Life span of different extracorporeal membrane systems for severe respiratory failure in the clinical practice

Philipp, Alois; Somer, Filip De; Foltan, Maik; Bredthauer, Andre; Krenkel, Lars; Zeman, Florian; Lehle, Karla

doi:10.1371/journal.pone.0198392

Cited by 28 publications

(30 citation statements)

References 25 publications

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“…For the RotaFlow device, the permanent-life-support system was used and for the CardioHelp system the HLS Set Advanced was used. Both systems were manufactured by Getinge, were Bioline-coated and possessed equivalent durability [ 11 ]. Patients were identified via established ECMO databases at both sites.…”

Section: Methodsmentioning

confidence: 99%

Comparison of anticoagulation strategies for veno-venous ECMO support in acute respiratory failure

et al. 2020

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Background Extracorporeal membrane oxygenation (ECMO) support in acute respiratory failure may be lifesaving, but bleeding and thromboembolic complications are common. The optimal anticoagulation strategy balancing these factors remains to be determined. This retrospective study compared two institutional anticoagulation management strategies focussing on oxygenator changes and both bleeding and thromboembolic events. Methods We conducted a retrospective observational cohort study between 04/2015 and 02/2020 in two ECMO referral centres in Germany in patients receiving veno-venous (VV)-ECMO support for acute respiratory failure for > 24 h. One centre routinely applied low-dose heparinization aiming for a partial thromboplastin time (PTT) of 35–40 s and the other routinely used a high-dose therapeutic heparinization strategy aiming for an activated clotting time (ACT) of 140–180 s. We assessed number of and time to ECMO oxygenator changes, 15-day freedom from oxygenator change, major bleeding events, thromboembolic events, 30-day ICU mortality, activated clotting time and partial thromboplastin time and administration of blood products. Primary outcome was the occurrence of oxygenator changes depending on heparinization strategy; main secondary outcomes were the occurrence of severe bleeding events and occurrence of thromboembolic events. The transfusion strategy was more liberal in the low-dose centre. Results Of 375 screened patients receiving VV-ECMO support, 218 were included in the analysis (117 high-dose group; 101 low-dose group). Disease severity measured by SAPS II score was 46 (IQR 36–57) versus 47 (IQR 37–55) and ECMO runtime was 8 (IQR 5–12) versus 11 (IQR 7–17) days (P = 0.003). There were 14 oxygenator changes in the high-dose group versus 48 in the low-dose group. Freedom from oxygenator change at 15 days was 73% versus 55% (adjusted HR 3.34 [95% confidence interval 1.2–9.4]; P = 0.023). Severe bleeding events occurred in 23 (19.7%) versus 14 (13.9%) patients (P = 0.256) and thromboembolic events occurred in 8 (6.8%) versus 19 (19%) patients (P = 0.007). Mortality at 30 days was 33.3% versus 30.7% (P = 0.11). Conclusions In this retrospective study, ECMO management with high-dose heparinization was associated with lower rates of oxygenator changes and thromboembolic events when compared to a low-dose heparinization strategy. Prospective, randomized trials are needed to determine the optimal anticoagulation strategy in patients receiving ECMO support.

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Section: Methodsmentioning

confidence: 99%

Comparison of anticoagulation strategies for veno-venous ECMO support in acute respiratory failure

et al. 2020

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“…Third, the oxygenator was manufactured using 3D printing, which allows a smaller prime volume and greater reproducibility. The commercially available Micro1 (Kewei Medical Instrument Inc., China) has a surface area of 0.05 m 2 and requires a 3.5 mL priming volume [25,30,32,33]. Similarly, commercially available HPO-003 (Senko Medical Co., Ltd, Japan) has a surface area of 0.03 m 2 and a 3.3 mL priming volume but utilizes blood ow inside bers, unlike current ECMO oxygenators [24].…”

Section: Discussionmentioning

confidence: 99%

“…Despite advancements in ECMO technology over the last decade, currently available commercial oxygenators last for only a few weeks due to thrombus formation [2][3][4][5]. While anticoagulation can be used to slow thrombus formation, its use must be signi cantly limited to avoid bleeding complications [1,4,5].…”

Section: Introductionmentioning

confidence: 99%

Establishment and Evaluation of a Rat Model of Extracorporeal Membrane Oxygenation (ECMO) Thrombosis Using a 3D-printed Mock Oxygenator

