Your search keyword '"Markstaller K"' showing total 108 results

1. Detection and differentiation of cerebral microemboli in patients undergoing major orthopaedic surgery using transcranial Doppler ultrasound

Author

Kietaibl, C, Engel, A, Horvat Menih, I, Huepfl, M, Erdoes, G, Kubista, B, Ullrich, R, Windhager, R, Markstaller, K, and Klein, K.U.

Published

2017

2. Ropivacaine Activates Multiple Proapoptotic and Inflammatory Signaling Pathways That Might Subsume to Trigger Epidural-related Maternal Fever

Author

Wohlrab, P., Boehme, S., Kaun, C., Wojta, J., Spittler, A., Saleh, L., Knöfler, M., Markstaller, K., Klein, K.U., and Tretter, V.

Published

2020

3. Konfliktmatrix: Instrument des Risikomanagements im Operationssaal

Author

Andel, D., Markstaller, K., and Andel, H.

Published

2017

4. Incidence of hyperoxia and related in‐hospital mortality in critically ill patients: a retrospective data analysis

Author

Kraft, F., Andel, H., Gamper, J., Markstaller, K., Ullrich, R., and Klein, K. U.

Published

2018

5. Art und Umfang der Anästhesierisikoaufklärung: Auswertung einer Befragung aller Gerichtssachverständigen in Österreich

Author

Andel, D., Röder, G., Markstaller, K., and Andel, H.

Published

2015

6. Rapid-sequence-Narkoseeinleitung und Intubation – das Timing-Prinzip

Author

Andel, H. and Markstaller, K.

Published

2019

7. Cyclic and constant hyperoxia cause inflammation, apoptosis and cell death in human umbilical vein endothelial cells

Author

Wu, J., Hafner, C., Schramel, J. P., Kaun, C., Krychtiuk, K. A., Wojta, J., Boehme, S., Ullrich, R., Tretter, E. V., Markstaller, K., and Klein, K. U.

Published

2016

8. In unserem Fach und über unser Fach hinaus

Author

Schuster, M., Markstaller, K., and Bauer, M.

Published

2017

9. Effect of Intraoperative High Positive End-Expiratory Pressure (PEEP) with Recruitment Maneuvers vs Low PEEP on Postoperative Pulmonary Complications in Obese Patients: A Randomized Clinical Trial

Author

Bluth, T, Neto, As, Schultz, Mj, Pelosi, P, de Abreu MG, Bobek, I, Canet, Jc, de Baerdemaeker, L, Gregoretti, C, Hedenstierna, G, Hemmes, Snt, Hiesmayr, M, Hollmann, M, Jaber, S, Laffey, J, Licker, Mj, Markstaller, K, Matot, I, Mills, G, Mulier, Jp, Putensen, C, Rossaint, R, Schmitt, J, Senturk, M, Severgnini, P, Sprung, J, Melo, Mfv, Wrigge, H, Abelha, F, Abitagaoglu, S, Achilles, M, Adebesin, A, Adriaensens, I, Ahene, C, Akbar, F, Al Harbi, M, al Kallab RA, Albanel, X, Aldenkortt, F, Alfouzan, Ras, Alruqaie, R, Altermatt, F, Araujo, Bld, Arbesu, G, Artsi, H, Aurilio, C, Ayanoglu, Oh, Bacuzzi, A, Baig, H, Baird, Y, Balonov, K, Balust, J, Banks, S, Bao, Xd, Baumgartner, M, Tortosa, Ib, Bergamaschi, A, Bergmann, L, Bigatello, L, Perez, Eb, Birr, K, Bojaxhi, E, Bonenti, C, Bonney, I, Bos, Ee, Bowman, S, Braz, Lg, Brugnoni, E, Brunetti, I, Bruni, A, Buenvenida, Sl, Camerini, Cj, Canet, J, Capatti, B, Carmona, J, Carungcong, J, Carvalho, M, Cattan, A, Cavaleiro, C, Chiumello, D, Ciardo, S, Coburn, M, Colella, U, Contreras, V, Dincer, Pc, Cotter, E, Crovetto, M, Crovetto, W, Darrah, W, Davies, S, De Hert, S, Peces, Ed, Delphin, E, Diaper, J, do Nascimento, P, Donatiello, V, Dong, J, Dourado, Md, Dullenkopf, A, Ebner, F, Elgendy, H, Ellenberger, C, Ari, De, Ermert, T, Farah, F, Fernandez-Bustamante, A, Ferreira, C, Fiore, M, Fonte, A, Palahi, Cf, Galimberti, A, Garofano, N, Giaccari, Lg, Gilsanz, F, Girrbach, F, Gobbi, L, Godfried, Mb, Goettel, N, Goldstein, Pa, Goren, O, Gorlin, A, Gil, Mg, Gratarola, A, Graterol, J, Guyon, P, Haire, K, Harou, P, Helf, A, Hempel, G, Cadiz, Mjh, Heyse, B, Hollmann, Mw, Huercio, I, Ilievska, J, Jakus, L, Jeganath, V, Jelting, Y, Jung, M, Kabon, B, Kacha, A, Ilic, Mk, Karuppiah, A, Kavas, Ad, Barcelos, Gk, Kellogg, Ta, Kemper, J, Kerbrat, R, Khodr, S, Kienbaum, P, Kir, B, Kiss, T, Kivrak, S, Klaric, V, Koch, T, Koksal, C, Kowark, A, Kranke, P, Kuvaki, B, Kuzmanovska, B, Lange, M, de Lemos MF, Lopez-Baamonde, M, Lopez-Hernandez, A, Lopez-Martinez, M, Luise, S, Macgregor, M, Magalhaes, D, Maillard, J, Malerbi, P, Manimekalai, N, Margarson, M, Martin, Dp, Martin, Yn, Martinez-Ocon, J, Martin-Loeches, I, Maseda, E, Mcauliffe, N, Mckenzie, Tj, Medina, P, Meersch, M, Menzen, A, Mertens, E, Meurer, B, Meyer-Treschan, T, Miao, Ch, Micalizzi, C, Milic, M, Modolo, Nsp, Moine, P, Molders, P, Montero-Feijoo, A, Moret, E, Muller, Mk, Murphy, Z, Nalwaya, P, Naumovski, F, Navalesi, P, Lima, Lhne, Adam, Vn, Neumann, C, Newell, C, Nisnevitch, Z, Nizamuddin, J, Novazzi, C, O'Connor, M, Oprea, G, Sungur, Mo, Ozbilgin, S, Pace, Mc, Pacheco, M, Packianathaswamy, B, Gonzalez, Ep, Papaspyros, F, Paredes, S, Passavanti, Mb, Pedemonte, Jc, Peremin, S, Philipsenburg, C, Pinho, D, Pinho, S, Posthuma, Lm, Pota, V, Preckel, B, Priani, P, Rached, Ma, Radoeshki, A, Ragazzi, R, Rajamanickam, T, Rajamohan, A, Ramakrishna, H, Rangarajan, D, Reiterer, C, Renew, Jr, Reynaud, T, Rhys, R, Rivas, E, Robitzky, L, Rubulotta, F, Machado, Hs, Nunes, Cs, Sabbatini, G, Sanahuja, Jm, Sansone, P, Santos, A, Sayedalahl, M, Schaefer, Ms, Scharffenberg, E, Scharffenberg, M, Schiffer, E, Schliewe, N, Schorer, R, Schumann, R, Selmo, G, Sendra, M, Shaw, K, Shosholcheva, M, Sibai, A, Simon, P, Simonassi, F, Sinno, C, Sivrikoz, N, Skandalou, V, Smith, N, Soares, M, Artiles, Ts, Castro, Ds, Sousa, M, Spadaro, S, Stamatakis, E, Steiner, La, Stevenazzi, A, Suarez-de-la-Rica, A, Suppan, M, Teichmann, R, Guerrero, Jmt, Thiel, B, Tolos, R, Altun, Gt, Tucci, M, Turnbull, Za, Turudic, Z, Unterberg, M, Van Limmen, J, Van Nieuwenhove, Y, Van Waesberghe, J, Francisco, M, Melo, V, Vitkovic, B, Vivona, L, Vizcaychipi, M, Volta, Ca, Weber, A, Weingarten, Tn, Wittenstein, J, Wyffels, P, Yague, J, Yates, D, Yavru, A, Zac, L, Zhong, J, Intensive Care Medicine, ACS - Heart failure & arrhythmias, Anesthesiology, ACS - Diabetes & metabolism, APH - Quality of Care, ACS - Pulmonary hypertension & thrombosis, ACS - Microcirculation, Bluth T., Serpa Neto A., Schultz M.J., Pelosi P., Gama de Abreu M., Bobek I., Canet J.C., Cinella G., de Baerdemaeker L., Gregoretti C., Hedenstierna G., Hemmes S.N.T., Hiesmayr M., Hollmann M.W., Jaber S., Laffey J., Licker M.-J., Markstaller K., Matot I., Mills G.H., Mulier J.P., Putensen C., Rossaint R., Schmitt J., Senturk M., Severgnini P., Sprung J., Vidal Melo M.F., Wrigge H., Abelha F., Abitagaoglu S., Achilles M., Adebesin A., Adriaensens I., Ahene C., Akbar F., Harbi M.A., Al Kallab R.A.K., Albanel X., Aldenkortt F., Alfouzan R.A.S., Alruqaie R., Altermatt F., de Castro Araujo B.L., Arbesu G., Artsi H., Aurilio C., Ayanoglu O.H., Bacuzzi A., Baig H., Baird Y., Balonov K., Balust J., Banks S., Bao X., Baumgartner M., Tortosa I.B., Bergamaschi A., Bergmann L., Bigatello L., Perez E.B., Birr K., Bojaxhi E., Bonenti C., Bonney I., Bos E.M.E., Bowman S., Braz L.G., Brugnoni E., Brull S.J., Brunetti I., Bruni A., Buenvenida S.L., Busch C.J., Camerini G., Capatti B., Carmona J., Carungcong J., Carvalho M., Cattan A., Cavaleiro C., Chiumello D., Ciardo S., Coburn M., Colella U., Contreras V., Dincer P.C., Cotter E., Crovetto M., Darrah W., Davies S., De Hert S., Peces E.D.C., Delphin E., Diaper J., Do Nascimento Junior P., Donatiello V., Dong J., Dourado M.D.S., Dullenkopf A., Ebner F., Elgendy H., Ellenberger C., Erdogan Ari D., Ermert T., Farah F., Fernandez-Bustamante A., Ferreira C., Fiore M., Fonte A., Palahi C.F., Galimberti A., Garofano N., Giaccari L.G., Gilsanz F., Girrbach F., Gobbi L., Godfried M.B., Goettel N., Goldstein P.A., Goren O., Gorlin A., Gil M.G., Gratarola A., Graterol J., Guyon P., Haire K., Harou P., Helf A., Hempel G., Cadiz M.J.H., Heyse B., Huercio I., Ilievska J., Jakus L., Jeganath V., Jelting Y., Jung M., Kabon B., Kacha A., Ilic M.K., Karuppiah A., Kavas A.D., Barcelos G.K., Kellogg T.A., Kemper J., Kerbrat R., Khodr S., Kienbaum P., Kir B., Kiss T., Kivrak S., Klaric V., Koch T., Koksal C., Kowark A., Kranke P., Kuvaki B., Kuzmanovska B., Lange M., de Lemos M.F., Lopez-Baamonde M., Lopez-Hernandez A., Lopez-Martinez M., Luise S., Macgregor M., Magalhaes D., Maillard J., Malerbi P., Manimekalai N., Margarson M., Martin A.K., Martin D.P., Martin Y.N., Martinez-Ocon J., Martin-Loeches I., Maseda E., McAuliffe N., McKenzie T.J., Medina P., Meersch M., Menzen A., Mertens E., Meurer B., Meyer-Treschan T., Miao C., Micalizzi C., Milic M., Modolo N.S.P., Moine P., Molders P., Montero-Feijoo A., Moret E., Muller M.K., Murphy Z., Nalwaya P., Naumovski F., Navalesi P., Navarro E Lima L.H., Adam V.N., Neumann C., Newell C., Nisnevitch Z., Nizamuddin J., Novazzi C., O'connor M., Oprea G., Sungur M.O., Ozbilgin S., Pace M.C., Pacheco M., Packianathaswamy B., Gonzalez E.P., Papaspyros F., Paredes S., Passavanti M.B., Pedemonte J.C., Peremin S., Philipsenburg C., Pinho D., Pinho S., Posthuma L.M., Pota V., Preckel B., Priani P., Rached M.A., Radoeshki A., Ragazzi R., Rajamanickam T., Rajamohan A., Ramakrishna H., Rangarajan D., Reiterer C., Ross Renew J., Reynaud T., Rhys R., Rivas E., Robitzky L., Rubulotta F., Machado H.S., Nunes C.S., Sabbatini G., Samuels J.D., Sanahuja J.M., Sansone P., Santos A., Sayedalahl M., Schaefer M.S., Scharffenberg M., Schiffer E., Schliewe N., Schorer R., Schumann R., Selmo G., Sendra M., Shaw K., Shosholcheva M., Sibai A., Simon P., Simonassi F., Sinno C., Sivrikoz N., Skandalou V., Smith N., Soares M., Artiles T.S., Castro D.S., Sousa M., Spadaro S., Stamatakis E., Steiner L.A., Stevenazzi A., Suarez-De-la-rica A., Suppan M., Teichmann R., Guerrero J.M.T., Thiel B., Tolos R., Altun G.T., Tucci M., Turnbull Z.A., Turudic Z., Unterberg M., Van Limmen J., Van Nieuwenhove Y., Van Waesberghe J., Vitkovic B., Vivona L., Vizcaychipi M., Volta C.A., Weber A., Weingarten T.N., Wittenstein J., Wyffels P., Yague J., Yates D., Yavru A., Zac L., Zhong J., Bluth, T., Serpa Neto, A., Schultz, M. J., Pelosi, P., Gama De Abreu, M., Aurilio, C., Pace, M. C., Passavanti, M. B., Pota, V., and Sansone, P.

