Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h
about
Collective Experience: A Database-Fuelled, Inter-Disciplinary Team-Led Learning SystemICU Pad Project: application of modern computer technology in pediatric postoperative cardiac intensive care. Pilot studyLower tidal volume at initiation of mechanical ventilation may reduce progression to acute respiratory distress syndrome: a systematic reviewAcute respiratory distress syndrome following cardiovascular surgery: current concepts and novel therapeutic approachesClinical Practice Guideline of Acute Respiratory Distress SyndromeMultiparameter Intelligent Monitoring in Intensive Care II: a public-access intensive care unit databaseExtracorporeal membrane oxygenation for critically ill patients with 2009 influenza A (H1N1)-related acute respiratory distress syndrome: preliminary experience from a single center.Blood product transfusion in emergency department patients: a case-control study of practice patterns and impact on outcomeMechanical ventilation modulates Toll-like receptor-3-induced lung inflammation via a MyD88-dependent, TLR4-independent pathway: a controlled animal study.Reducing the burden of acute respiratory distress syndrome: the case for early intervention and the potential role of the emergency department.Hypervolemia induces and potentiates lung damage after recruitment maneuver in a model of sepsis-induced acute lung injury.Current ventilation practice during general anaesthesia: a prospective audit in Melbourne, AustraliaThe utility of clinical predictors of acute lung injury: towards prevention and earlier recognitionBody mass index is associated with the development of acute respiratory distress syndromeOxygen saturation/fraction of inspired oxygen ratio is a simple predictor of noninvasive positive pressure ventilation failure in critically ill patientsAlveolar instability (atelectrauma) is not identified by arterial oxygenation predisposing the development of an occult ventilator-induced lung injuryTransfusion of fresh frozen plasma in non-bleeding ICU patients--TOPIC trial: study protocol for a randomized controlled trial.Kidney failure related to broad-spectrum antibiotics in critically ill patients: secondary end point results from a 1200 patient randomised trial.Passive leg raising can predict fluid responsiveness in patients placed on venovenous extracorporeal membrane oxygenation.Mechanical Ventilation and ARDS in the ED: A Multicenter, Observational, Prospective, Cross-sectional Study.Sepsis-associated pulmonary complications in emergency department patients monitored with serial lactate: An observational cohort studyMechanical Ventilation as a Therapeutic Tool to Reduce ARDS Incidence.Influence of low tidal volume ventilation on time to extubation in cardiac surgical patients.Acute respiratory distress syndrome: prevention and early recognition.Lung-protective ventilation initiated in the emergency department (LOV-ED): a study protocol for a quasi-experimental, before-after trial aimed at reducing pulmonary complicationsAccuracy of height estimation and tidal volume setting using anthropometric formulas in an ICU Caucasian population.Mechanical ventilation and acute lung injury in emergency department patients with severe sepsis and septic shock: an observational studyAcute respiratory distress syndrome after spontaneous intracerebral hemorrhage*Participation of mammalian target of rapamycin complex 1 in Toll-like receptor 2- and 4-induced neutrophil activation and acute lung injury.Suppressive oligonucleotides inhibit inflammation in a murine model of mechanical ventilator induced lung injury.Contemporary ventilator management in patients with and at risk of ALI/ARDS.Designing a better "nest": applicable to preventing hospital exposures to risk factors for acute respiratory distress syndrome or just retrospective study design?Does point of care prothrombin time measurement reduce the transfusion of fresh frozen plasma in patients undergoing major surgery? The POC-OP randomized-controlled trial.The NLRP3 inflammasome is required for the development of hypoxemia in LPS/mechanical ventilation acute lung injury.The effect of demographics and patient location on the outcome of patients with acute respiratory distress syndrome.State of the art: strategies for extracorporeal membrane oxygenation in respiratory failure.Advances in ventilator-associated lung injury: prevention is the target.Potential Strategies to Prevent Ventilator-associated Events.Protocols for massive blood transfusion: when and why, and potential complications.Plasma membrane wounding and repair in pulmonary diseases.
