I Frerichs1, G Hahn, T Schröder, G Hellige. 1. Department of Anaesthesiological Research, Centre of Anaesthesiology, Emergency and Intensive Care Medicine, University of Göttingen, Germany.
Abstract
OBJECTIVE: To apply electrical impedance tomography (EIT) and the new evaluation approach (the functional EIT) in monitoring the development of artificial lung injury. DESIGN: Acute experimental trial. SETTING: Operating room for animal experimental studies at a university hospital. SUBJECTS: Five pigs (41.3 +/- 4.1 kg, mean body weight +/- SD). INTERVENTIONS: The animals were anaesthetised and mechanically ventilated. Sixteen electrodes were attached on the thoracic circumference and used for electrical current injection and surface voltage measurement. Oleic acid was applied sequentially (total dose 0.05 ml/kg body weight) into the left pulmonary artery to produce selective unilateral lung injury. MEASUREMENTS AND RESULTS: The presence of lung injury was documented by significant changes of PaCO2 (40.1 mmHg vs control 37.1 mmHg), PaO2 (112.3 mmHg vs 187.5 mmHg), pH (7.35 vs 7.42), mean pulmonary arterial pressure (29.2 mmHg vs 20.8 mmHg) and chest radiography. EIT detected 1) a regional decrease in mean impedance variation over the affected left lung (-41.4% vs control) and an increase over the intact right lung (+ 20.4% vs control) indicating reduced ventilation of the affected, and a compensatory augmented ventilation of the unaffected lung and 2) a pronounced fall in local baseline electrical impedance over the injured lung (-20.6% vs control) with a moderate fall over the intact lung (-10.0% vs control) indicating the development of lung oedema in the injured lung with a probable atelectasis formation in the contralateral one. CONCLUSION: The development of the local impairment of pulmonary ventilation and the formation of lung oedema could be followed by EIT in an experimental model of lung injury. This technique may become a useful tool for monitoring local pulmonary ventilation in intensive care patients suffering from pulmonary disorders associated with regionally reduced ventilation, fluid accumulation and/or cell membrane changes.
OBJECTIVE: To apply electrical impedance tomography (EIT) and the new evaluation approach (the functional EIT) in monitoring the development of artificial lung injury. DESIGN: Acute experimental trial. SETTING: Operating room for animal experimental studies at a university hospital. SUBJECTS: Five pigs (41.3 +/- 4.1 kg, mean body weight +/- SD). INTERVENTIONS: The animals were anaesthetised and mechanically ventilated. Sixteen electrodes were attached on the thoracic circumference and used for electrical current injection and surface voltage measurement. Oleic acid was applied sequentially (total dose 0.05 ml/kg body weight) into the left pulmonary artery to produce selective unilateral lung injury. MEASUREMENTS AND RESULTS: The presence of lung injury was documented by significant changes of PaCO2 (40.1 mmHg vs control 37.1 mmHg), PaO2 (112.3 mmHg vs 187.5 mmHg), pH (7.35 vs 7.42), mean pulmonary arterial pressure (29.2 mmHg vs 20.8 mmHg) and chest radiography. EIT detected 1) a regional decrease in mean impedance variation over the affected left lung (-41.4% vs control) and an increase over the intact right lung (+ 20.4% vs control) indicating reduced ventilation of the affected, and a compensatory augmented ventilation of the unaffected lung and 2) a pronounced fall in local baseline electrical impedance over the injured lung (-20.6% vs control) with a moderate fall over the intact lung (-10.0% vs control) indicating the development of lung oedema in the injured lung with a probable atelectasis formation in the contralateral one. CONCLUSION: The development of the local impairment of pulmonary ventilation and the formation of lung oedema could be followed by EIT in an experimental model of lung injury. This technique may become a useful tool for monitoring local pulmonary ventilation in intensive care patients suffering from pulmonary disorders associated with regionally reduced ventilation, fluid accumulation and/or cell membrane changes.
Authors: Barbara Cambiaghi; Francesco Vasques; Onnen Mörer; Christian Ritter; Tommaso Mauri; Nils Kunze-Szikszay; Karin Holke; Francesca Collino; Giorgia Maiolo; Francesca Rapetti; Elias Schulze-Kalthoff; Tommaso Tonetti; Günter Hahn; Michael Quintel; Luciano Gattinoni Journal: Intensive Care Med Exp Date: 2017-10-13
Authors: Constantin J C Trepte; Charles R Phillips; Josep Solà; Andy Adler; Sebastian A Haas; Michael Rapin; Stephan H Böhm; Daniel A Reuter Journal: Crit Care Date: 2016-01-22 Impact factor: 9.097