Subjects

Lung Diseases, Male, medicine.medical_treatment, Atelectasis, Lung Disease, 01 natural sciences, Body Mass Index, Hypoxemia, Positive-Pressure Respiration, Postoperative Complications, 0302 clinical medicine, PEEP, postoperative complications, obese patients, Anesthesia, Respiratory function, 030212 general & internal medicine, Tidal volume, General Medicine, Middle Aged, Pleural Diseases, respiratory system, Adult, Anesthesia, General, Female, Humans, Obesity, Pulmonary Atelectasis, Respiratory Insufficiency, Surgical Procedures, Operative, Tidal Volume, Treatment Outcome, Intraoperative Care, Operative, 3. Good health, Pneumothorax, medicine.symptom, psychological phenomena and processes, Human, circulatory and respiratory physiology, NO, 03 medical and health sciences, mental disorders, medicine, Pleural Disease, 0101 mathematics, General, Positive end-expiratory pressure, Mechanical ventilation, Surgical Procedures, Pulmonary Atelectasi, business.industry, 010102 general mathematics, medicine.disease, respiratory tract diseases, Respiratory failure, Postoperative Complication, business

Abstract

Importance: An intraoperative higher level of positive end-expiratory positive pressure (PEEP) with alveolar recruitment maneuvers improves respiratory function in obese patients undergoing surgery, but the effect on clinical outcomes is uncertain. Objective: To determine whether a higher level of PEEP with alveolar recruitment maneuvers decreases postoperative pulmonary complications in obese patients undergoing surgery compared with a lower level of PEEP. Design, Setting, and Participants: Randomized clinical trial of 2013 adults with body mass indices of 35 or greater and substantial risk for postoperative pulmonary complications who were undergoing noncardiac, nonneurological surgery under general anesthesia. The trial was conducted at 77 sites in 23 countries from July 2014-February 2018; final follow-up: May 2018. Interventions: Patients were randomized to the high level of PEEP group (n = 989), consisting of a PEEP level of 12 cm H2O with alveolar recruitment maneuvers (a stepwise increase of tidal volume and eventually PEEP) or to the low level of PEEP group (n = 987), consisting of a PEEP level of 4 cm H2O. All patients received volume-controlled ventilation with a tidal volume of 7 mL/kg of predicted body weight. Main Outcomes and Measures: The primary outcome was a composite of pulmonary complications within the first 5 postoperative days, including respiratory failure, acute respiratory distress syndrome, bronchospasm, new pulmonary infiltrates, pulmonary infection, aspiration pneumonitis, pleural effusion, atelectasis, cardiopulmonary edema, and pneumothorax. Among the 9 prespecified secondary outcomes, 3 were intraoperative complications, including hypoxemia (oxygen desaturation with Spo2 ≤92% for >1 minute). Results: Among 2013 adults who were randomized, 1976 (98.2%) completed the trial (mean age, 48.8 years; 1381 [69.9%] women; 1778 [90.1%] underwent abdominal operations). In the intention-to-treat analysis, the primary outcome occurred in 211 of 989 patients (21.3%) in the high level of PEEP group compared with 233 of 987 patients (23.6%) in the low level of PEEP group (difference, -2.3% [95% CI, -5.9% to 1.4%]; risk ratio, 0.93 [95% CI, 0.83 to 1.04]; P =.23). Among the 9 prespecified secondary outcomes, 6 were not significantly different between the high and low level of PEEP groups, and 3 were significantly different, including fewer patients with hypoxemia (5.0% in the high level of PEEP group vs 13.6% in the low level of PEEP group; difference, -8.6% [95% CI, -11.1% to 6.1%]; P

Published

2019

10. „Awareness“ während Allgemeinanästhesie: Unterschätzte Komplikation?

Author

Markstaller, K.

Published

2015

11. Protective intraoperative ventilation with higher versus lower levels of positive end-expiratory pressure in obese patients (PROBESE): study protocol for a randomized controlled trial

Author

Bluth, T., Teichmann, R., Hiesmayr, M., Socorro, Tania, Izquierdo, Ana, Soro, Marina, Granell Gil, Manuel, Hernández Cádiz, María José, Biosca Pérez, Elena, Suarez-de-la-Rica, Alejandro, Lopez-Martinez, Mercedes, Huercio, Iván, Maseda, Emilio, Hollmann, M. W., Yagüe, Julio, Cebrian Moreno, Alba, Rivas, Eva, Lopez-Baamonde, Manuel, Elgendy, Hamed, Sayedalahl, Mohamed, SIibai, Abdul Razak, Yavru, Aysen, Sivrikoz, Nukhet, Karadeniz, Meltem, Jaber, S., Corman Dincer, Pelin, Ayanoglu, Hilmi Omer, Tore Altun, Gulbin, Kavas, Ayse Duygu, Dinc, Bora, Kuvaki, Bahar, Ozbilgin, Sule, Erdogan, Dilek, Koksal, Ceren, Abitagaglu, Suheyla, Laffey, J. G., Aurilio, Caterina, Sansone, Pasquale, Pace, Caterina Maria, Donatiello, Valerio, Mattera, Silvana, Nazareno, Palange, Di Colandrea, Salvatore, Spadaro, Savino, Volta, Carlo Alberto, Ragazzi, Riccardo, Licker, M. J., Ciardo, Stefano, Gobbi, Luca, Severgnini, Paolo, Bacuzzi, Alessandro, Brugnoni, Elisa, Gratarola, Angelo, Micalizzi, Camilla, Simonassi, Francesca, Malerbi, Patrizia, Carboni, Adrea, Markstaller, K., Licker, Marc-Joseph, Dullenkopf, Alexander, Goettel, Nicolai, Nesek Adam, Visnja, Karaman Ilic, Maja, Klaric, Vlasta, Vitkovic, Bibiana, Milic, Morena, Zupcic, Miro, De Baerdemaeker, Luc, Matot, I., De Hert, Stefan, Heyse, Bjorn, Van Limmen, Jurgen, Van Nieuwenhove, Yves, Mertens, Els, Neyrinck, Arne, Mulier, Jan, Kahn, David, Godoroja, Daniela, Martin-Loeches, Martin, Müller, G., Vorotyntsev, Sergiy, Fronchko, Valentyna, Matot, Idit, Goren, Or, Zac, Lilach, Gaszynski, Thomasz, Laffey, Jon, Mills, Gary, Nalwaya, Pramod, Mac Gregor, Mark, Mills, G. H., Paddle, Jonathan, Balaji, Packianathaswamy, Rubulotta, Francesca, Adebesin, Afeez, Margarson, Mike, Davies, Simon, Rangarajan, Desikan, Newell, Christopher, Shosholcheva, Mirjana, Papaspyros, Fotios, Mulier, J. P., Skandalou, Vasiliki, Dzurnakov, Paula, Kiss, T., Putensen, C., Rossaint, Rolf, Schmitt, J., Senturk, M., Serpa Neto, A., Severgnini, P., Sprung, J., Vidal Melo, M. F., Wrigge, H., Schultz, M. J., Bobek, I., Pelosi, P., Gama de Abreu, M., PROBESE investigators, PROtective VEntilation Network (PROVEnet), Clinical Trial Network of the European Society of Anaesthesiology (ESA), Güldner, Andreas, Huhle, Robert, Uhlig, Christopher, Vivona, Luigi, Bergamaschi, Alice, Canet, J., Stevanovic, Ana, Treschan, Tanja, Schaefer, Maximilian, Kienbaum, Peter, Laufenberg-Feldmann, Rita, Bergmann, Lars, Ebner, Felix, Robitzky, Luisa, Mölders, Patrick, Cinnella, G., Unterberg, Matthias, Busch, Cornelius, Achilles, Marc, Menzen, Angelika, Freesemann, Harbert, Putensen, Christian, Machado, Humberto, Cavaleiro, Carla, Ferreira, Cristina, Pinho, Daniela, De Baerdemaeker, L., Carvalho, Marta, Pinho, Sílvia, Soares, Maria, Castro, Diogo Sousa, Abelha, Fernando, Rabico, Rui, Delphin, Ellise, Sprung, Juraj, Weingarten, Toby N., Kellogg, Todd A., Gregoretti, C., Martin, Yvette N., McKenzie, Travis J., Brull, Sorin J., Renew, J. Ross, Ramakrishna, Harish, Fernandez-Bustamante, Ana, Balonov, Konstantin, Baig, Harris R., Kacha, Aalok, Pedemonte, Juan C., Hedenstierna, G., Altermatt, Fernando, Corvetto, Marcia A., Paredes, Sebastian, Carmona, Javiera, Rolle, Augusto, Bos, Elke, Beurskens, Charlotte, Veering, B., Zonneveldt, Harry, Boer, Christa, Hemmes, S. N., Godfried, Marc, Thiel, Bram, Kabon, Barbara, Reiterer, Christian, Canet, Jaume, Tolós, Raquel, Sendra, Mar, González, Miriam, Gómez, Noemí, Ferrando, Carlos, Centre Hospitalier Régional Universitaire [Montpellier] (CHRU Montpellier), Bluth T., Teichmann R., Kiss T., Bobek I., Canet J., Cinnella G., De Baerdemaeker L., Gregoretti C., Hedenstierna G., Hemmes S.N., Hiesmayr M., Hollmann M.W., Jaber S., Laffey J.G., Licker M.J., Markstaller K., Matot I., Muller G., Mills G.H., Mulier J.P., Putensen C., Rossaint R., Schmitt J., Senturk M., Serpa Neto A., Severgnini P., Sprung J., Vidal Melo M.F., Wrigge H., Schultz M.J., Pelosi P., Gama de Abreu M., Guldner A., Huhle R., Uhlig C., Vivona L., Bergamaschi A., Stevanovic A., Treschan T., Schaefer M., Kienbaum P., Laufenberg-Feldmann R., Bergmann L., Ebner F., Robitzky L., Molders P., Unterberg M., Busch C., Achilles M., Menzen A., Freesemann H., Machado H., Cavaleiro C., Ferreira C.P., Pinho D., Carvalho M., Pinho S., Soares M., Castro D.S., Abelha F., Rabico R., Delphin E., Weingarten T.N., Kellogg T.A., Martin Y.N., McKenzie T.J., Brull S.J., Renew J.R., Ramakrishna H., Fernandez-Bustamante A., Balonov K., Baig H.R., Kacha A., Pedemonte J.C., Altermatt F., Corvetto M.A., Paredes S., Carmona J., Rolle A., Bos E., Beurskens C., Veering B., Zonneveldt H., Boer C., Godfried M., Thiel B., Kabon B., Reiterer C., Tolos R., Sendra M., Gonzalez M., Gomez N., Ferrando C., Socorro T., Izquierdo A., Soro M., Granell Gil M., Hernandez Cadiz M.J., Biosca Perez E., Suarez-de-la-Rica A., Lopez-Martinez M., Huercio I., Maseda E., Yague J., Cebrian Moreno A., Rivas E., Lopez-Baamonde M., Elgendy H., Sibai A.R., Yavru A., Sivrikoz N., Karadeniz M., Corman Dincer P., Ayanoglu H., Tore Altun G., Kavas A.D., Dinc B., Kuvaki B., Ozbilgin S., Erdogan D., Koksal C., Abitagaglu S., Aurilio C., Sansone P., Pace C.M., Donatiello V., Mattera S., Palange N., Di Colandrea S., Spadaro S., Volta C.A., Ragazzi R., Ciardo S., Gobbi L., Bacuzzi A., Brugnoni E., Gratarola A., Micalizzi C., Simonassi F., Malerbi P., Carboni A., Dullenkopf A., Goettel N., Nesek Adam V., Karaman Ilic M., Klaric V., Vitkovic B., Milic M., Miro Z., De Hert S., Heyse B., Van Limmen J., Van Nieuwenhove Y., Mertens E., Kahn D., Godoroja D., Martin-Loeches M., Vorotyntsev S., Fronchko V., Goren O., Zac L., Gaszynski T., Nalwaya P., Mac Gregor M., Paddle J., Balaji P., Rubulotta F., Adebesin A., Margarson M., Davies S., Rangarajan D., Newell C., Shosholcheva M., Papaspyros F., Skandalou V., Dzurnakova P., Anesthesiology, ACS - Heart failure & arrhythmias, AII - Inflammatory diseases, Intensive Care Medicine, ACS - Diabetes & metabolism, ACS - Pulmonary hypertension & thrombosis, ACS - Microcirculation, UCL - (SLuc) Département de médecine aiguë, UCL - (SLuc) Service d'anesthésiologie, Bluth, T, Teichmann, R, Kiss, T, Bobek, I, Canet, J, Cinnella, G, De Baerdemaeker, L, Gregoretti, C, Hedenstierna, G, Hemmes, S N, Hiesmayr, M, Hollmann, M W, Jaber, S, Laffey, J G, Licker, M J, Markstaller, K, Matot, I, Müller, G, Mills, G H, Mulier, J P, Putensen, C, Rossaint, R, Schmitt, J, Senturk, M, Serpa Neto, A, Severgnini, P, Sprung, J, Vidal Melo, M F, Wrigge, H, Schultz, M J, Pelosi, P, Gama de Abreu, M, Güldner, A, Huhle, R, Uhlig, C, Vivona, L, Bergamaschi, A, Stevanovic, A, Treschan, T, Schaefer, M, Kienbaum, P, Laufenberg-Feldmann, R, Bergmann, L, Ebner, F, Robitzky, L, Mölders, P, Unterberg, M, Busch, C, Achilles, M, Menzen, A, Freesemann, H, Machado, H, Cavaleiro, C, Ferreira, C, Pinho, D, Carvalho, M, Pinho, S, Soares, M, Castro, D, Abelha, F, Rabico, R, Delphin, E, Weingarten, Tn, Kellogg, Ta, Martin, Yn, Mckenzie, Tj, Brull, Sj, Renew, Jr, Ramakrishna, H, Fernandez-Bustamante, A, Balonov, K, Baig, Hr, Kacha, A, Pedemonte, Jc, Altermatt, F, Corvetto, Ma, Paredes, S, Carmona, J, Rolle, A, Bos, E, Beurskens, C, Veering, B, Zonneveldt, H, Boer, C, Godfried, M, Thiel, B, Kabon, B, Reiterer, C, Tolós, R, Sendra, M, González, M, Gómez, N, Ferrando, C, Socorro, T, Izquierdo, A, Soro, M, Granell Gil, M, Hernández Cádiz, Mj, Biosca Pérez, E, Suarez-de-la-Rica, A, Lopez-Martinez, M, Huercio, I, Maseda, E, Yagüe, J, Cebrian Moreno, A, Rivas, E, Lopez-Baamonde, M, Elgendy, H, Sayedalahl, M, Siibai, Ar, Yavru, A, Sivrikoz, N, Karadeniz, M, Corman Dincer, P, Ayanoglu, Ho, Tore Altun, G, Kavas, Ad, Dinc, B, Kuvaki, B, Ozbilgin, S, Erdogan, D, Koksal, C, Abitagaglu, S, Aurilio, C, Sansone, P, Pace, Mc, Donatiello, V, Mattera, S, Nazareno, P, Di Colandrea, S, Spadaro, Antonino, Volta, Ca, Ragazzi, R, Ciardo, S, Gobbi, L, Bacuzzi, A, Brugnoni, E, Gratarola, A, Micalizzi, C, Simonassi, F, Malerbi, P, Carboni, A, Licker, Mj, Dullenkopf, A, Goettel, N, Nesek Adam, V, Karaman Ilić, M, Klaric, V, Vitkovic, B, Milic, M, Zupcic, M, De Hert, S, Heyse, B, Van Limmen, J, Van Nieuwenhove, Y, Mertens, E, Neyrinck, A, Mulier, J, Kahn, D, Godoroja, D, Martin-Loeches, M, Vorotyntsev, S, Fronchko, V, Goren, O, Zac, L, Gaszynski, T, Laffey, J, Mills, G, Nalwaya, P, Mac Gregor, M, Paddle, J, Balaji, P, Rubulotta, F, Adebesin, A, Margarson, M, Davies, S, Rangarajan, D, Newell, C, Shosholcheva, M, Papaspyros, F, Skandalou, V, and Dzurňáková, P.