P2860
Q24273269-50272ED3-24C4-4433-90A2-2468D86456FFQ26747018-B85F789D-641D-47AE-BF51-2CFFCB7ADCF9Q27025304-878AF8C6-B157-413A-816E-7E982ED03E01Q27693319-E03352E4-A8D6-4339-AE71-CF9692020790Q28074353-E2B5673D-5E06-46FC-B7E8-942B10AA4181Q28743230-B195DF5B-66A7-4856-9B04-DF9485F7D3E3Q30418681-3C6EEC5D-BEED-448D-9DC7-7B28A305AC6EQ30837280-CEC15FD4-EAA0-4790-9208-E54B8F98826FQ33751850-FE7762E3-D86F-4EA8-ABD8-D8FE8B08ADB8Q33940879-2DB3C7B4-9E8A-4F75-AA11-132CADA7A836Q34027021-D554DC23-7D41-4E5F-BF20-BEF6B3D9E03CQ34309216-C04F38B2-95A9-4ABA-9B0C-BD4E362690E8Q34603444-51032C46-1531-47A4-8B8E-1FD493C19DA1Q34956191-83E9E809-E126-40EF-BA83-556A91312A79Q35050891-DCBA1ECE-F38E-4889-B80D-807B83029E3DQ35717489-D2755760-6792-4AB2-B1E5-B023BBBDA7EAQ35772078-ABDD770B-0EED-43DF-A8A9-B6F2CE7A1236Q35838490-2616DFBC-599B-402B-8D73-E99C75550114Q35908123-C82DB654-74FC-4DCC-902B-F30087B39FE3Q35914601-22932935-D322-47E7-AC80-DC1D4BB88F5AQ36288408-364FFC05-76B6-4DC8-B291-5CA5715A4DC0Q36335724-E21523DA-5DAC-4832-A6E7-DC26F88DEAA6Q36405711-E4B096C4-F4E6-47F5-A0D1-BF99578426C5Q36803291-584D5F05-A816-4036-8C40-0BED0AB3B098Q36819149-838208CC-EC4E-4ECA-8217-E19F0F57262EQ37026754-E8A9F6D0-025C-463B-BE3F-D52116CC0B5CQ37032823-BDAB398B-0F27-41FD-89EE-BB0FCC584885Q37119211-6D1D8341-8667-4AAC-88B4-F92062EDF02BQ37275496-931684A2-47B9-48D0-B97D-446B9996F411Q37329356-8DB401FC-BADB-4DB5-B18B-C2E6088ECD6DQ37341406-FF8D4880-9F3B-4345-A3CF-9A17A8784CD9Q37405930-4F69775D-C321-45EA-AE7E-F1890ED225A0Q37448482-5530273A-B5CF-4AAB-BA21-E64356F19A6DQ37596140-5D8694C4-6D5B-4AEE-B1CE-924A9944AD51Q37604417-CC2EE313-6031-4896-835B-09215CCE6995Q38058353-39A649AD-0C66-4D0B-B06E-8AC6EAB0F9BBQ38193860-F03996F9-99EB-46C1-8154-3A2542C190B0Q38591718-E58282AA-EE68-4A08-9EA6-B9A4B000A0CFQ38663991-330FC44B-E9BC-4D07-966E-9FFCBFAD7101Q39071297-9BF8F6B4-4E6E-4A55-8D52-0ADFD84D677A
P2860
Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 08 February 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h
@en
Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h.
@nl
type
label
Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h
@en
Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h.
@nl
prefLabel
Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h
@en
Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h.
@nl
P2093
P2860
P921
P356
P1433
P1476
Risk factors for ARDS in patients receiving mechanical ventilation for > 48 h
@en
P2093
Atul Malhotra
Daniel Talmor
Mohammed Saeed
Roger G Mark
Xiaoming Jia
P2860
P304
P356
10.1378/CHEST.07-1121
P407
P577
2008-02-08T00:00:00Z