Umei¹,

Lai²,

Miller³

et al. 2021

Preprint

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Background: Extracorporeal membrane oxygenation (ECMO) research using large animals requires a significant amount of resources, slowing down the development of new means of ECMO anticoagulation. Therefore, this study developed and evaluated a new rat ECMO model using a 3D-printed mock oxygenator.Methods: The circuit consisted of tubing, a 3D-printed mock oxygenator, and a roller pump. The mock oxygenator was designed to simulate the geometry and blood flow patterns of the fiber bundle in full-scale oxygenators but with a low (2.5 mL) priming volume. Rats were placed on arteriovenous ECMO at a 1.9 mL/min flow rate at two different heparin doses (n = 3 each): low (15 IU/kg/h for eight hours) versus high (50 IU/kg/h for one hour followed by 25 IU/kg/h for seven hours). The experiment continued for eight hours or until the mock oxygenator failed. The mock oxygenator was considered to have failed when its blood flow resistance reached three times its baseline resistance.Results: During ECMO, rats maintained near-normal mean arterial pressure and arterial blood gases with minimal hemodilution. The mock oxygenator thrombus weight was significantly different (p < 0.05) between the low (0.02 ± 0.006 g) and high (0.003 ± 0.001 g) heparin delivery groups, and blood flow resistance was also larger in the low anticoagulation group.Conclusions: This model is a simple, inexpensive system for investigating new anticoagulation agents for ECMO and provides low and high levels of anticoagulation that can serve as control groups for future studies.

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“…If flow through these short, preferential pathways increases, the low flow areas will receive even less flow and are thus even more prone to clot development. 7 , 8 Clotting, in turn, adds to the decreased gas transfer efficiency by blocking part of the gas transfer membrane and might eventually lead to oxygenator failure necessitating oxygenator exchange, clot embolism or coagulation disorders. 9 – 12 …”

Section: Discussionmentioning

confidence: 99%

The effect of flow and pressure on the intraoxygenator flow path of different contemporary oxygenators: an in vitro trial

et al. 2020

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Introduction: This study analyzed the effect of different flows and pressures on the intraoxygenator flow path in three contemporary oxygenators and its consequences for oxygen transfer efficiency. Methods: In an experimental setup, intraoxygenator flow path parameters were analyzed at post-oxygenator pressures of 150, 200, and 250 mm Hg and at flows ranging from 2 L/min to the oxygenators’ maximum permitted flow, with and without pulsatility. The oxygen gradient and the oxygen transfer per minute and per 100 mL blood were calculated using previously collected clinical data and compared with the flow path parameters. Results: Increasing pressure did not affect the flow path parameters, whereas pulsatile flow led to significantly increased dynamic oxygenator blood volumes. Increased flow resulted in decreased values of the flow path parameters in all oxygenators, indicating increased flow through short pathways in the oxygenator. In parallel, oxygen transfer/100 mL blood decreased in all oxygenators (average 2.5 ± 0.4 to 2.4 ± 0.3 mL/dL, p > 0.001) and the oxygen gradient increased from 229 ± 45 to 287 ± 29 mm Hg, p > 0.001, indicating decreased oxygen transfer efficiency. Oxygen transfer/min increased (101 ± 15 to 143 ± 20 mL/min/m2, p > 0.001), however, due to the increased flow through the oxygenator. Conclusion: Varying trans-membrane oxygenator pressures did not lead to changes in the intraoxygenator flow path, while an increased flow exhibited lower flow path parameters resulting in less efficient use of the gas exchange compartment. The latter was confirmed by a decrease in O2 transfer efficiency during higher blood flows.

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Life span of different extracorporeal membrane systems for severe respiratory failure in the clinical practice

Cited by 28 publications

References 25 publications

Comparison of anticoagulation strategies for veno-venous ECMO support in acute respiratory failure

Comparison of anticoagulation strategies for veno-venous ECMO support in acute respiratory failure

Establishment and Evaluation of a Rat Model of Extracorporeal Membrane Oxygenation (ECMO) Thrombosis Using a 3D-printed Mock Oxygenator

The effect of flow and pressure on the intraoxygenator flow path of different contemporary oxygenators: an in vitro trial

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