Subjects

Male, Lung Diseases, Time Factors, [SDV]Life Sciences [q-bio], Respiratory Medicine and Allergy, medicine.medical_treatment, RESPIRATORY-DISTRESS-SYNDROME, Medicine (miscellaneous), Hemodynamics, Mechanical ventilation, Obesity, Positive end-expiratory pressure, Postoperative pulmonary complication, Recruitment maneuver, Pharmacology (medical), LAPAROSCOPIC BARIATRIC SURGERY, Lung Disease, Body Mass Index, law.invention, Positive-Pressure Respiration, Study Protocol, 0302 clinical medicine, Clinical Protocols, Randomized controlled trial, Risk Factors, 030202 anesthesiology, law, Medicine and Health Sciences, Clinical endpoint, Anesthesia, Respiratory function, 030212 general & internal medicine, Lung, Lungmedicin och allergi, 2. Zero hunger, lcsh:R5-920, ddc:617, respiratory system, Operative, 3. Good health, Treatment Outcome, TIDAL VOLUMES, Research Design, Mechanical ventilation, Positive end-expiratory pressure, Recruitment maneuver, Obesity, Postoperative pulmonary complication, Surgical Procedures, Operative, Breathing, Female, Erratum, lcsh:Medicine (General), ALVEOLAR RECRUITMENT MANEUVER, Human, circulatory and respiratory physiology, medicine.medical_specialty, Time Factor, Anesthesia, General, Lung injury, Humans, Intraoperative Care, Protective Factors, NO, GENERAL-ANESTHESIA, DRIVING PRESSURE, 03 medical and health sciences, medicine, ddc:610, Clinical Protocol, General, Protective Factor, POSTOPERATIVE PULMONARY COMPLICATIONS, Surgical Procedures, INTERNATIONAL CONSENSUS, business.industry, Risk Factor, Surgery, respiratory tract diseases, business, LUNG INJURY

Abstract

Background Postoperative pulmonary complications (PPCs) increase the morbidity and mortality of surgery in obese patients. High levels of positive end-expiratory pressure (PEEP) with lung recruitment maneuvers may improve intraoperative respiratory function, but they can also compromise hemodynamics, and the effects on PPCs are uncertain. We hypothesized that intraoperative mechanical ventilation using high PEEP with periodic recruitment maneuvers, as compared with low PEEP without recruitment maneuvers, prevents PPCs in obese patients. Methods/design The PRotective Ventilation with Higher versus Lower PEEP during General Anesthesia for Surgery in OBESE Patients (PROBESE) study is a multicenter, two-arm, international randomized controlled trial. In total, 2013 obese patients with body mass index ≥35 kg/m2 scheduled for at least 2 h of surgery under general anesthesia and at intermediate to high risk for PPCs will be included. Patients are ventilated intraoperatively with a low tidal volume of 7 ml/kg (predicted body weight) and randomly assigned to PEEP of 12 cmH2O with lung recruitment maneuvers (high PEEP) or PEEP of 4 cmH2O without recruitment maneuvers (low PEEP). The occurrence of PPCs will be recorded as collapsed composite of single adverse pulmonary events and represents the primary endpoint. Discussion To our knowledge, the PROBESE trial is the first multicenter, international randomized controlled trial to compare the effects of two different levels of intraoperative PEEP during protective low tidal volume ventilation on PPCs in obese patients. The results of the PROBESE trial will support anesthesiologists in their decision to choose a certain PEEP level during general anesthesia for surgery in obese patients in an attempt to prevent PPCs. Trial registration ClinicalTrials.gov identifier: NCT02148692. Registered on 23 May 2014; last updated 7 June 2016. Electronic supplementary material The online version of this article (doi:10.1186/s13063-017-1929-0) contains supplementary material, which is available to authorized users.

Published

2017

12. Intensivmedizin (B) – Kostenreduktion durch Einsparung von Laboruntersuchungen auf Intensivstation

Author

Palma, SA, additional, Markstaller, K, additional, Ullrich, R, additional, and Klein, KU, additional

Published

2019

13. Erratum: Protective intraoperative ventilation with higher versus lower levels of positive end-expiratory pressure in obese patients (PROBESE): Study protocol for a randomized controlled trial [Trials, 18, (2017)(202)] DOI: 10.1186/s13063-017-1929-0

Author

Bluth, T., Teichmann, R., Kiss, T., Bobek, I., Canet, J., Cinnella, G., De Baerdemaeker, L., Gregoretti, C., Hedenstierna, G., Hemmes, S. N., Hiesmayr, M., Hollmann, M. W., Jaber, S., Laffey, J. G., Licker, M. J., Markstaller, K., Matot, I., Müller, G., Mills, G. H., Mulier, J. P., Putensen, C., Rossaint, R., Schmitt, J., Senturk, M., Neto, A. Serpa, Severgnini, P., Sprung, J., Vidal Melo, M. F., Wrigge, H., Schultz, M. J., Pelosi, P., Gama de Abreu, Marcelo, Bluth T., Teichmann R., Kiss T., Bobek I., Canet J., Cinnella G., De Baerdemaeker L., Gregoretti C., Hedenstierna G., Hemmes S.N., Hiesmayr M., Hollmann M.W., Jaber S., Laffey J.G., Licker M.J., Markstaller K., Matot I., Muller G., Mills G.H., Mulier J.P., Putensen C., Rossaint R., Schmitt J., Senturk M., Neto A.S., Severgnini P., Sprung J., Vidal Melo M.F., Wrigge H., Schultz M.J., Pelosi P., and Gama de Abreu M.

Subjects

Medicine (miscellaneous), Pharmacology (medical), Protective ventilation

Published

2017

14. Effect of Intraoperative High Positive End-Expiratory Pressure (PEEP) With Recruitment Maneuvers vs Low PEEP on Postoperative Pulmonary Complications in Obese Patients : A Randomized Clinical Trial.

Author

Bluth, Thomas, Serpa Neto, Ary, Schultz, Marcus J, Pelosi, Paolo, Gama de Abreu, Marcelo, Bluth, T, Bobek, I, Canet, J C, Cinnella, G, de Baerdemaeker, L, Gama de Abreu, M, Gregoretti, C, Hedenstierna, Göran, Hemmes, S N T, Hiesmayr, M, Hollmann, M W, Jaber, S, Laffey, J, Licker, M J, Markstaller, K, Matot, I, Mills, G H, Mulier, J P, Pelosi, P, Putensen, C, Rossaint, R, Schmitt, J, Schultz, M J, Senturk, M, Serpa Neto, A, Severgnini, P, Sprung, J, Vidal Melo, M F, Wrigge, H, Bluth, Thomas, Serpa Neto, Ary, Schultz, Marcus J, Pelosi, Paolo, Gama de Abreu, Marcelo, Bluth, T, Bobek, I, Canet, J C, Cinnella, G, de Baerdemaeker, L, Gama de Abreu, M, Gregoretti, C, Hedenstierna, Göran, Hemmes, S N T, Hiesmayr, M, Hollmann, M W, Jaber, S, Laffey, J, Licker, M J, Markstaller, K, Matot, I, Mills, G H, Mulier, J P, Pelosi, P, Putensen, C, Rossaint, R, Schmitt, J, Schultz, M J, Senturk, M, Serpa Neto, A, Severgnini, P, Sprung, J, Vidal Melo, M F, and Wrigge, H

Abstract

Importance: An intraoperative higher level of positive end-expiratory positive pressure (PEEP) with alveolar recruitment maneuvers improves respiratory function in obese patients undergoing surgery, but the effect on clinical outcomes is uncertain. Objective: To determine whether a higher level of PEEP with alveolar recruitment maneuvers decreases postoperative pulmonary complications in obese patients undergoing surgery compared with a lower level of PEEP. Design, Setting, and Participants: Randomized clinical trial of 2013 adults with body mass indices of 35 or greater and substantial risk for postoperative pulmonary complications who were undergoing noncardiac, nonneurological surgery under general anesthesia. The trial was conducted at 77 sites in 23 countries from July 2014-February 2018; final follow-up: May 2018. Interventions: Patients were randomized to the high level of PEEP group (n = 989), consisting of a PEEP level of 12 cm H2O with alveolar recruitment maneuvers (a stepwise increase of tidal volume and eventually PEEP) or to the low level of PEEP group (n = 987), consisting of a PEEP level of 4 cm H2O. All patients received volume-controlled ventilation with a tidal volume of 7 mL/kg of predicted body weight. Main Outcomes and Measures: The primary outcome was a composite of pulmonary complications within the first 5 postoperative days, including respiratory failure, acute respiratory distress syndrome, bronchospasm, new pulmonary infiltrates, pulmonary infection, aspiration pneumonitis, pleural effusion, atelectasis, cardiopulmonary edema, and pneumothorax. Among the 9 prespecified secondary outcomes, 3 were intraoperative complications, including hypoxemia (oxygen desaturation with Spo2 ≤92% for >1 minute). Results: Among 2013 adults who were randomized, 1976 (98.2%) completed the trial (mean age, 48.8 years; 1381 [69.9%] women; 1778 [90.1%] underwent abdominal operations). In the intention-to-treat analysis, the primary outcome occurred in 211 of

Published

2019

15. Erratum to Protective intraoperative ventilation with higher versus lower levels of positive end-expiratory pressure in obese patients (PROBESE): study protocol for a randomized controlled trial

