4.6.1  Dornase Alfa -- 7.4.7  Pulmonary Vasodilators -- 7.4.7.1  Epoprostenol, Iloprost -- 7.4.8  Miscellaneous -- 7.4.8.1  Surfactant -- 7.5  Barriers to Safe and Effective Nebulized Therapy in COVID-19 Pneumonia in Critical Care -- 7.6  Conclusion -- References -- Part III: Mechanical Ventilation -- 8: Positive End-Expiratory Pressure in Invasive and Non-invasive Ventilation of COVID-19 Acute Respiratory Distress Syndrome -- 8.1  Introduction -- 8.2  Evidence for a Unique CARDS Pathophysiology -- 8.3  A Computational Simulator to Compare CARDS Versus ARDS Pathophysiology -- 8.4  Setting PEEP in Invasive Mechanical Ventilation of CARDS Patients -- 8.5  Setting PEEP in Non-invasive Pressure Support Ventilation of CARDS Patients -- 8.6  Conclusion -- References -- 9: Personalized Mechanical Ventilation Settings: Slower Is Better! -- 9.1  Introduction -- 9.2  Strain, Stress, and Strain Rate: Insights from Polymeric Material -- 9.3  Origins of the Mechanical Power Formula: The Components Must Respect Time -- 9.4  Slow the Changes in Tidal Volume during Mechanical Ventilation -- 9.5  Slow the Changes in Respiratory Rate during Mechanical Ventilation -- 9.5.1  Prolonged Versus Short Inspiratory Time?.
327   $a9.5.2  High Versus Low Inspiratory Flow? -- 9.6  Stepwise Increase in Airway Pressure during Recruitment Maneuvers -- 9.7  Slow Decreases in PEEP Levels and Lung Damage -- 9.8  Smooth the Expiration Phase: Does It Matter? -- 9.9  Conclusion -- References -- 10: Spontaneous Breathing in Acute Respiratory Failure -- 10.1  Introduction -- 10.2  Acute Respiratory Distress Syndrome -- 10.3  Mechanical Ventilation and VILI -- 10.4  Stress, Strain, and Stress Raisers -- 10.5  P-SILI and Assisted Ventilation -- 10.6  Lung Mechanics and Pulmonary Heterogeneity -- 10.7  Conclusion -- References -- 11: Laryngeal Injury: Impact on Patients in the Acute and Chronic Phases -- 11.1  Introduction -- 11.2  Laryngeal Injury -- 11.2.1  Endotracheal Intubation -- 11.2.2  Identification and Management of Laryngeal Injury in the Acute Phase -- 11.3  Impact of Laryngeal Injury on the Patient in the Acute Phase -- 11.3.1  Swallowing and Return to Oral Intake -- 11.3.2  Communication in the ICU -- 11.4  Impact of Laryngeal Injury on the Patient in the Chronic Phase -- 11.5  Laryngeal Injury in the ICU and beyond -- 11.5.1  Clinical Assessment: Future Directions -- 11.5.2  Laryngeal Rehabilitation -- 11.5.3  Community Follow Up of Critical Illness Survivors -- 11.6  Conclusion -- References -- Part IV: Fluids and Electrolytes -- 12: Fluid Responsiveness as a Physiologic Endpoint to Improve Successful Weaning -- 12.1  Introduction -- 12.2  Weaning from Mechanical Ventilation -- 12.3  Weaning Failure -- 12.4  Weaning-Induced Pulmonary Edema -- 12.5  De-Resuscitation -- 12.6  Physiology-Based Fluid Depletion -- 12.7  Monitoring Fluid Responsiveness Prior to SBT -- 12.8  Conclusion -- References -- 13: Tidal Volume Challenge Test: Expanding Possibilities -- 13.1  Introduction -- 13.2  Rationale for Developing the Tidal Volume Challenge Test.
327   $a13.3  Reliability of the Tidal Volume Challenge Test to Predict Fluid Responsiveness -- 13.4  How to Perform and Interpret the Tidal Volume Challenge Test -- 13.5  Applications of the Tidal Volume Challenge Test -- 13.5.1  In ICU Patients Mechanically Ventilated Using Low Tidal Volumes -- 13.5.2  In Mechanically Ventilated Patients with Spontaneous Breathing Activity -- 13.5.3  In Patients with Normal Lungs Ventilated Using Low Tidal Volumes in the Operating Room -- 13.5.3.1  In the Supine Position -- 13.5.3.2  In the Prone Position -- 13.5.4  During Laparoscopic Surgery Using Pneumoperitoneum in the Trendelenburg Position -- 13.6  Comparison of Tidal Volume Challenge with Other Tests Used to Predict Fluid Responsiveness -- 13.7  Advantages of the Tidal Volume Challenge -- 13.8  Limitations of the Tidal Volume Challenge -- 13.9  Future Directions -- 13.10  Conclusion -- References -- 14: Fluid Management in COVID-19 ICU Patients -- 14.1  Introduction -- 14.2  Why Patients with COVID-19 Can Develop Acute Circulatory Failure? -- 14.2.1  Hypovolemia -- 14.2.2  Vasoplegia -- 14.2.3  Impaired Left Heart Function -- 14.2.4  Right Ventricular (RV) Dysfunction or Failure -- 14.3  Consequences of Fluid Therapy in COVID-19 Patients with Shock -- 14.4  How to Assess the Benefits and the Risks of Fluid Administration in COVID-19 Patients with Shock? -- 14.5  Summary -- 14.6  Conclusion -- References -- 15: Electrolytes in the ICU -- 15.1  Introduction -- 15.2  Physiology and Pathophysiology -- 15.2.1  Sodium: Regulator of Osmolality -- 15.2.1.1  Physiology -- 15.2.1.2  Pathophysiology -- 15.2.2  Potassium: Determinant of Excitability -- 15.2.2.1  Physiology -- 15.2.2.2  Pathophysiology -- 15.2.3  Magnesium: Membrane Stabilizer -- 15.2.3.1  Physiology -- 15.2.3.2  Pathophysiology -- 15.2.4  Calcium: Conduction and Contraction -- 15.2.4.1  Physiology.
327   $a15.2.4.2  Pathophysiology.
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