摘要
原文 | 英語 |
---|---|
頁(從 - 到) | 658-662 |
頁數 | 5 |
期刊 | American Journal of Emergency Medicine |
卷 | 33 |
發行號 | 5 |
DOIs | |
出版狀態 | 已發佈 - 2015 |
對外發佈 | 是 |
指紋
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於: American Journal of Emergency Medicine, 卷 33, 編號 5, 2015, p. 658-662.
研究成果: 雜誌貢獻 › 文章 › 同行評審
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TY - JOUR
T1 - Use of extracorporeal membrane oxygenation in severe traumatic lung injury with respiratory failure
AU - Wu, Shih-Chi
AU - Chen, Tzu-Liang
AU - Lin, Hui-Han
AU - Fu, Chih-Yuan
AU - Wang, Yu-Chun
AU - Lo, Hung-Chieh
AU - Cheng, Han-Tsung
AU - Tzeng, Chia-Wei
N1 - Export Date: 24 March 2016 CODEN: AJEME 通訊地址: Wu, S.-C.; Trauma and Emergency Center, China Medical University Hospital, No. 2 Yuh-Der Road, Taiwan 化學物質/CAS: oxygen, 7782-44-7 參考文獻: Rossaint, R., Cerny, V., Coats, T.J., Duranteau, J., Fernández-Mondéjar, E., Gordini, G., Key issues in advanced bleeding care in trauma (2006) Shock, 26, pp. 322-331; Krug, E.G., Sharma, G.K., Lozano, R., The global burden of injuries (2000) Am J Public Health, 90, pp. 523-526; Vecsei, V., Arbes, S., Aldrian, S., Nau, T., Chest injuries in polytrauma (2005) Eur J Trauma, 31, pp. 239-243; Brower, R.G., Lanken, P.N., Macintyre, N., Matthay, M.A., Morris, A., Ancukiewicz, M., National Heart, Lung, and Blood Institute ARDS Clinical Trials Network: Higher versus lower positive end-expiratory pressures in patients with the acute respiratory distress syndrome (2004) N Engl J Med, 351, pp. 327-336; Determann, R.M., Royakkers, A., Wolthuis, E.K., Vlaar, A.P., Choi, G., Paulus, F., Ventilation with lower tidal volumes as compared with conventional tidal volumes for patients without acute lung injury: A preventive randomized controlled trial (2010) Crit Care, 14 (1), p. R1; Burns, K.E., Adhikari, N.K., Slutsky, A.S., Guyatt, G.H., Villar, J., Zhang, H., Pressure and volume limited ventilation for the ventilatory management of patients with acute lung injury: A systematic review and meta-analysis (2011) PLoS ONE, 6 (1), p. e14623; Vasilyev, S., Schaap, R.N., Mortensen, J.D., Hospital survival rates of patients with acute respiratory failure in modern respiratory intensive care units: An international, multicenter, prospective study (1995) Chest, 107, pp. 1083-1088; Maccallum, N.S., Evans, T.W., Epidemiology of acute lung injury (2005) Curr Opin Crit Care, 11 (1), pp. 43-49; Rubenfeld, G.D., Caldwell, E., Peabody, E., Weaver, J., Martin, D.P., Neff, M., Incidence and outcomes of acute lung injury (2005) N Engl J Med, 353 (16), pp. 1685-1693; Villar, J., Blanco, J., Añón, J.M., Santos-Bouza, A., Blanch, L., Ambrós, A., The ALIEN study: Incidence and outcome of acute respiratory distress syndrome in the era of lung protective ventilation (2011) Intensive Care Med, 37 (12), pp. 1932-1941; Checkley, W., Extracorporeal membrane oxygenation as a first-line treatment strategy for ARDS: Is the evidence sufficiently strong? (2011) JAMA, 306, pp. 1703-1704; Peek, G.J., Mugford, M., Tiruvoipati, R., Wilson, A., Allen, E., Thalanany, M.M., Efficacy and economic assessment of conventional ventilatory support versus extracorporeal membrane oxygenation for severe adult respiratory failure (CESAR): A multicentre randomised controlled trial (2009) Lancet, 374, pp. 1351-1363; Keel, M., Meier, C., Chest injuries - What is new? (2007) Curr Opin Crit Care, 13, pp. 674-679; UK collaborative randomized trial of neonatal extracorporeal membrane oxygenation (1996) Lancet, 348, pp. 75-82; Ferguson, N.D., Fan, E., Camporotal, L., Antonelli, M., Anzueto, A., Beale, R., The Berlin definition of ARDS: An expanded rationale, justification, and supplementary material (2012) Intensive Care Med, 38 (10), pp. 1573-1582; Madershahian, N., Wittwer, T., Strauch, J., Franke, U.F., Wippermann, J., Kaluza, M., Application of ECMO in multitrauma patients with ARDS as rescue therapy (2007) J Card Surg, 22, pp. 180-184; Huang, Y.K., Liu, K.S., Lu, M.S., Wu, M.Y., Tsai, F.C., Lin, P.J., Extracorporeal life support in post-traumatic respiratory distress patients (2009) Resuscitation, 80, pp. 535-539; Arlt, M., Philipp, A., Voelkel, S., Rupprecht, L., Mueller, T., Hilker, M., Extracorporeal membrane oxygenation in severe trauma patients with bleeding shock (2010) Resuscitation, 81, pp. 804-809; Bellomo, R., Ronco, C., Kellum, J.A., Mehta, R.L., Palevsky, P., Acute renal failure - Definition, outcome measures, animal models, fluid therapy and information technology needs: The Second International Consensus Conference of the Acute Dialysis Quality Initiative (ADQI) Group (2004) Crit Care, 8, pp. R204-R212; Bouman, C., Kellum, J.A., Lamiere, N., Definition for acute renal failure (2003) Acute Dialysis Quality Initiative - 2nd International Consensus