Author

Bluth, T., Teichmann, R., Hiesmayr, M., Socorro, Tania, Izquierdo, Ana, Soro, Marina, Granell Gil, Manuel, Hernández Cádiz, María José, Biosca Pérez, Elena, Suarez-de-la-Rica, Alejandro, Lopez-Martinez, Mercedes, Huercio, Iván, Maseda, Emilio, Hollmann, M. W., Yagüe, Julio, Cebrian Moreno, Alba, Rivas, Eva, Lopez-Baamonde, Manuel, Elgendy, Hamed, Sayedalahl, Mohamed, SIibai, Abdul Razak, Yavru, Aysen, Sivrikoz, Nukhet, Karadeniz, Meltem, Jaber, S., Corman Dincer, Pelin, Ayanoglu, Hilmi Omer, Tore Altun, Gulbin, Kavas, Ayse Duygu, Dinc, Bora, Kuvaki, Bahar, Ozbilgin, Sule, Erdogan, Dilek, Koksal, Ceren, Abitagaglu, Suheyla, Laffey, J. G., Aurilio, Caterina, Sansone, Pasquale, Pace, Caterina Maria, Donatiello, Valerio, Mattera, Silvana, Nazareno, Palange, Di Colandrea, Salvatore, Spadaro, Savino, Volta, Carlo Alberto, Ragazzi, Riccardo, Licker, M. J., Ciardo, Stefano, Gobbi, Luca, Severgnini, Paolo, Bacuzzi, Alessandro, Brugnoni, Elisa, Gratarola, Angelo, Micalizzi, Camilla, Simonassi, Francesca, Malerbi, Patrizia, Carboni, Adrea, Markstaller, K., Licker, Marc-Joseph, Dullenkopf, Alexander, Goettel, Nicolai, Nesek Adam, Visnja, Karaman Ilic, Maja, Klaric, Vlasta, Vitkovic, Bibiana, Milic, Morena, Zupcic, Miro, De Baerdemaeker, Luc, Matot, I., De Hert, Stefan, Heyse, Bjorn, Van Limmen, Jurgen, Van Nieuwenhove, Yves, Mertens, Els, Neyrinck, Arne, Mulier, Jan, Kahn, David, Godoroja, Daniela, Martin-Loeches, Martin, Müller, G., Vorotyntsev, Sergiy, Fronchko, Valentyna, Matot, Idit, Goren, Or, Zac, Lilach, Gaszynski, Thomasz, Laffey, Jon, Mills, Gary, Nalwaya, Pramod, Mac Gregor, Mark, Mills, G. H., Paddle, Jonathan, Balaji, Packianathaswamy, Rubulotta, Francesca, Adebesin, Afeez, Margarson, Mike, Davies, Simon, Rangarajan, Desikan, Newell, Christopher, Shosholcheva, Mirjana, Papaspyros, Fotios, Mulier, J. P., Skandalou, Vasiliki, Dzurnakov, Paula, Kiss, T., Putensen, C., Rossaint, Rolf, Schmitt, J., Senturk, M., Serpa Neto, A., Severgnini, P., Sprung, J., Vidal Melo, M. F., Wrigge, H., Schultz, M. J., Bobek, I., Pelosi, P., Gama de Abreu, M., PROBESE investigators, PROtective VEntilation Network (PROVEnet), Clinical Trial Network of the European Society of Anaesthesiology (ESA), Güldner, Andreas, Huhle, Robert, Uhlig, Christopher, Vivona, Luigi, Bergamaschi, Alice, Canet, J., Stevanovic, Ana, Treschan, Tanja, Schaefer, Maximilian, Kienbaum, Peter, Laufenberg-Feldmann, Rita, Bergmann, Lars, Ebner, Felix, Robitzky, Luisa, Mölders, Patrick, Cinnella, G., Unterberg, Matthias, Busch, Cornelius, Achilles, Marc, Menzen, Angelika, Freesemann, Harbert, Putensen, Christian, Machado, Humberto, Cavaleiro, Carla, Ferreira, Cristina, Pinho, Daniela, De Baerdemaeker, L., Carvalho, Marta, Pinho, Sílvia, Soares, Maria, Castro, Diogo Sousa, Abelha, Fernando, Rabico, Rui, Delphin, Ellise, Sprung, Juraj, Weingarten, Toby N., Kellogg, Todd A., Gregoretti, C., Martin, Yvette N., McKenzie, Travis J., Brull, Sorin J., Renew, J. Ross, Ramakrishna, Harish, Fernandez-Bustamante, Ana, Balonov, Konstantin, Baig, Harris R., Kacha, Aalok, Pedemonte, Juan C., Hedenstierna, G., Altermatt, Fernando, Corvetto, Marcia A., Paredes, Sebastian, Carmona, Javiera, Rolle, Augusto, Bos, Elke, Beurskens, Charlotte, Veering, B., Zonneveldt, Harry, Boer, Christa, Hemmes, S. N., Godfried, Marc, Thiel, Bram, Kabon, Barbara, Reiterer, Christian, Canet, Jaume, Tolós, Raquel, Sendra, Mar, González, Miriam, Gómez, Noemí, Ferrando, Carlos, University Hospital Carl Gustav Carus, Semmelweis Egyetem, Budapest, Hospital Universitari Germans Trias I Pujol, Università degli Studi di Foggia - University of Foggia, Ghent University Hospital, Policlinico P. Giaccone, Palermo, University Hospital, Uppsala, University of Amsterdam [Amsterdam] (UvA), Medizinische Universität Wien = Medical University of Vienna, Physiologie & médecine expérimentale du Cœur et des Muscles [U 1046] (PhyMedExp), Institut National de la Santé et de la Recherche Médicale (INSERM)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS), Centre Hospitalier Régional Universitaire [Montpellier] (CHRU Montpellier), Faculdade de Medicina do ABC, São Paulo, University of Insubria, Varese, Mayo Clinic [Rochester], Massachusetts General Hospital [Boston], Universität Leipzig [Leipzig], University of Genoa (UNIGE), University Hospital Carl Gustav Carus Dresden, Dresden University of Technology, and Université de Montpellier (UM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)

Subjects

lcsh:R5-920, Anestesi och intensivvård, Anesthesiology and Intensive Care, business.industry, [SDV]Life Sciences [q-bio], Medicine (miscellaneous), 3. Good health, law.invention, 03 medical and health sciences, Protective ventilation, 0302 clinical medicine, Randomized controlled trial, law, Anesthesia, Ventilation (architecture), Medicine, Pharmacology (medical), 030212 general & internal medicine, business, lcsh:Medicine (General), 030217 neurology & neurosurgery, Positive end-expiratory pressure, ComputingMilieux_MISCELLANEOUS

Abstract

Trials 18(1), 247 (2017). doi:10.1186/s13063-017-1987-3

Published

2017

16. Incidence of hyperoxia and related in-hospital mortality in critically ill patients: a retrospective data analysis

Author

Kraft, F., primary, Andel, H., additional, Gamper, J., additional, Markstaller, K., additional, Ullrich, R., additional, and Klein, K. U., additional

Published

2017

17. Konfliktmatrix

Author

Andel, D., primary, Markstaller, K., additional, and Andel, H., additional

Published

2017

18. Erratum to Protective intraoperative ventilation with higher versus lower levels of positive end-expiratory pressure in obese patients (PROBESE) : study protocol for a randomized controlled trial

Author

Bluth, T, Teichmann, R, Kiss, T, Bobek, I, Canet, J, Cinnella, G, De Baerdemaeker, L, Gregoretti, C, Hedenstierna, Göran, Hemmes, S N, Hiesmayr, M, Hollmann, M W, Jaber, S, Laffey, J G, Licker, M J, Markstaller, K, Matot, I, Müller, G, Mills, G H, Mulier, J P, Putensen, C, Rossaint, R, Schmitt, J, Senturk, M, Neto, A Serpa, Severgnini, P, Sprung, J, Vidal Melo, M F, Wrigge, H, Schultz, M J, Pelosi, P, Gama de Abreu, Marcelo, Bluth, T, Teichmann, R, Kiss, T, Bobek, I, Canet, J, Cinnella, G, De Baerdemaeker, L, Gregoretti, C, Hedenstierna, Göran, Hemmes, S N, Hiesmayr, M, Hollmann, M W, Jaber, S, Laffey, J G, Licker, M J, Markstaller, K, Matot, I, Müller, G, Mills, G H, Mulier, J P, Putensen, C, Rossaint, R, Schmitt, J, Senturk, M, Neto, A Serpa, Severgnini, P, Sprung, J, Vidal Melo, M F, Wrigge, H, Schultz, M J, Pelosi, P, and Gama de Abreu, Marcelo

Published

2017

19. Protective intraoperative ventilation with higher versus lower levels of positive end-expiratory pressure in obese patients (PROBESE): study protocol for a randomized controlled trial

Author

UCL - (SLuc) Département de médecine aiguë, UCL - (SLuc) Service d'anesthésiologie, Bluth, T., Teichmann, R., Kiss, T., Bobek, I., Canet, J., Cinnella, G., De Baerdemaeker, L., Gregoretti, C., Hedenstierna, G., Hemmes, S. N., Hiesmayr, M., Hollmann, M. W., Jaber, S., Laffey, J. G., Licker, M. J., Markstaller, K., Matot, I., Müller, G., Mills, G. H., Mulier, J. P., Putensen, C., Rossaint, R., Schmitt, J., Senturk, M., Serpa Neto, A., Severgnini, P., Sprung, J., Vidal Melo, M. F., Wrigge, H., Schultz, M. J., Pelosi, P., Gama de Abreu, M., UCL - (SLuc) Département de médecine aiguë, UCL - (SLuc) Service d'anesthésiologie, Bluth, T., Teichmann, R., Kiss, T., Bobek, I., Canet, J., Cinnella, G., De Baerdemaeker, L., Gregoretti, C., Hedenstierna, G., Hemmes, S. N., Hiesmayr, M., Hollmann, M. W., Jaber, S., Laffey, J. G., Licker, M. J., Markstaller, K., Matot, I., Müller, G., Mills, G. H., Mulier, J. P., Putensen, C., Rossaint, R., Schmitt, J., Senturk, M., Serpa Neto, A., Severgnini, P., Sprung, J., Vidal Melo, M. F., Wrigge, H., Schultz, M. J., Pelosi, P., and Gama de Abreu, M.

Abstract

Background Postoperative pulmonary complications (PPCs) increase the morbidity and mortality of surgery in obese patients. High levels of positive end-expiratory pressure (PEEP) with lung recruitment maneuvers may improve intraoperative respiratory function, but they can also compromise hemodynamics, and the effects on PPCs are uncertain. We hypothesized that intraoperative mechanical ventilation using high PEEP with periodic recruitment maneuvers, as compared with low PEEP without recruitment maneuvers, prevents PPCs in obese patients. Methods/design The PRotective Ventilation with Higher versus Lower PEEP during General Anesthesia for Surgery in OBESE Patients (PROBESE) study is a multicenter, two-arm, international randomized controlled trial. In total, 2013 obese patients with body mass index ≥35 kg/m2 scheduled for at least 2 h of surgery under general anesthesia and at intermediate to high risk for PPCs will be included. Patients are ventilated intraoperatively with a low tidal volume of 7 ml/kg (predicted body weight) and randomly assigned to PEEP of 12 cmH2O with lung recruitment maneuvers (high PEEP) or PEEP of 4 cmH2O without recruitment maneuvers (low PEEP). The occurrence of PPCs will be recorded as collapsed composite of single adverse pulmonary events and represents the primary endpoint. Discussion To our knowledge, the PROBESE trial is the first multicenter, international randomized controlled trial to compare the effects of two different levels of intraoperative PEEP during protective low tidal volume ventilation on PPCs in obese patients. The results of the PROBESE trial will support anesthesiologists in their decision to choose a certain PEEP level during general anesthesia for surgery in obese patients in an attempt to prevent PPCs.

Published

2017

20. Cyclic and constant hyperoxia cause inflammation, apoptosis and cell death in human umbilical vein endothelial cells

Author

Wu, J., primary, Hafner, C., additional, Schramel, J. P., additional, Kaun, C., additional, Krychtiuk, K. A., additional, Wojta, J., additional, Boehme, S., additional, Ullrich, R., additional, Tretter, E. V., additional, Markstaller, K., additional, and Klein, K. U., additional

Published

2015

21. „Awareness“ während Allgemeinanästhesie

Author

Markstaller, K., primary

Published

2015

22. ERS statement on chest imaging in acute respiratory failure

Author

Giovanni Sotgiu, Antonio Artigas, Peter M. Spieth, Aleksandar Grgic, Giuseppe Francesco Sferrazza Papa, Davide Chiumello, Leo M. A. Heunks, Paolo Navalesi, Maurizio Zompatori, Marcus J. Schultz, Klaus Markstaller, Giulia Michela Pellegrino, Lara Pisani, Belaid Bouhemad, David Rigau, Intensive care medicine, ACS - Pulmonary hypertension & thrombosis, Chiumello D., Sferrazza Papa G.F., Artigas A., Bouhemad B., Grgic A., Heunks L., Markstaller K., Pellegrino G.M., Pisani L., Rigau D., Schultz M.J., Sotgiu G., Spieth P., Zompatori M., Navalesi P., Intensive Care Medicine, AII - Inflammatory diseases, ACS - Diabetes & metabolism, and ACS - Microcirculation

Subjects

Pulmonary and Respiratory Medicine, medicine.medical_specialty, medicine.medical_treatment, Radiography, MEDLINE, 03 medical and health sciences, Pulmonary Disease, Chronic Obstructive, 0302 clinical medicine, medicine, Electric Impedance, Pulmonary Medicine, Humans, Acute respiratory failure, Intensive care medicine, Electrical impedance tomography, Ultrasonography, Mechanical ventilation, Heart Failure, Respiratory Distress Syndrome, Modalities, Chest imaging, medicine.diagnostic_test, business.industry, Pneumothorax, 030208 emergency & critical care medicine, Pneumonia, Europe, Pleural Effusion, 030228 respiratory system, Positron emission tomography, Positron-Emission Tomography, Radiography, Thoracic, business, Respiratory Insufficiency, Tomography, X-Ray Computed, Human

Abstract

Chest imaging in patients with acute respiratory failure plays an important role in diagnosing, monitoring and assessing the underlying disease. The available modalities range from plain chest X-ray to computed tomography, lung ultrasound, electrical impedance tomography and positron emission tomography. Surprisingly, there are presently no clear-cut recommendations for critical care physicians regarding indications for and limitations of these different techniques.The purpose of the present European Respiratory Society (ERS) statement is to provide physicians with a comprehensive clinical review of chest imaging techniques for the assessment of patients with acute respiratory failure, based on the scientific evidence as identified by systematic searches. For each of these imaging techniques, the panel evaluated the following items: possible indications, technical aspects, qualitative and quantitative analysis of lung morphology and the potential interplay with mechanical ventilation. A systematic search of the literature was performed from inception to September 2018. A first search provided 1833 references. After evaluating the full text and discussion among the committee, 135 references were used to prepare the current statement.These chest imaging techniques allow a better assessment and understanding of the pathogenesis and pathophysiology of patients with acute respiratory failure, but have different indications and can provide additional information to each other.

Published

2019

23. The Effect of Prone Positioning After Lung Transplantation.

Author

Frick AE, Schiefer J, Maleczek M, Schwarz S, Benazzo A, Rath A, Kulu A, Hritcu R, Faybik P, Schaden E, Jaksch P, Tschernko E, Frommlet F, Markstaller K, and Hoetzenecker K

Subjects

Humans, Prone Position, Male, Female, Middle Aged, Retrospective Studies, Adult, Patient Positioning methods, Pulmonary Gas Exchange physiology, Treatment Outcome, Lung Transplantation methods

Abstract

Background: Prone positioning has become a standard therapy in acute respiratory distress syndrome to improve oxygenation and decrease mortality. However, little is known about prone positioning in lung transplant recipients. This large, singe-center analysis investigated whether prone positioning improves gas exchange after lung transplantation., Methods: Clinical data of 583 patients were analyzed. Prone position was considered in case of impaired gas exchange Pao 2 /fraction of oxygen in inhaled air (<250), signs of edema after lung transplantation, and/or evidence of reperfusion injury. Patients with hemodynamic instability or active bleeding were not proned. Impact of prone positioning (n = 165) on gas exchange, early outcome and survival were determined and compared with patients in supine positioning (n = 418)., Results: Patients in prone position were younger, more likely to have interstitial lung disease, and had a higher lung allocation score. Patients were proned for a median of 19 hours (interquartile range,15-26) hours). They had significantly lower Pao 2 /fraction of oxygen in inhaled air (227 ± 96 vs 303 ± 127 mm Hg, P = .004), and lower lung compliance (24.8 ± 9.1 mL/mbar vs 29.8 ± 9.7 mL/mbar, P < .001) immediately after lung transplantation. Both values significantly improved after prone positioning for 24 hours (Pao 2 /fraction of oxygen ratio: 331 ± 91 mm Hg; lung compliance: 31.7 ± 20.2 mL/mbar). Survival at 90 days was similar between the 2 groups (93% vs 96%, P = .105)., Conclusions: Prone positioning led to a significant improvement in lung compliance and oxygenation after lung transplantation. Prospective studies are needed to confirm the benefit of prone positioning in lung transplantation., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

24. [Infection prevention in the operating theater: practice-oriented recommendations for anesthesiologists].

