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− | '''[[Hypoxia tolerance]]''' | + | {{ft|A}} |
− | *[http://archive.is/VTqtr happy hypoxia experience]
| + | '''[[Resp Proning ]]''' |
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− | '''any other topic''' | + | '''[[Resp high-flow nasal cannula ]]''' |
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− | *[https://gab.com/TomDoniphon/posts/104162938810676022 proposal of iron lungs (kinderlähmung times)]
| + | '''[[Resp non-inv ]]''' |
− | {{tp|p=32285929|t=2020. Extracorporeal membrane oxygenation in COVID-19 |pdf=|usr=}}
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− | {{tp|p=32287142|t=2020. Pediatric Airway Management in Coronavirus Disease 2019 Patients: Consensus Guidelines From the Society for Pediatric Anesthesia?s Pediatric Difficult Intubation Collaborative and the Canadian Pediatric Anesthesia Society |pdf=|usr=}}
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− | {{tp|p=32360979|t=ä. Sedation for critically ill patients with COVID-19: which specificities? One size does not fit all |pdf=|usr=}}
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− | {{tp|p=32360978|t=2020. Preliminary observations of anaesthesia ventilators use for prolonged mechanical ventilation in intensive care unit patients during the COVID-19 pandemic |pdf=|usr=}}
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− | {{tp|p=32305591|t=ä. Treating hypoxemic patients with SARS-COV-2 pneumonia: Back to applied physiology |pdf=|usr=}}
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− | {{tp|p=32350543|t=ä. COVID-19-Pandemie: strukturierte Erweiterung von Beatmungskapazitäten mithilfe von Heimrespiratoren |pdf=|usr=}}
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− | {{tp|p=32333024|t=ä. Anästhesie- und Intensivbeatmungsgeräte: Unterschiede und Nutzbarkeit bei COVID-19-Patienten |pdf=|usr=}}
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− | {{tp|p=32209810|t=2020. Recommendations for Endotracheal Intubation of COVID-19 Patients |pdf=|usr=}}
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− | {{tp|p=32250977|t=2020. Your COVID-19 Intubation Kit |pdf=|usr=}}
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− | {{tp|p=32345852|t=2020. COVID-19 and One-Lung Ventilation |pdf=|usr=}}
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− | {{tp|p=32345859|t=2020. Use of a Modified System for Manual Ventilation of the Patient for In-Hospital and Extra-Hospital Transport to Avoid Aerosolizing Spread of Droplets During COVID-19 Outbreak |pdf=|usr=}}
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− | {{tp|p=32345856|t=2020. Adaptation to the Plastic Barrier Sheet to Facilitate Intubation During the COVID-19 Pandemic |pdf=|usr=}}
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− | {{tp|p=32324597|t=2020. Barrier Shields: Not Just for Intubations in Today?s COVID-19 World?|pdf=|usr=}}
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− | {{tp|p=32287141|t=2020. Role of Mask/Respirator Protection Against SARS-CoV-2 |pdf=|usr=}}
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− | {{tp|p=32282387|t=2020. A Carton-Made Protective Shield for Suspicious/Confirmed COVID-19 Intubation and Extubation During Surgery |pdf=|usr=}}
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− | {{tp|p=32304463|t=2020. COVID-19 Putting Patients at Risk of Unplanned Extubation and Airway Providers at Increased Risk of Contamination |pdf=|usr=}}
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− | {{tp|p=32195703|t=2020. Precautions for Intubating Patients with COVID-19 |pdf=|usr=}}
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− | {{tp|p=32195705|t=2020. Intubation and Ventilation amid the COVID-19 Outbreak: Wuhan?s Experience |pdf=|usr=}}
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− | {{tp|p=32287047|t=2020. Emergency Open-source Three-dimensional Printable Ventilator Circuit Splitter and Flow Regulator during the COVID-19 Pandemic |pdf=|usr=}}
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− | {{tp|p=32334882|t=ä. A Protection Tent for Airway Management in Patients With COVID-19 Infection |pdf=|usr=}}
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− | {{tp|p=32232685|t=2020. The experience of high-flow nasal cannula in hospitalized patients with 2019 novel coronavirus-infected pneumonia in two hospitals of Chongqing, China |pdf=|usr=}}
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− | {{tp|p=32315800|t=ä. A model for a ventilator-weaning and early rehabilitation unit to deal with post-ICU impairments with severe COVID-19 |pdf=|usr=}}
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− | {{tp|p=32353441|t=ä. MANAGEMENT OF PERSISTENT PNEUMOTHORAX WITH THORACOSCOPY AND BLEBS RESECTION IN COVID-19 PATIENTS |pdf=|usr=}}
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− | {{tp|p=32339508|t=ä. Novel Percutaneous Tracheostomy for Critically Ill Patients with COVID-19 |pdf=|usr=}}