Conference, , http://www.adqi.net; Dellinger, R.P., Levy, M.M., Rhodes, A., Annane, D., Gerlach, H., Opal, S.M., Surviving Sepsis Campaign: International Guidelines for Management of Severe Sepsis and Septic Shock: 2012 (2013) Crit Care Med, 41, pp. 580-637; Lewandowski, K., Extracorporeal membrane oxygenation for severe acute respiratory failure (2000) Crit Care, 4, pp. 156-168; Cordell-Smith, J.A., Roberts, N., Peek, G.J., Firmin, R.K., Traumatic lung injury treated by extracorporeal membrane oxygenation (ECMO) (2006) Injury, 37, pp. 29-32; Ried, M., Bein, T., Philipp, A., Müller, T., Graf, B., Schmid, C., Extracorporeal lung support in trauma patients with severe chest injury and acute lung failure: A 10-year institutional experience (2013) Crit Care, 17 (3), p. R110; Biderman, P., Einav, S., Fainblut, M., Stein, M., Singer, P., Medalion, B., Extracorporeal life support in patients with multiple injuries and severe respiratory failure: A single-center experience? (2013) J Trauma Acute Care Surg, 75, pp. 907-912; Michaels, A.J., Schriener, R.J., Kolla, S., Awad, S.S., Rich, P.B., Reickert, C., Extracorporeal life support in pulmonary failure after trauma (1999) J Trauma, 46, pp. 638-645; Wolf, M.J., Chanani, N.K., Heard, M.L., Kanter, K.R., Mahle, W.T., Early renal replacement therapy during pediatric cardiac extracorporeal support increases mortality (2013) Ann Thorac Surg, 96 (3), pp. 917-922; Shi, J., Chen, Q., Yu, W., Shen, J., Gong, J., He, C., Continuous renal replacement therapy reduces the systemic and pulmonary inflammation induced by venovenous extracorporeal membrane oxygenation in a porcine model (2014) Artif Organs, 38 (3), pp. 215-223; Shen, J., Yu, W., Chen, Q., Shi, J., Hu, Y., Zhang, J., Continuous renal replacement therapy (CRRT) attenuates myocardial inflammation and mitochondrial injury induced by venovenous extracorporeal membrane oxygenation (VV ECMO) in a healthy piglet model (2013) Inflammation, 36 (5), pp. 1186-1193; Yuan, K.C., Fang, J.F., Chen, M.F., Treatment of endobronchial hemorrhage after blunt chest trauma with extracorporeal membrane oxygenation (ECMO) (2008) J Trauma, 65 (5), pp. 1151-1154; Liao, C.H., Huang, Y.K., Tseng, C.N., Wu, M.Y., Tsai, F.C., Successful use of extracorporeal life support to resuscitate traumatic inoperable pulmonary hemorrhage (2008) J Trauma, 64 (2), pp. E15-E17; Muellenbach, R.M., Redel, A., Küstermann, J., Brack, A., Gorski, A., Rösner, T., Extracorporeal membrane oxygenation and severe traumatic brain injury. Is the ECMO-therapy in traumatic lung failure and severe traumatic brain injury really contraindicated? (2011) Anaesthesist, 60 (7), pp. 647-652; Muellenbach, R.M., Kredel, M., Kunze, E., Kranke, P., Kuestermann, J., Brack, A., Prolonged heparin-free extracorporeal membrane oxygenation in multiple injured acute respiratory distress syndrome patients with traumatic brain injury (2012) J Trauma Acute Care Surg, 72 (5), pp. 1444-1447
PY - 2015
Y1 - 2015
N2 - Objectives: The use of extracorporeal membrane oxygenation (ECMO) in managing acute respiratory distress syndrome had been accepted. Severe lung injury with respiratory failure is often encountered in trauma patients. We report our experience with the use of ECMO in severe traumatic lung injury. Methods: Patients with severe traumatic lung injury that met the following criteria were candidates for ECMO: (1) severe hypoxemia, Pao2/fraction of inspired oxygen (1.0) less than 60, and positive end-expiratory pressure greater than 10 cm H2O in spite of vigorous ventilation strategy; (2) irreversible CO2 retention with unstable hemodynamics; and (3) an initial arterial Pao2/fraction of inspired oxygen (1.0) less than 60, where the pulmonary condition and hemodynamics rapidly deteriorated despite vigorous mechanical ventilation strategy. Results: Over 60 months, a total of 19 patients with severe traumatic lung injury who received ECMO management were retrospectively reviewed. The median age was 38 years (25-58 years), the median injury severity score was 29(25-34), the median admission Acute Physiology and Chronic Health Evaluation II (APACHE II) score was 25(21-36), and the median blood transfusion volume was 5500 mL (3500-13 000). There were 9 venovenous and 10 venoarterial types. The survival rate was 68.4% (13/19). The survivors were younger (30 vs 53 years; 21-39 vs 48-63). There were 6 mortalities (3 pneumonia, 2 coagulopathy, and 1 cardiac rupture with cardiac tamponade). There were 5 of 19 patients with pre-ECMO traumatic brain hemorrhage (3 survived and 2 mortalities). A total of 16 patients received heparinization with 5 mortalities. Conclusions: The use of ECMO may offer an additional treatment modality in severe traumatic lung injury with respiratory failure that is unresponsive to optimal conventional ventilator support. Timely ECMO intervention is of value. © 2015 Elsevier Inc.