Author

Schnetzinger M, Assadian O, Markstaller K, and Klein KU

Subjects

Humans, Hospitals, Germany, Hygiene, Anesthesiologists, Operating Rooms

Abstract

This article is intended to provide clinically working anesthesiologists with a practice-oriented overview of selected important current guidelines and recommendations pertaining to intraoperative prevention of infection. The contents of this article are based on the guidelines or recommendation of the World Health Organization (WHO) and the Association of the Scientific Medical Societies in Germany (AWMF) as well as the Commission for Hospital Hygiene and Infection Prevention (KRINKO) at the Robert Koch Institute (RKI). The authors' objective is to foster and support the standard of infection prevention and control in the operating theater by optimizing the standard of hygiene in daily practice to reduce the number of perioperative infections., (© 2022. The Author(s).)

Published

2023

25. Effects of Hyperoxia and Hyperoxic Oscillations on the Proteome of Murine Lung Microvascular Endothelium.

Author

Tiboldi A, Hunyadi-Gulyas E, Wohlrab P, Schmid JA, Markstaller K, Klein KU, and Tretter V

Abstract

Patients presenting with insufficient tissue oxygenation and impaired lung function as in acute respiratory distress syndrome (ARDS) frequently require mechanical ventilation with supplemental oxygen. Despite the lung being used to experiencing the highest partial pressure of oxygen during healthy breathing, the organ is susceptible to oxygen-induced injury at supraphysiological concentrations. Hyperoxia-induced lung injury (HALI) has been regarded as a second hit to pre-existing lung injury and ventilator-induced lung injury (VILI) attributed to oxidative stress. The injured lung has a tendency to form atelectasis, a cyclic collapse and reopening of alveoli. The affected lung areas experience oxygen conditions that oscillate between hyperoxia and hypoxia rather than remaining in a constant hyperoxic state. Mechanisms of HALI have been investigated in many animal models previously. These studies provided insights into the effects of hyperoxia on the whole organism. However, cell type-specific responses have not been dissected in detail, but are necessary for a complete mechanistic understanding of ongoing pathological processes. In our study, we investigated the effects of constant and intermittent hyperoxia on the lung endothelium from a mouse by an in vitro proteomic approach. We demonstrate that these oxygen conditions have characteristic effects on the pulmonary endothelial proteome that underlie the physiological (patho)mechanisms.

Published

2022

26. Gamma-glutamyltransferase is a strong predictor of secondary sclerosing cholangitis after lung transplantation for COVID-19 ARDS.

Author

Schwarz S, Lang C, Harlander M, Štupnik T, Slambrouck JV, Ceulemans LJ, Ius F, Gottlieb J, Kuhnert S, Hecker M, Aigner C, Kneidinger N, Verschuuren EA, Smits JM, Tschernko E, Schaden E, Faybik P, Markstaller K, Trauner M, Jaksch P, and Hoetzenecker K

Subjects

Humans, Retrospective Studies, gamma-Glutamyltransferase, COVID-19 complications, Cholangitis, Sclerosing complications, Cholangitis, Sclerosing surgery, Lung Transplantation adverse effects, Respiratory Distress Syndrome

Abstract

Background: Lung transplantation (LTx) can be considered for selected patients suffering from COVID-19 acute respiratory distress syndrome (ARDS). Secondary sclerosing cholangitis in critically ill (SSC-CIP) patients has been described as a late complication in COVID-19 ARDS survivors, however, rates of SSC-CIP after LTx and factors predicting this detrimental sequela are unknown., Methods: This retrospective analysis included all LTx performed for post-COVID ARDS at 8 European LTx centers between May 2020 and January 2022. Clinical risk factors for SSC-CIP were analyzed over time. Prediction of SSC-CIP was assessed by ROC-analysis., Results: A total of 40 patients were included in the analysis. Fifteen patients (37.5%) developed SSC-CIP. GGT at the time of listing was significantly higher in patients who developed SSC-CIP (median 661 (IQR 324-871) vs 186 (109-346); p = 0.001). Moreover, higher peak values for GGT (585 vs 128.4; p < 0.001) and ALP (325 vs 160.2; p = 0.015) were found in the 'SSC' group during the waiting period. Both, GGT at the time of listing and peak GGT during the waiting time, could predict SSC-CIP with an AUC of 0.797 (95% CI: 0.647-0.947) and 0.851 (95% CI: 0.707-0.995). Survival of 'SSC' patients was severely impaired compared to 'no SSC' patients (1-year: 46.7% vs 90.2%, log-rank p = 0.004)., Conclusions: SSC-CIP is a severe late complication after LTx for COVID-19 ARDS leading to significant morbidity and mortality. GGT appears to be a sensitive parameter able to predict SSC-CIP even at the time of listing., Competing Interests: Disclosure statement None of the authors have any relevant conflict of interest to declare., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

27. A Dual-Lumen Extracorporeal Membrane Oxygenation Cannulation Technique Using a Mobile X-Ray Device.

Author

Schweiger T, Ponholzer F, Kifjak D, Schwarz S, Benazzo A, Lang G, Tschernko E, Markstaller K, and Hoetzenecker K

Subjects

Humans, Retrospective Studies, Ultrasonography, Catheterization, Extracorporeal Membrane Oxygenation instrumentation, Extracorporeal Membrane Oxygenation methods, X-Rays

Abstract

Purpose: Dual-lumen extracorporeal membrane oxygenation (ECMO) cannulation is considered technically challenging and harbors the risk of potential life-threatening complications during cannulation. Dual-lumen cannula insertion is performed under either ultrasound or fluoroscopy guidance. Both techniques have significant disadvantages, such as examiner dependence or the necessity for transportation of the patient from the intensive care unit to the operating room., Description: Digital, mobile x-ray devices provide a novel, examiner-independent imaging modality for bedside dual-lumen ECMO cannulation., Evaluation: From November 2019 to November 2021, 23 dual-lumen cannulations were performed in 20 patients at the Department of Thoracic Surgery, Medical University of Vienna. Twelve of 23 (52.2%) were inserted in the intensive care unit using a mobile x-ray device. The remaining patients (47.8%) were cannulated in the operating room with conventional fluoroscopy guidance. In none of the procedures did cardiovascular injuries occur. Insertion site bleeding was the most common ECMO-related complication (n = 2)., Conclusions: Dual-lumen cannulation using sequential x-rays can be performed safely. Especially for infectious patients or patients who require an awake ECMO, this technique overcomes disadvantages of established imaging modalities., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

28. Intensive care medicine must not be a primary discipline in Europe.

Author

Hasibeder W, Markstaller K, Schaden E, and Kietaibl S

Subjects

Critical Care, Europe, Humans, Medicine

Published

2022

29. Clinical relevance of lung transplantation for COVID-19 ARDS: a nationwide study.

Author

Lang C, Ritschl V, Augustin F, Lang G, Moser B, Taghavi S, Murakoezy G, Lambers C, Flick H, Koestenberger M, Brooks R, Muhr T, Knotzer J, Mydza D, Kaufmann M, Staudinger T, Zauner C, Krenn C, Schaden E, Bacher A, Rössler B, Faybik P, Tschernko E, Anwar M, Markstaller K, Höfer D, Stamm T, Jaksch P, and Hoetzenecker K

Abstract

Background: Although the number of lung transplantations (LTx) performed worldwide for COVID-19 induced acute respiratory distress syndrome (ARDS) is still low, there is general agreement that this treatment can save a subgroup of most severly ill patients with irreversible lung damage. However, the true proportion of patients eligible for LTx, the overall outcome and the impact of LTx to the pandemic are unknown., Methods: A retrospective analysis was performed using a nationwide registry of hospitalised patients with confirmed severe acute respiratory syndrome coronavirus type 2 (SARS-Cov-2) infection admitted between January 1, 2020 and May 30, 2021 in Austria. Patients referred to one of the two Austrian LTx centers were analyzed and grouped into patients accepted and rejected for LTx. Detailed outcome analysis was performed for all patients who received a LTx for post-COVID-19 ARDS and compared to patients who underwent LTx for other indications., Results: Between January 1, 2020 and May 30, 2021, 39.485 patients were hospitalised for COVID-19 in Austria. 2323 required mechanical ventilation, 183 received extra-corporeal membrane oxygenation (ECMO) support. 106 patients with severe COVID-19 ARDS were referred for LTx. Of these, 19 (18%) underwent LTx. 30-day mortality after LTx was 0% for COVID-19 ARDS transplant recipients. With a median follow-up of 134 (47-450) days, 14/19 patients are alive., Conclusions: Early referral of ECMO patients to a LTx center is pivotal in order to select patients eligible for LTx. Transplantation offers excellent midterm outcomes and should be incorporated in the treatment algorithm of post-COVID-19 ARDS., Competing Interests: Conflict of interest:The authors declare that there is no conflict of interest., (Copyright ©The authors 2022. For reproduction rights and permissions contact permissions@ersnet.org.)

Published

2022

30. Duration of invasive mechanical ventilation prior to extracorporeal membrane oxygenation is not associated with survival in acute respiratory distress syndrome caused by coronavirus disease 2019.

Author

Hermann M, Laxar D, Krall C, Hafner C, Herzog O, Kimberger O, Koenig S, Kraft F, Maleczek M, Markstaller K, Robak O, Rössler B, Schaden E, Schellongowski P, Schneeweiss-Gleixner M, Staudinger T, Ullrich R, Wiegele M, Willschke H, Zauner C, and Hermann A

Abstract

Background: Duration of invasive mechanical ventilation (IMV) prior to extracorporeal membrane oxygenation (ECMO) affects outcome in acute respiratory distress syndrome (ARDS). In coronavirus disease 2019 (COVID-19) related ARDS, the role of pre-ECMO IMV duration is unclear. This single-centre, retrospective study included critically ill adults treated with ECMO due to severe COVID-19-related ARDS between 01/2020 and 05/2021. The primary objective was to determine whether duration of IMV prior to ECMO cannulation influenced ICU mortality., Results: During the study period, 101 patients (mean age 56 [SD ± 10] years; 70 [69%] men; median RESP score 2 [IQR 1-4]) were treated with ECMO for COVID-19. Sixty patients (59%) survived to ICU discharge. Median ICU length of stay was 31 [IQR 20.7-51] days, median ECMO duration was 16.4 [IQR 8.7-27.7] days, and median time from intubation to ECMO start was 7.7 [IQR 3.6-12.5] days. Fifty-three (52%) patients had a pre-ECMO IMV duration of > 7 days. Pre-ECMO IMV duration had no effect on survival (p = 0.95). No significant difference in survival was found when patients with a pre-ECMO IMV duration of < 7 days (< 10 days) were compared to ≥ 7 days (≥ 10 days) (p = 0.59 and p = 1.0)., Conclusions: The role of prolonged pre-ECMO IMV duration as a contraindication for ECMO in patients with COVID-19-related ARDS should be scrutinised. Evaluation for ECMO should be assessed on an individual and patient-centred basis., (© 2022. The Author(s).)

Published

2022

31. Oxygen-Dependent Changes in the N-Glycome of Murine Pulmonary Endothelial Cells.

Author

Tiboldi A, Führer J, Schaubmayr W, Hunyadi-Gulyas E, Zach ML, Hochreiter B, Spittler A, Ullrich R, Markstaller K, Altmann F, Klein KU, and Tretter V

Abstract

Supplemental oxygen is frequently used together with mechanical ventilation to achieve sufficient blood oxygenation. Despite the undoubted benefits, it is vigorously debated whether too much oxygen can also have unpredicted side-effects. Uncertainty is also due to the fact that the molecular mechanisms are still insufficiently understood. The lung endothelium is covered with an exceptionally broad glycocalyx, carrying N- and O-glycans, proteoglycans, glycolipids and glycosaminoglycans. Glycan structures are not genetically determined but depend on the metabolic state and the expression level and activity of biosynthetic and glycan remodeling enzymes, which can be influenced by oxygen and the redox status of the cell. Altered glycan structures can affect cell interactions and signaling. In this study, we investigated the effect of different oxygen conditions on aspects of the glycobiology of the pulmonary endothelium with an emphasis on N-glycans and terminal sialylation using an in vitro cell culture system. We combined a proteomic approach with N-glycan structure analysis by LC-MS, qRT-PCR, sialic acid analysis and lectin binding to show that constant and intermittent hyperoxia induced time dependent changes in global and surface glycosylation. An siRNA approach identified St6gal1 as being primarily responsible for the early transient increase of α2-6 sialylated structures in response to hyperoxia.

Published

2021

32. Safety and preliminary efficacy of sequential multiple ascending doses of solnatide to treat pulmonary permeability edema in patients with moderate-to-severe ARDS-a randomized, placebo-controlled, double-blind trial.

Author

Schmid B, Kredel M, Ullrich R, Krenn K, Lucas R, Markstaller K, Fischer B, Kranke P, Meybohm P, Zwißler B, and Frank S

Subjects

Double-Blind Method, Edema, Humans, Peptides, Cyclic, Permeability, SARS-CoV-2, Treatment Outcome, COVID-19, Pulmonary Edema diagnosis, Pulmonary Edema drug therapy, Respiratory Distress Syndrome diagnosis, Respiratory Distress Syndrome drug therapy

Abstract

Background: Acute respiratory distress syndrome (ARDS) is a complex clinical diagnosis with various possible etiologies. One common feature, however, is pulmonary permeability edema, which leads to an increased alveolar diffusion pathway and, subsequently, impaired oxygenation and decarboxylation. A novel inhaled peptide agent (AP301, solnatide) was shown to markedly reduce pulmonary edema in animal models of ARDS and to be safe to administer to healthy humans in a Phase I clinical trial. Here, we present the protocol for a Phase IIB clinical trial investigating the safety and possible future efficacy endpoints in ARDS patients., Methods: This is a randomized, placebo-controlled, double-blind intervention study. Patients with moderate to severe ARDS in need of mechanical ventilation will be randomized to parallel groups receiving escalating doses of solnatide or placebo, respectively. Before advancing to a higher dose, a data safety monitoring board will investigate the data from previous patients for any indication of patient safety violations. The intervention (application of the investigational drug) takes places twice daily over the course of 7 days, ensued by a follow-up period of another 21 days., Discussion: The patients to be included in this trial will be severely sick and in need of mechanical ventilation. The amount of data to be collected upon screening and during the course of the intervention phase is substantial and the potential timeframe for inclusion of any given patient is short. However, when prepared properly, adherence to this protocol will make for the acquisition of reliable data. Particular diligence needs to be exercised with respect to informed consent, because eligible patients will most likely be comatose and/or deeply sedated at the time of inclusion., Trial Registration: This trial was prospectively registered with the EU Clinical trials register (clinicaltrialsregister.eu). EudraCT Number: 2017-003855-47 ., (© 2021. The Author(s).)