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− | {{tp|p=32232219|t=2020. The COVID-19 Intubation and Ventilation Pathway (CiVP); a Commentary |pdf=|usr=}}
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− | {{tp|p=32345515|t=ä. Anesthetic and surgical management of tracheostomy in a patient with COVID-19 |pdf=|usr=}}
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− | {{tp|p=32303376|t=ä. Extubation of patients with COVID-19 |pdf=|usr=}}
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− | {{tp|p=32362339|t=ä. The Wuhan COVID-19 intubation experience |pdf=|usr=}}
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− | {{tp|p=32312572|t=ä. Reducing droplet spread during airway manipulation: lessons from the COVID-19 pandemic in Singapore |pdf=|usr=}}
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− | {{tp|p=32362340|t=ä. COVID-19 patients with respiratory failure: what can we learn from aviation medicine?|pdf=|usr=}}
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− | {{tp|p=32340733|t=ä. Rapid Ramp-up of Powered Air-Purifying Respirator (PAPR) Training for Infection Prevention and Control during the COVID-19 Pandemic |pdf=|usr=}}
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− | {{tp|p=32312570|t=ä. Extubation barrier drape to minimise droplet spread |pdf=|usr=}}
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− | {{tp|p=32312573|t=ä. Fibreoptic tracheal intubation in COVID-19: not so fast |pdf=|usr=}}
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− | {{tp|p=32312571|t=ä. Emergency tracheal intubation in 202 patients with COVID-19 in Wuhan, China: lessons learnt and international expert recommendations |pdf=|usr=}}
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− | {{tp|p=32321662|t=ä. Surgical tracheostomies in Covid-19 patients: Important considerations and the ?5Ts? of safety |pdf=|usr=}}
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− | {{tp|p=32322128|t=ä. Management of CO2 absorbent while using the anesthesia machine as a mechanical ventilator on patients with COVID-19 |pdf=|usr=}}
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− | {{tp|p=32180173|t=ä. Lidocaine during intubation and extubation in patients with coronavirus disease (COVID-19) |pdf=|usr=}}
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− | {{tp|p=32323101|t=ä. Safer intubation and extubation of patients with COVID-19 |pdf=|usr=}}
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− | {{tp|p=32319029|t=ä. Patient self-proning with high-flow nasal cannula improves oxygenation in COVID-19 pneumonia |pdf=|usr=}}
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− | {{tp|p=32291633|t=ä. Locating and repurposing anesthetic machines as intensive care unit ventilators during the COVID-19 pandemic |pdf=|usr=}}
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− | {{tp|p=32223782|t=ä. Just the Facts: Airway management during the coronavirus disease 2019 (COVID-19) pandemic |pdf=|usr=}}
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− | {{tp|p=32313662|t=2020. Veno-venous extracorporeal membrane oxygenation for severe pneumonia: COVID-19 case in Japan |pdf=|usr=}}
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− | {{tp|p=32371555|t=2020. Utility of extracorporeal membrane oxygenation in COVID-19 |pdf=|usr=}}
| + | '''[[Resp invasive ]]''' |
− | {{tp|p=32357995|t=2020. Tracheal intubation in patients with COVID-19 |pdf=|usr=}}
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− | {{tp|p=32326959|t=2020. High-flow nasal cannula may be no safer than non-invasive positive pressure ventilation for COVID-19 patients |pdf=|usr=}}
| + | '''[[Resp Tracheotomy ]]''' |
− | {{tp|p=C7156900|t=2020. Prognosis when using extracorporeal membrane oxygenation (ECMO) for critically ill COVID-19 patients in China: a retrospective case series |pdf=|usr=}}
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− | {{tp|p=32322959|t=ä. Tracheostomy in the COVID-19 pandemic |pdf=|usr=}}
| + | '''[[Resp Intubation ]]''' |
− | {{tp|p=32314050|t=ä. Recommendation of a practical guideline for safe tracheostomy during the COVID-19 pandemic |pdf=|usr=}}
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− | {{tp|p=32299867|t=2020. High-flow nasal cannula for COVID-19 patients: low risk of bio-aerosol dispersion |pdf=|usr=}}
| + | '''[[Resp ECMO ]]''' |
− | {{tp|p=32271455|t=2020. Successful treatment of COVID-19 using extracorporeal membrane oxygenation, a case report |pdf=|usr=}}
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| + | '''[[Resp var./rev. ]]''' |
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| + | '''[[Resp adv.effects ]]''' |
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| + | '''[[Resp other modalities ]]''' |
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| + | '''[[Resp non-conventional machines]]''' |
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| + | '''[[Resp Sedation]]''' |
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| + | '''[[Resp NO]]''' |
| + | |
| + | '''[[Hypoxia tolerance]]''' |