AB - Objectives: The use of extracorporeal membrane oxygenation (ECMO) in managing acute respiratory distress syndrome had been accepted. Severe lung injury with respiratory failure is often encountered in trauma patients. We report our experience with the use of ECMO in severe traumatic lung injury. Methods: Patients with severe traumatic lung injury that met the following criteria were candidates for ECMO: (1) severe hypoxemia, Pao2/fraction of inspired oxygen (1.0) less than 60, and positive end-expiratory pressure greater than 10 cm H2O in spite of vigorous ventilation strategy; (2) irreversible CO2 retention with unstable hemodynamics; and (3) an initial arterial Pao2/fraction of inspired oxygen (1.0) less than 60, where the pulmonary condition and hemodynamics rapidly deteriorated despite vigorous mechanical ventilation strategy. Results: Over 60 months, a total of 19 patients with severe traumatic lung injury who received ECMO management were retrospectively reviewed. The median age was 38 years (25-58 years), the median injury severity score was 29(25-34), the median admission Acute Physiology and Chronic Health Evaluation II (APACHE II) score was 25(21-36), and the median blood transfusion volume was 5500 mL (3500-13 000). There were 9 venovenous and 10 venoarterial types. The survival rate was 68.4% (13/19). The survivors were younger (30 vs 53 years; 21-39 vs 48-63). There were 6 mortalities (3 pneumonia, 2 coagulopathy, and 1 cardiac rupture with cardiac tamponade). There were 5 of 19 patients with pre-ECMO traumatic brain hemorrhage (3 survived and 2 mortalities). A total of 16 patients received heparinization with 5 mortalities. Conclusions: The use of ECMO may offer an additional treatment modality in severe traumatic lung injury with respiratory failure that is unresponsive to optimal conventional ventilator support. Timely ECMO intervention is of value. © 2015 Elsevier Inc.
KW - oxygen
KW - adult
KW - APACHE
KW - arterial gas
KW - Article
KW - artificial ventilation
KW - blood clotting disorder
KW - blunt trauma
KW - brain hemorrhage
KW - clinical article
KW - extracorporeal oxygenation
KW - female
KW - heart rupture
KW - heart tamponade
KW - heparinization
KW - human
KW - hypercapnia
KW - hypoxemia
KW - injury scale
KW - injury severity
KW - intensive care unit
KW - lung hemodynamics
KW - lung injury
KW - male
KW - oxygen consumption
KW - positive end expiratory pressure
KW - priority journal
KW - respiratory failure
KW - retrospective study
KW - severe traumatic lung injury
KW - survival rate
KW - traffic accident
KW - blood transfusion
KW - cause of death
KW - hemodynamics
KW - length of stay
KW - lung function test
KW - middle aged
KW - mortality
KW - Respiratory Distress Syndrome, Adult
KW - statistics and numerical data
KW - Adult
KW - Blood Transfusion
KW - Cause of Death
KW - Extracorporeal Membrane Oxygenation
KW - Female
KW - Hemodynamics
KW - Humans
KW - Length of Stay
KW - Lung Injury
KW - Male
KW - Middle Aged
KW - Positive-Pressure Respiration
KW - Respiratory Function Tests
KW - Retrospective Studies
KW - Survival Rate
KW - Trauma Severity Indices
U2 - 10.1016/j.ajem.2015.02.007
DO - 10.1016/j.ajem.2015.02.007
M3 - Article
SN - 0735-6757
VL - 33
SP - 658
EP - 662
JO - American Journal of Emergency Medicine
JF - American Journal of Emergency Medicine
IS - 5
ER -