Published

2021

33. Oxygen conditions oscillating between hypoxia and hyperoxia induce different effects in the pulmonary endothelium compared to constant oxygen conditions.

Author

Wohlrab P, Johann Danhofer M, Schaubmayr W, Tiboldi A, Krenn K, Markstaller K, Ullrich R, Ulrich Klein K, and Tretter V

Subjects

Animals, Antioxidants metabolism, Apoptosis, Blood Coagulation, Cell Hypoxia, Cells, Cultured, Cytokines metabolism, Endothelial Cells pathology, Endothelium, Vascular pathology, Endothelium, Vascular physiopathology, Hyperoxia pathology, Hyperoxia physiopathology, Hypoxia pathology, Hypoxia physiopathology, Inflammation Mediators metabolism, Mice, Mice, Inbred C57BL, Necrosis, Renin-Angiotensin System, Time Factors, Endothelial Cells metabolism, Endothelium, Vascular metabolism, Hyperoxia metabolism, Hypoxia metabolism, Lung blood supply, Oxygen metabolism

Abstract

The pulmonary endothelium is an immediate recipient of high oxygen concentrations upon oxygen therapy and mediates down-stream responses. Cyclic collapse and reopening of atelectatic lung areas during mechanical ventilation with high fractions of inspired oxygen result in the propagation of oxygen oscillations in the hypoxic/hyperoxic range. We used primary murine lung endothelial cell cultures to investigate cell responses to constant and oscillating oxygen conditions in the hypoxic to hyperoxic range. Severe constant hyperoxia had pro-inflammatory and cytotoxic effects including an increase in expression of ICAM1, E-selectin, and RAGE at 24 hr exposure. The coagulative/fibrinolytic system responded by upregulation of uPA, tPA, and vWF and PAI1 under constant severe hyperoxia. Among antioxidant enzymes, the upregulation of SOD2, TXN1, TXNRD3, GPX1, and Gstp1 at 24 hr, but downregulation of SOD3 at 72 hr constant hyperoxia was evident. Hypoxic/hyperoxic oscillating oxygen conditions induced pro-inflammatory cytokine release to a lesser extent and later than constant hyperoxia. Gene expression analyses showed upregulation of NFKB p65 mRNA at 72 hr. More evident was a biphasic response of NOS3 and ACE1 gene expression (downregulation until 24 hr and upregulation at 72 hr). ACE2 mRNA was upregulated until 72 hr, but shedding of the mature protein from the cell surface favored ACE1. Oscillations resulted in severe production of peroxynitrite, but apart from upregulation of Gstp1 at 24 hr responses of antioxidative proteins were less pronounced than under constant hyperoxia. Oscillating oxygen in the hypoxic/hyperoxic range has a characteristical impact on vasoactive mediators like NOS3 and on the activation of the renin-angiotensin system in the lung endothelium., (© 2021 The Authors. Physiological Reports published by Wiley Periodicals, Inc. on behalf of The Physiological Society and the American Physiological Society.)

Published

2021

34. Update on hyperbaric oxygen therapy in burn treatment.

Author

Weitgasser L, Ihra G, Schäfer B, Markstaller K, and Radtke C

Subjects

Humans, Prospective Studies, Wound Healing, Burns therapy, Hyperbaric Oxygenation, Plastic Surgery Procedures

Abstract

Hyperbaric oxygen therapy (HBOT) has been shown to improve tissue hypoxia, neovascularization and ischemia reperfusion injury and reduce pathologic inflammation in various clinical settings and was proposed to be a game changer in treatment of burns. Improved and faster wound healing as well as a reduction of morbidity and mortality after thermal and concomitant carbon monoxide poisoning are expected. In defiance of the observed benefits for burn wounds and carbon monoxide poisoning in animal models and few randomized controlled trials there is an ongoing controversy regarding its use, indications and cost effectiveness. Furthermore, the use of HBOT, its indications and the evidence behind its efficiency are still widely unknown to most physicians involved in the treatment of burn patients. Therefore, a review of the up to date evidence-based literature was performed with a focus on available data of HBOT in burn care, to elaborate its use in acute thermal injury and carbon monoxide intoxication. Although beneficial effects of HBOT seem very likely insufficient evidence to support or disprove the routine use of HBOT in the treatment of burn care was found. Although difficult to carry out because of the high interindividual variability of burns and chronic wounds, the need for larger high-quality prospective randomized double-blinded controlled multicenter trials are necessary to be able to evaluate useful applications, expense and cost-efficiency of HBOT for burn care.

Published

2021

35. Recommendations for extracorporeal membrane oxygenation (ECMO) in COVID-19 patients : Consensus paper of the Medical University of Vienna.

Author

Wiedemann D, Bernardi MH, Distelmaier K, Goliasch G, Hengstenberg C, Hermann A, Holzer M, Hoetzenecker K, Klepetko W, Lang G, Lassnigg A, Laufer G, Magnet IAM, Markstaller K, Röggla M, Rössler B, Schellongowski P, Simon P, Tschernko E, Ullrich R, Zimpfer D, and Staudinger T

Subjects

Aged, COVID-19, Child, Humans, SARS-CoV-2, Betacoronavirus, Coronavirus Infections, Extracorporeal Membrane Oxygenation, Pandemics, Pneumonia, Viral

Abstract

The pandemic from the SARS-CoV‑2 virus is currently challenging healthcare systems all over the world. Maintaining appropriate staffing and resources in healthcare facilities is essential to guarantee a safe working environment for healthcare personnel and safe patient care. Extracorporeal membrane oxygenation (ECMO) represents a valuable therapeutic option in patients with severe heart or lung failure. Although only a limited proportion of COVID-19 patients develop respiratory or circulatory failure that is refractory to conventional treatment, it is of utmost importance to clearly define criteria for the use of ECMO in this steadily growing patient population. The ECMO working group of the Medical University of Vienna has established the following recommendations for ECMO support in COVID-19 patients.

Published

2020

36. SARS-CoV-2: recommendations for treatment in intensive care medicine.

Author

Köstenberger M, Hasibeder W, Dankl D, Germann R, Hörmann C, Joannidis M, Markstaller K, Müller-Muttonen SO, Neuwersch-Sommeregger S, Schaden E, Staudinger T, Ullrich R, Valentin A, and Likar R

Subjects

Austria, COVID-19, Critical Care, Humans, SARS-CoV-2, Betacoronavirus, Coronavirus Infections therapy, Pandemics, Pneumonia, Viral therapy

Abstract

Coronavirus disease 2019 (COVID-19) progresses mildly in most of the cases; however, about 5% of the patients develop a severe acute respiratory distress syndrome (ARDS). Of all COVID-19 patients 3% need intensive care treatment, which becomes a great challenge for anesthesiology and intensive care medicine, medically, hygienically and for technical safety requirements. For these reasons, only experienced medical and nursing staff in the smallest grouping possible should be assigned. For these team members, a consistent use of personal protective equipment (PPE) is essential.Due to the immense medical challenges, the following treatment guidelines were developed by the ÖGARI (Österreichische Gesellschaft für Anästhesiologie, Reanimation und Intensivmedizin), FASIM (Federation of Austrian Societies of Intensive Care Medicine) and ÖGIAIN (Österreichische Gesellschaft für Internistische und Allgemeine Intensivmedizin und Notfallmedizin).The recommendations given in this article are to be understood as short snapshots of the moment; all basic guidelines are works in progress and will be regularly updated as evidence levels, new study results and additional experience are gathered.

Published

2020

37. Investigating Disturbances of Oxygen Homeostasis: From Cellular Mechanisms to the Clinical Practice.

Author

Tretter V, Zach ML, Böhme S, Ullrich R, Markstaller K, and Klein KU

Abstract

Soon after its discovery in the 18th century, oxygen was applied as a therapeutic agent to treat severely ill patients. Lack of oxygen, commonly termed as hypoxia, is frequently encountered in different disease states and is detrimental to human life. However, at the end of the 19th century, Paul Bert and James Lorrain Smith identified what is known as oxygen toxicity. The molecular basis of this phenomenon is oxygen's readiness to accept electrons and to form different variants of aggressive radicals that interfere with normal cell functions. The human body has evolved to maintain oxygen homeostasis by different molecular systems that are either activated in the case of oxygen under-supply, or to scavenge and to transform oxygen radicals when excess amounts are encountered. Research has provided insights into cellular mechanisms of oxygen homeostasis and is still called upon in order to better understand related diseases. Oxygen therapy is one of the prime clinical interventions, as it is life saving, readily available, easy to apply and economically affordable. However, the current state of research also implicates a reconsidering of the liberal application of oxygen causing hyperoxia. Increasing evidence from preclinical and clinical studies suggest detrimental outcomes as a consequence of liberal oxygen therapy. In this review, we summarize concepts of cellular mechanisms regarding different forms of disturbed cellular oxygen homeostasis that may help to better define safe clinical application of oxygen therapy., (Copyright © 2020 Tretter, Zach, Böhme, Ullrich, Markstaller and Klein.)

Published

2020

38. Ropivacaine Activates Multiple Proapoptotic and Inflammatory Signaling Pathways That Might Subsume to Trigger Epidural-Related Maternal Fever.

Author

Wohlrab P, Boehme S, Kaun C, Wojta J, Spittler A, Saleh L, Knöfler M, Markstaller K, Klein KU, and Tretter V

Subjects

Anesthetics, Local administration & dosage, Apoptosis physiology, Cells, Cultured, Dose-Response Relationship, Drug, Female, Fever chemically induced, Human Umbilical Vein Endothelial Cells drug effects, Human Umbilical Vein Endothelial Cells metabolism, Humans, Pregnancy, Ropivacaine administration & dosage, Signal Transduction drug effects, Signal Transduction physiology, Anesthesia, Epidural adverse effects, Anesthetics, Local adverse effects, Apoptosis drug effects, Fever metabolism, Inflammation Mediators metabolism, Ropivacaine adverse effects

Abstract

Background: Epidural-related maternal fever (ERMF) is an adverse effect of epidural analgesia during labor and is associated with perinatal and neonatal morbidity. Local anesthetics have been proposed to trigger ERMF via sterile inflammation. Ropivacaine is currently the most frequently used epidural anesthetic and considered least toxic. This study investigates molecular effects of ropivacaine on human umbilical vein endothelial cells (HUVECs) as model system for endothelial cells and human placental trophoblasts (TBs), compares the effects to the putative anti-inflammatory lidocaine and investigates the partially alleviating impact of the anti-inflammatory corticosteroid dexamethasone., Methods: HUVECs and TBs were exposed to ropivacaine (35 μM-7 mM) or lidocaine (21 mM) with or without dexamethasone (1 μM). AnnexinV/propidium iodide staining and lactate dehydrogenase release were used to analyze apoptosis and cytotoxicity. Proinflammatory interleukins-6 (IL-6) and IL-8 as well as prostaglandin E2 (PGE2) were measured by enzyme-linked immunosorbent assay (ELISA), while activation of signaling pathways was detected by Western blotting. Oxidative stress was visualized by live cell imaging and quantification of antioxidant proteins, intercellular adhesion molecule 1, vascular cell adhesion molecule 1, platelet endothelial cell adhesion molecule 1, cyclooxygenase 2, and mitochondrial deoxyribonucleic acid by real-time polymerase chain reaction. Dissipation of the mitochondrial membrane potential was assessed with cytofluorimetric analysis using the J-Aggregate (JC-1 staining [cytofluorimetric analysis using the J-Aggregate])., Results: Ropivacaine exposure dose-dependently induced apoptosis and an increased release of IL-6, IL-8, and PGE2 from HUVECs and TBs. Furthermore, caspase-3, nuclear factor-κB, and p38 mitogen-activated protein kinase pathways were activated, while extracellular signal-regulated kinase 1/2 and protein kinase B (Akt) were dephosphorylated. Downregulation of antioxidative proteins induced oxidative stress and upregulation of ICAM1, VCAM1, and PECAM1 possibly facilitate leukocyte transmigration. Mitochondrial effects included increased release of the proinflammatory mitochondrial DNA damage-associated molecular patterns, but no significant dissipation of the mitochondrial membrane potential. Conversely, lidocaine exhibited repression of IL-6 and IL-8 release over all time points, and early downregulation of COX2 and cell adhesion molecules, which was followed by a late overshooting reaction. Dexamethasone reduced especially inflammatory effects, but as an inducer of mitophagy, had negative long-term effects on mitochondrial function., Conclusions: This study suggests that ropivacaine causes cellular injury and death in HUVECs and TBs via different signaling pathways. The detrimental effects induced by ropivacaine are only partially blunted by dexamethasone. This observation strengthens the importance of inflammation in ERMF.

Published

2020

39. [Recommendations for Extracorporeal Membrane Oxygenation (ECMO) in COVID-19 Patients].

Author

Wiedemann D, Bernardi MH, Distelmaier K, Goliasch G, Hengstenberg C, Hermann A, Holzer M, Hoetzenecker K, Klepetko W, Lang G, Lassnigg A, Laufer G, Magnet IAM, Markstaller K, Röggla M, Rössler B, Schellongowski P, Simon P, Tschernko E, Ullrich R, Zimpfer D, and Staudinger T

Abstract

The pandemic from the SARS-CoV‑2 Virus is currently challenging health care systems all over the world. Maintaining appropriate staffing and resources in healthcare facilities is essential to guarantee a safe work environment for healthcare personnel and safe patient care. Extracorporeal membrane oxygenation (ECMO) represents a valuable therapeutic option in patients with severe heart or lung failure. Although only a limited proportion of COVID-19 patients develops respiratory or circulatory failure that is refractory to conventional therapies, it is of utmost importance to clearly define criteria for the use of ECMOs in this steadily growing patient population. The ECMO working group of the Medical University of Vienna has established the following recommendations for ECMO support in COVID-19 patients., (© The Author(s) 2020.)

Published

2020

40. ÖGARI Ethik-Manifest für eine menschlichere Medizin.

Author

Likar R, Markstaller K, von Goedecke A, Stromer W, Fritsch G, and Wallner J

Subjects

Ethics, Medical, Humans, Medicine

Published

2019

41. Impact of CPAP on Forehead Near-infrared Spectroscopy Measurements in Patients With Acute Respiratory Failure: Truth or Illusion.

Author

Doerr C, Kietaibl C, Doerr K, Hagmann M, Baumann L, Kimberger O, Ullrich R, Markstaller K, and Klein KU

Subjects

Adult, Aged, Aged, 80 and over, Blood Gas Analysis, Critical Care, Critical Illness, Cross-Over Studies, Female, Forehead, Humans, Hypoxia, Brain prevention & control, Male, Middle Aged, Monitoring, Physiologic, Oxygen therapeutic use, Continuous Positive Airway Pressure methods, Respiratory Insufficiency diagnosis, Spectroscopy, Near-Infrared methods

Abstract

Background: Critically ill patients with acute respiratory failure admitted to an intensive care unit are at high risk for cerebral hypoxia. We investigated the impact of continuous positive airway pressure (CPAP) therapy on regional cerebral tissue oxygenation (rSO2)., Materials and Methods: In total, 40 extubated surgical intensive care unit patients requiring classic oxygen therapy (COT) for acute respiratory failure were examined. Near-infrared spectroscopy (INVOS 5100C, Covidien) was used for 30 minutes to detect bilateral rSO2 during COT via facemask (6 L/min) and CPAP therapy (40% fraction of inspired oxygen, 8 cm H2O CPAP) using a randomized crossover study design. Patients served as their own control. Continuous hemodynamic routine monitoring and blood gas analysis were performed. The effect of CPAP therapy on rSO2 and influence of assessed covariables were investigated using a mixed linear model., Results: Median rSO2 increased from 57.9% (95% confidence interval [CI], 54.2-61.5) during COT to 62.8% (95% CI, 59.2-66.5) during CPAP therapy (P<0.0001). The estimated difference from the mixed model between COT and CPAP is -5.0 (95% CI, -6.3 to -3.7). Median arterial partial pressure of carbon dioxide decreased from 47.8±5.1 mm Hg during COT to 43.1±5 mm Hg during CPAP (P<0.001), whereas arterial partial pressure of oxygen remained unchanged (P=0.329). In total, 23% of patients had SO2 levels <50%, with a higher prevalence under COT., Conclusions: Our results reveal that CPAP therapy compared with COT may influence rSO2 in patients with acute respiratory failure. However, the cause of the rSO2 increase following CPAP application remains to be elucidated, and the accuracy of cerebral oximetry during CPAP therapy in patients with acute respiratory failure remains questionable.

Published

2019

42. Effect of Intraoperative High Positive End-Expiratory Pressure (PEEP) With Recruitment Maneuvers vs Low PEEP on Postoperative Pulmonary Complications in Obese Patients: A Randomized Clinical Trial.

Author

Bluth T, Serpa Neto A, Schultz MJ, Pelosi P, Gama de Abreu M, Bluth T, Bobek I, Canet JC, Cinnella G, de Baerdemaeker L, Gama de Abreu M, Gregoretti C, Hedenstierna G, Hemmes SNT, Hiesmayr M, Hollmann MW, Jaber S, Laffey J, Licker MJ, Markstaller K, Matot I, Mills GH, Mulier JP, Pelosi P, Putensen C, Rossaint R, Schmitt J, Schultz MJ, Senturk M, Serpa Neto A, Severgnini P, Sprung J, Vidal Melo MF, and Wrigge H

Subjects

Adult, Anesthesia, General, Body Mass Index, Female, Humans, Lung Diseases etiology, Male, Middle Aged, Pleural Diseases etiology, Pleural Diseases prevention & control, Pulmonary Atelectasis therapy, Respiratory Insufficiency etiology, Respiratory Insufficiency prevention & control, Tidal Volume, Treatment Outcome, Intraoperative Care, Lung Diseases prevention & control, Obesity complications, Positive-Pressure Respiration methods, Postoperative Complications prevention & control, Surgical Procedures, Operative adverse effects

Abstract

Importance: An intraoperative higher level of positive end-expiratory positive pressure (PEEP) with alveolar recruitment maneuvers improves respiratory function in obese patients undergoing surgery, but the effect on clinical outcomes is uncertain., Objective: To determine whether a higher level of PEEP with alveolar recruitment maneuvers decreases postoperative pulmonary complications in obese patients undergoing surgery compared with a lower level of PEEP., Design, Setting, and Participants: Randomized clinical trial of 2013 adults with body mass indices of 35 or greater and substantial risk for postoperative pulmonary complications who were undergoing noncardiac, nonneurological surgery under general anesthesia. The trial was conducted at 77 sites in 23 countries from July 2014-February 2018; final follow-up: May 2018., Interventions: Patients were randomized to the high level of PEEP group (n = 989), consisting of a PEEP level of 12 cm H2O with alveolar recruitment maneuvers (a stepwise increase of tidal volume and eventually PEEP) or to the low level of PEEP group (n = 987), consisting of a PEEP level of 4 cm H2O. All patients received volume-controlled ventilation with a tidal volume of 7 mL/kg of predicted body weight., Main Outcomes and Measures: The primary outcome was a composite of pulmonary complications within the first 5 postoperative days, including respiratory failure, acute respiratory distress syndrome, bronchospasm, new pulmonary infiltrates, pulmonary infection, aspiration pneumonitis, pleural effusion, atelectasis, cardiopulmonary edema, and pneumothorax. Among the 9 prespecified secondary outcomes, 3 were intraoperative complications, including hypoxemia (oxygen desaturation with Spo2 ≤92% for >1 minute)., Results: Among 2013 adults who were randomized, 1976 (98.2%) completed the trial (mean age, 48.8 years; 1381 [69.9%] women; 1778 [90.1%] underwent abdominal operations). In the intention-to-treat analysis, the primary outcome occurred in 211 of 989 patients (21.3%) in the high level of PEEP group compared with 233 of 987 patients (23.6%) in the low level of PEEP group (difference, -2.3% [95% CI, -5.9% to 1.4%]; risk ratio, 0.93 [95% CI, 0.83 to 1.04]; P = .23). Among the 9 prespecified secondary outcomes, 6 were not significantly different between the high and low level of PEEP groups, and 3 were significantly different, including fewer patients with hypoxemia (5.0% in the high level of PEEP group vs 13.6% in the low level of PEEP group; difference, -8.6% [95% CI, -11.1% to 6.1%]; P < .001)., Conclusions and Relevance: Among obese patients undergoing surgery under general anesthesia, an intraoperative mechanical ventilation strategy with a higher level of PEEP and alveolar recruitment maneuvers, compared with a strategy with a lower level of PEEP, did not reduce postoperative pulmonary complications., Trial Registration: ClinicalTrials.gov Identifier: NCT02148692.

Published

2019

43. PO 2 oscillations induce lung injury and inflammation.

Author

Boehme S, Hartmann EK, Tripp T, Thal SC, David M, Abraham D, Baumgardner JE, Markstaller K, and Klein KU

Subjects

Animals, Disease Models, Animal, Enzyme-Linked Immunosorbent Assay methods, Female, Germany, Oxygen administration & dosage, Oxygen adverse effects, Oxygen therapeutic use, Partial Pressure, Pneumonia pathology, Pneumonia physiopathology, Respiration, Artificial adverse effects, Respiration, Artificial methods, Respiration, Artificial standards, Respiratory Mechanics physiology, Swine, Ventilator-Induced Lung Injury etiology, Ventilator-Induced Lung Injury pathology, Pneumonia etiology, Ventilator-Induced Lung Injury physiopathology

Abstract

Background: Mechanical ventilation can lead to ventilator-induced lung injury (VILI). In addition to the well-known mechanical forces of volutrauma, barotrauma, and atelectrauma, non-mechanical mechanisms have recently been discussed as contributing to the pathogenesis of VILI. One such mechanism is oscillations in partial pressure of oxygen (PO 2 ) which originate in lung tissue in the presence of within-breath recruitment and derecruitment of alveoli. The purpose of this study was to investigate this mechanism's possible independent effects on lung tissue and inflammation in a porcine model., Methods: To separately study the impact of PO 2 oscillations on the lungs, an in vivo model was set up that allowed for generating mixed-venous PO 2 oscillations by the use of veno-venous extracorporeal membrane oxygenation (vvECMO) in a state of minimal mechanical stress. While applying the identical minimal-invasive ventilator settings, 16 healthy female piglets (weight 50 ± 4 kg) were either exposed for 6 h to a constant mixed-venous hemoglobin saturation (S mv O 2 ) of 65% (which equals a P mv O 2 of 41 Torr) (control group), or an oscillating S mv O 2 (intervention group) of 40-90% (which equals P mv O 2 oscillations of 30-68 Torr)-while systemic normoxia in both groups was maintained. The primary endpoint of histologic lung damage was assessed by ex vivo histologic lung injury scoring (LIS), the secondary endpoint of pulmonary inflammation by qRT-PCR of lung tissue. Cytokine concentration of plasma was carried out by ELISA. A bioinformatic microarray analysis of lung samples was performed to generate hypotheses about underlying pathomechanisms., Results: The LIS showed significantly more severe damage of lung tissue after exposure to PO 2 oscillations compared to controls (0.53 [0.51; 0.58] vs. 0.27 [0.23; 0.28]; P = 0.0025). Likewise, a higher expression of TNF-α (P = 0.0127), IL-1β (P = 0.0013), IL-6 (P = 0.0007), and iNOS (P = 0.0013) in lung tissue was determined after exposure to PO 2 oscillations. Cytokines in plasma showed a similar trend between the groups, however, without significant differences. Results of the microarray analysis suggest that inflammatory (IL-6) and oxidative stress (NO/ROS) signaling pathways are involved in the pathology linked to PO 2 oscillations., Conclusions: Artificial mixed-venous PO 2 oscillations induced lung damage and pulmonary inflammation in healthy animals during lung protective ventilation. These findings suggest that PO 2 oscillations represent an independent mechanism of VILI.

Published

2019

44. Intermittent Hypoxia Activates Duration-Dependent Protective and Injurious Mechanisms in Mouse Lung Endothelial Cells.

Author

Wohlrab P, Soto-Gonzales L, Benesch T, Winter MP, Lang IM, Markstaller K, Tretter V, and Klein KU

Abstract

Intermittent hypoxia is a major factor in clinical conditions like the obstructive sleep apnea syndrome or the cyclic recruitment and derecruitment of atelectasis in acute respiratory distress syndrome and positive pressure mechanical ventilation. In vivo investigations of the direct impact of intermittent hypoxia are frequently hampered by multiple co-morbidities of patients. Therefore, cell culture experiments are important model systems to elucidate molecular mechanisms that are involved in the cellular response to alternating oxygen conditions and could represent future targets for tailored therapies. In this study, we focused on mouse lung endothelial cells as a first frontier to encounter altered oxygen due to disturbances in airway or lung function, that play an important role in the development of secondary diseases like vascular disease and pulmonary hypertension. We analyzed key markers for endothelial function including cell adhesion molecules, molecules involved in regulation of fibrinolysis, hemostasis, redox balance, and regulators of gene expression like miRNAs. Results show that short-time exposure to intermittent hypoxia has little impact on vitality and health of cells. At early timepoints and up to 24 h, many endothelial markers are unchanged in their expression and some indicators of injury are even downregulated. However, in the long-term, multiple signaling pathways are activated, that ultimately result in cellular inflammation, oxidative stress, and apoptosis.

Published

2018

45. Argon preconditioning enhances postischaemic cardiac functional recovery following cardioplegic arrest and global cold ischaemia.

Author

Kiss A, Shu H, Hamza O, Santer D, Tretter EV, Yao S, Markstaller K, Hallström S, Podesser BK, and Klein KU

Subjects

Administration, Inhalation, Animals, Argon administration & dosage, Cardioplegic Solutions administration & dosage, Cardiotonic Agents administration & dosage, Heart drug effects, Male, Myocardial Reperfusion Injury metabolism, Myocardium chemistry, Myocardium metabolism, Rats, Rats, Sprague-Dawley, Signal Transduction drug effects, Argon pharmacology, Cardioplegic Solutions pharmacology, Cardiotonic Agents pharmacology, Heart Arrest, Induced methods, Ischemic Preconditioning, Myocardial methods, Myocardial Reperfusion Injury prevention & control

Abstract

Objectives: Previous studies demonstrated that preconditioning with argon gas provided a marked reduction in inflammation and apoptosis and increased myocardial contractility in the setting of acute myocardial ischaemia-reperfusion (IR). There is substantial evidence that myocardial IR injury following cardioplegic arrest is associated with the enhancement of apoptosis and inflammation, which is considered to play a role in cardiac functional impairment. Therefore, the present study was designed to clarify whether preconditioning with argon gas enhances recovery of cardiac function following cardioplegic arrest., Methods: Sprague-Dawley rats were anaesthetized and ventilated and allocated to (i) the control group (control IR, n = 10) and (ii) the in vivo group (argon IR), which received 3 cycles of argon (50% argon, 21% oxygen and 29% nitrogen, n = 10) administered for 5 min interspersed with 5 min of a gas mixture (79% nitrogen and 21% oxygen). The hearts were excised and then evaluated in an erythrocyte-perfused isolated working heart system. Cold ischaemia (4°C) for 60 min was induced by histidine-tryptophan-ketoglutarate cardioplegia, followed by 40 min of reperfusion. Cardiac functional parameters were assessed. In left ventricular tissue samples, the expressions of extracellular-regulated kinase (ERK1/2), AKT serine/threonine kinase (Akt), jun N-terminal kinase (JNK), endothelial nitric oxide synthase (eNOS) and HMGB1: high-mobility group box 1 (HMGB1) protein were assessed by western blot, and high-energy phosphates were evaluated by high-performance liquid chromatography., Results: At the end of reperfusion, the rats preconditioned with argon showed significantly enhanced recovery of cardiac output (101 ± 6% vs 87 ± 11%; P < 0.01), stroke volume (94 ± 4% vs 80 ± 11%; P = 0.001), external heart work (100 ± 6% vs 81 ± 13%; P < 0.001) and coronary flow (90 ± 13% vs 125 ± 21%; P < 0.01) compared with the control IR group. These results were accompanied by a significant increase in the levels of myocardial phosphocreatine (23.71 ± 2.07 µmol/g protein vs the control IR group, 13.50 ± 4.75; P = 0.001) and maintained adenosine triphosphate levels (13.62 ±1.89 µmol/g protein vs control IR group adenosine triphosphate: 10.08 ± 1.94 µmol/g; P = 0.017). Additionally, preconditioning with argon markedly reduced the activation of JNK (0.11 ± 0.01 vs 0.25 ± 0.03; P = 0.005) and the expression of HMGB1 protein (0.52 ± 0.04 vs 1.5 ± 0.10; P < 0.001) following reperfusion., Conclusions: Preconditioning with argon enhanced cardiac functional recovery in rat hearts arrested with histidine-tryptophan-ketoglutarate cardioplegia, thereby representing a potential novel cardioprotective approach in cardiac surgery.

Published

2018

46. Pretreatment With Argon Protects Human Cardiac Myocyte-Like Progenitor Cells from Oxygen Glucose Deprivation-Induced Cell Death by Activation of AKT and Differential Regulation of Mapkinases.

Author

Qi H, Soto-Gonzalez L, Krychtiuk KA, Ruhittel S, Kaun C, Speidl WS, Kiss A, Podesser BK, Yao S, Markstaller K, Klein KU, and Tretter V

Subjects

Animals, Apoptosis drug effects, Extracellular Signal-Regulated MAP Kinases metabolism, Flow Cytometry, Humans, In Situ Nick-End Labeling, JNK Mitogen-Activated Protein Kinases metabolism, L-Lactate Dehydrogenase metabolism, Rabbits, Signal Transduction drug effects, Argon pharmacology, Myocytes, Cardiac cytology, Myocytes, Cardiac drug effects, Proto-Oncogene Proteins c-akt metabolism, Stem Cells cytology, Stem Cells drug effects

Abstract

Background: The noble gas argon induces cardioprotection in a rabbit model of myocardial ischemia and reperfusion. However, no studies in human primary cells or subjects have been performed so far. We used human cardiac myocyte-like progenitor cells (HCMs) to investigate the protective effect on the cellular level., Methods: HCMs were pretreated with 30% or 50% argon before oxygen-glucose deprivation (OGD) and reperfusion. We evaluated apoptotic states by flow cytometry and the activation of mitogen-activated protein kinase (MAPKs) members extracellular signal-regulated kinase (ERK), c-jun N-terminal kinase (JNK), p38 MAPkinase, and protein kinase B (Akt) by Westernblot analysis and by activity assays of downstream transcription factors. Specific inhibitors were used to proof a significant participation of these pathways in the protection by argon. Beneficial effects were further assessed by TdT-mediated dUTP-biotin nick end labeling (TUNEL) assay, lactate dehydrogenase (LDH), mitochondrial deoxyribonucleic acid (mtDNA), and cytokine release., Results: Pretreatment with 30% or 50% argon for 90 min before OGD resulted in a significant protection of HCMs against apoptosis. This effect was reversed by the application of MAPK and Akt inhibitors during argon exposure. Argon 30% reduced the release of LDH by 33% and mtDNA by 45%. The release of interleukin 1β was reduced by 44% after OGD and more than 90% during reperfusion., Conclusions: Pretreatment with argon protects HCMs from apoptosis under ischemic conditions via activation of Akt, Erk, and biphasic regulation of JNK. Argon gas is cheap and easily administrable, and might be a novel therapy to reduce myocardial ischemia-reperfusion injury.

Published

2018

47. Recent advances in understanding acute respiratory distress syndrome.

Author

Wohlrab P, Kraft F, Tretter V, Ullrich R, Markstaller K, and Klein KU

Abstract

Acute respiratory distress syndrome (ARDS) is characterized by acute diffuse lung injury, which results in increased pulmonary vascular permeability and loss of aerated lung tissue. This causes bilateral opacity consistent with pulmonary edema, hypoxemia, increased venous admixture, and decreased lung compliance such that patients with ARDS need supportive care in the intensive care unit to maintain oxygenation and prevent adverse outcomes. Recently, advances in understanding the underlying pathophysiology of ARDS led to new approaches in managing these patients. In this review, we want to focus on recent scientific evidence in the field of ARDS research and discuss promising new developments in the treatment of this disease., Competing Interests: Competing interests: None of the authors has to declare any conflict of interest with regard to the present F1000 review. Roman Ullrich received funding from Apeptico GmbH (Vienna, Austria) using funds from grant no. 833159 of the Austrian Research Promotion Agency (FFG) to perform a clinical study investigating AP301 (cited in text PMID: 28750677).No competing interests were disclosed.No competing interests were disclosed.

Published

2018

48. Detection of inspiratory recruitment of atelectasis by automated lung sound analysis as compared to four-dimensional computed tomography in a porcine lung injury model.

Author

Boehme S, Toemboel FPR, Hartmann EK, Bentley AH, Weinheimer O, Yang Y, Achenbach T, Hagmann M, Kaniusas E, Baumgardner JE, and Markstaller K

Subjects

Animals, Area Under Curve, Disease Models, Animal, Four-Dimensional Computed Tomography methods, Lung physiopathology, Monitoring, Physiologic standards, Pulmonary Atelectasis physiopathology, ROC Curve, Respiration, Artificial methods, Swine, Ventilator-Induced Lung Injury prevention & control, Inhalation physiology, Monitoring, Physiologic methods, Pulmonary Atelectasis diagnosis, Respiration, Artificial standards, Respiratory Sounds

Abstract

Background: Cyclic recruitment and de-recruitment of atelectasis (c-R/D) is a contributor to ventilator-induced lung injury (VILI). Bedside detection of this dynamic process could improve ventilator management. This study investigated the potential of automated lung sound analysis to detect c-R/D as compared to four-dimensional computed tomography (4DCT)., Methods: In ten piglets (25 ± 2 kg), acoustic measurements from 34 thoracic piezoelectric sensors (Meditron ASA, Norway) were performed, time synchronized to 4DCT scans, at positive end-expiratory pressures of 0, 5, 10, and 15 cmH 2 O during mechanical ventilation, before and after induction of c-R/D by surfactant washout. 4DCT was post-processed for within-breath variation in atelectatic volume (Δ atelectasis) as a measure of c-R/D. Sound waveforms were evaluated for: 1) dynamic crackle energy (dCE): filtered crackle sounds (600-700 Hz); 2) fast Fourier transform area (FFT area): spectral content above 500 Hz in frequency and above -70 dB in amplitude in proportion to the total amount of sound above -70 dB amplitude; and 3) dynamic spectral coherence (dSC): variation in acoustical homogeneity over time. Parameters were analyzed for global, nondependent, central, and dependent lung areas., Results: In healthy lungs, negligible values of Δ atelectasis, dCE, and FFT area occurred. In lavage lung injury, the novel dCE parameter showed the best correlation to Δ atelectasis in dependent lung areas (R 2 = 0.88) where c-R/D took place. dCE was superior to FFT area analysis for each lung region examined. The analysis of dSC could predict the lung regions where c-R/D originated., Conclusions: c-R/D is associated with the occurrence of fine crackle sounds as demonstrated by dCE analysis. Standardized computer-assisted analysis of dCE and dSC seems to be a promising method for depicting c-R/D.

Published

2018

49. Treatment of primary graft dysfunction after lung transplantation with orally inhaled AP301: A prospective, randomized pilot study.

Author

Aigner C, Slama A, Barta M, Mitterbauer A, Lang G, Taghavi S, Matilla J, Ullrich R, Krenn K, Jaksch P, Markstaller K, and Klepetko W

Abstract

Background: Primary graft dysfunction (PGD) after lung transplantation (LTx) carries significant morbidity and mortality in the early post-operative period and is associated with the development of chronic lung allograft dysfunction. AP301, an activator of epithelial sodium channel-mediated Na + uptake represents a new concept for prevention and treatment of pulmonary edema and has shown promising results in the pre-clinical setting. This pilot study investigated the clinical effect of inhaled AP301 on patients with development of PGD > 1 according to International Society of Heart and Lung Transplantation criteria after primary LTx in a high-volume center and was conducted as a randomized, placebo-controlled, single-center pilot-study including 20 patients. All consecutive patients fulfilling inclusion criteria were screened for PGD at arrival on the intensive care unit (ICU) after LTx. After randomization, inhaled AP301 or placebo was administered by nebulizer twice daily for 7 days or until extubation. Otherwise, patients were treated according to routine clinical protocol. Partial pressure of arterial oxygen (Pao 2 )/fraction of inspired oxygen (Fio 2 ) values were obtained until extubation and assessed as a primary outcome parameter. Patients were monitored for 30 days within the study protocol., Results: From July 2013 to August 2014, 20 patients were randomized 1:1 to AP301 (Group 1) or placebo (Group 2). Both groups were comparable with regard to sex (40% women/60% men vs 50% women/50% men), mean age (55 ± 13 vs 54 ± 6 years), comorbidities, and diagnosis leading to LTx. The Pao 2 /Fio 2 ratio at the time of inclusion was comparable in both groups, with a mean 235.65 ± 90.78 vs 214.2 ± 95.84 (p = 0.405), and there was no significant difference in the extravascular lung water index (13.88 ± 5.28 vs 16 ± 6.29 ml/kg, p = 0.476). The primary end point was mean Pao 2 /Fio 2 ratio values between baseline and Day 3. In the AP301 group, only 1 patient was ventilated at Day 4 and no patients were ventilated after Day 4. In the placebo group, 5 patients were ventilated on Day 4 and 2 patients on Days 5, 6, and 7. The mean increase in the Pao 2 /Fio 2 ratio was significantly higher in Group 1 patients, and the mean between baseline and at 72 hours was 365.6 ± 90.4 in Group 1 vs 335.2 ± 42.3 in Group 2 (p = 0.049). The duration of intubation was shorter in Group 1 than in Group 2 patients (2 ± 0.82 vs 3.7 ± 1.95 days; p = 0.02). ICU stay was 7.5 ± 3.13 days in Group 1 vs 10.8 ± 8.65 days in group 2 (p = 0.57). Survival at 30 days was 100%. No severe adverse events were recorded., Conclusions: This study was designed as a proof-of-concept pilot study. Although it was not powered to achieve statistical significances, the study demonstrated relevant clinical effects of inhaled AP301 on patients with PGD after primary LTx. The improved gas exchange led to a significantly shorter duration of mechanical ventilation and a trend towards a shorter ICU stay. Further investigation of AP301 for treatment of PGD in larger studies is warranted., Trial Registration: The trial is registered at https://www.clinicaltrialsregister.eu/ctr-search/trial/2013-000716-21/AT., (Copyright © 2017 International Society for the Heart and Lung Transplantation. Published by Elsevier Inc. All rights reserved.)

Published

2017

50. Inhaled AP301 for treatment of pulmonary edema in mechanically ventilated patients with acute respiratory distress syndrome: a phase IIa randomized placebo-controlled trial.

Author

Krenn K, Lucas R, Croizé A, Boehme S, Klein KU, Hermann R, Markstaller K, and Ullrich R

Subjects

Administration, Inhalation, Adult, Aged, Double-Blind Method, Female, Humans, Lung drug effects, Male, Middle Aged, Organ Dysfunction Scores, Peptides, Cyclic therapeutic use, Pulmonary Edema etiology, Respiration, Artificial methods, Peptides, Cyclic pharmacology, Pulmonary Edema drug therapy, Respiratory Distress Syndrome complications

Abstract

Background: High-permeability pulmonary edema is a hallmark of acute respiratory distress syndrome (ARDS) and is frequently accompanied by impaired alveolar fluid clearance (AFC). AP301 enhances AFC by activating epithelial sodium channels (ENaCs) on alveolar epithelial cells, and we investigated its effect on extravascular lung water index (EVLWI) in mechanically ventilated patients with ARDS., Methods: Forty adult mechanically ventilated patients with ARDS were included in a randomized, double-blind, placebo-controlled trial for proof of concept. Patients were treated with inhaled AP301 (n = 20) or placebo (0.9% NaCl; n = 20) twice daily for 7 days. EVLWI was measured by thermodilution (PiCCO®), and treatment groups were compared using the nonparametric Mann-Whitney U test., Results: AP301 inhalation was well tolerated. No differences in mean baseline-adjusted change in EVLWI from screening to day 7 were found between the AP301 and placebo group (p = 0.196). There was no difference in the PaO 2 /FiO 2 ratio, ventilation pressures, Murray lung injury score, or 28-day mortality between the treatment groups. An exploratory subgroup analysis according to severity of illness showed reductions in EVLWI (p = 0.04) and ventilation pressures (p < 0.05) over 7 days in patients with initial sequential organ failure assessment (SOFA) scores ≥11 inhaling AP301 versus placebo, but not in patients with SOFA scores ≤10., Conclusions: There was no difference in mean baseline-adjusted EVLWI between the AP301 and placebo group. An exploratory post-hoc subgroup analysis indicated reduced EVLWI in patients with SOFA scores ≥11 receiving AP301. These results suggest further confirmation in future clinical trials of inhaled AP301 for treatment of pulmonary edema in patients with ARDS., Trial Registration: The study was prospectively registered at clinicaltrials.gov, NCT01627613 . Registered 20 June 2012.

Published

2017