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. 2021 Jan 4;24:701. doi: 10.1186/s13054-020-03348-w

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

Benjamin Seeliger 1,#, Michael Döbler 2,#, Robert Friedrich 1, Klaus Stahl 3, Christian Kühn 4, Johann Bauersachs 5, Folkert Steinhagen 2, Stefan F Ehrentraut 2, Jens-Christian Schewe 2, Christian Putensen 2, Tobias Welte 1, Marius M Hoeper 1, Andreas Tiede 6, Sascha David 7,8,✉,#, Christian Bode 2,✉,#
PMCID: PMC7780376  PMID: 33397427

Abstract

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.

Keywords: ECMO, Heparinization, ARDS, Bleeding, Thromboembolism

Introduction

In refractory acute respiratory failure (ARF), implementation of veno-venous extracorporeal membrane oxygenation (VV-ECMO) as a rescue strategy may be life-saving and is increasingly applied [1]. However, ECMO support is associated with potentially life-threatening complications, mostly related to either bleeding events or thromboembolic complications [24]. To minimize such events, most centres use unfractionated heparin (UFH)-based anticoagulation adjusted by partial thromboplastin time (PTT), usually within 40–80 s or by activated clotting time (ACT) within 140–180 s [5]. Current guidelines advice an ACT-guided approach aiming at 1.5 fold increase of normal [6]. With bleeding complications occurring in up to 50% of patients, there is a quest for alternative anticoagulatory strategies without compromising integrity of the ECMO circuits and risk of thromboembolism [2]. Previous studies found lower heparin dosing to be generally safe with regards to thromboembolic complications but conclusions are limited by small patient numbers [79].

Our study aimed to retrospectively compare oxygenator durability, bleeding and thromboembolic events between two experienced ECMO centres with considerably different routine anticoagulation strategies but identical oxygenator change management. We hypothesized, that a strategy including low-dose heparin strategy would result in similar oxygenator durability and similar thromboembolic complications while reducing bleeding events compared to a high-dose strategy.

Methods

Design, settings and participants

We conducted a retrospective cohort study including patients with severe ARF receiving VV-ECMO support between April 2015 and February 2020 at two German university hospitals with extensive ECMO experience. Both centres routinely used UFH-based anticoagulation, but with different intensity, thus enabling us to compare a low-dose heparinization strategy aiming for a PTT between 35 and 40 s (measured thrice per day using the actin FS assay by Siemens) with a high-dose heparinization strategy aiming for an ACT between 140 and 180 s (measured every 2 h). In the high-dose-group, PTT was measured once daily using the Pathrombin SL assay, with both tests showing excellent correlation [10]. ECMO systems used were Getinge/Maquet RotaFlow or CardioHelp with cannulation of the internal jugular and/or femoral veins via 19–25 French cannulas. Standard cannulation in the high-dose centre was femoral/jugular venous access, while in the low-dose centre a bi-femoral venous access was mostly established. 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. Inclusion criteria were VV-ECMO support ≥ 24 h and provided written informed consent by patients or proxy for analysis of clinical data. Exclusion criteria were duration of VV-ECMO support < 24 h; external ECMO support > 24 h before referral; addition of a third (arterial) cannula within 24 h; age < 18 years; acute liver failure with relevant coagulopathy precluding heparin administration; missing informed consent and medical indication for high-dose anticoagulation in the low-dose centre. The study was approved by the institutional review boards at both sites.

Endpoints

The primary endpoint was ECMO oxygenator change within the first 15 days. Secondary endpoints were 30-day ICU mortality, severe bleeding complications (defined as need for intervention or ≥ 10 red blood cell (RBC) transfusions), symptomatic thromboembolic events, number of platelet and RBC transfusions during ECMO, administered units of UFH during ECMO and coagulation studies (mean ACT in the high-dose-group, mean PTT in both groups).

Transfusion strategies

Absent of overt bleeding, the routine threshold for RBC transfusion at the high-dose centre was a haemoglobin level < 8 g/dL versus < 9 g/dL in the low-dose group. Routine threshold for platelet transfusions were < 30.000/µL in the high-dose centre versus 70.000/µL in the low-dose centre. With overt bleeding, the routine thresholds for platelet transfusion were 50.000/µL (high-dose centre) versus 100.000/µL (low-dose centre) but could be individualized depending on the clinical scenario, severity and site of bleeding. Antithrombin III was substituted if antithrombin III levels were < 50% and antifibrinolytic agents administered in cases of clinical suspicion of hyperfibrinolysis or proof by thromboelastography. Bleeding management regarding administration of prothrombin complex concentrates was adjusted by event severity at the discretion of the treating physicians and was not standardized in both centres.

Indication for oxygenator changes

Oxygenator change was considered in the settings of decreasing post-filter pO2 < 200 mmHg with increasing transmembrane pressure gradient (with the CardioHelp system), overt circuit thrombosis with thrombi > 5 mm, rising D-dimers with progressive thrombocytopenia and hyperfibrinolysis with increasing transmembrane pressure gradient, and otherwise unexplained haemolysis with increasing transmembrane pressure gradient.

Covariates

Age, admission and discharge dates to ICU, underlying reason for ARF, body-mass-index, pre-existing antiplatelet therapy and comorbidities were obtained from charts. Simplified acute physiology score (SAPS) II [12] at day of ECMO implantation, Respiratory ECMO Survival Prediction (RESP) score [13], sequential organ failure assessment score (SOFA) [14], heparin doses, ECMO devices and settings and coagulation studies were extracted from the clinical patient data management system.

Statistical analysis

Continuous data was assessed for normal distribution by Shapiro–Wilk-test and group comparison was performed using t-test or rank-sum test, as appropriate. Hazard ratios for freedom from oxygenator change at 15 days was calculated using a multivariable cox regression. Covariables were selected if baseline values were significantly unbalanced between the groups or if they were overtly physiologically linked to the outcome. We did not include number of blood product transfusions and ECMO device since they were not independent factors but part of the institutional strategy. The final model included age, sex, BMI, RESP Score, SAPS II score, SOFA renal sub-score, ECMO runtime, sepsis, pre-existing coronary artery disease, prior treatment with aspirin, mean ECMO flow and baseline fibrinogen, d-dimers and antithrombin III levels as covariables. Analyses were performed using STATA V16.0 (STATA Corp LP) and RStudio V1.2.5033 (RStudio Inc).

Results

Patient characteristics

At screening, 375 patients receiving VV-ECMO support for ARF were identified. A total of 218 patients were included in the analysis (117 high-dose group vs. 101 low-dose group), with details on exclusions provided in Fig. 1. The baseline characteristics are shown in Table 1. ECMO settings and associated laboratory are shown in Table 2. The causes of ARF according the RESP score were viral pneumonia (22.5%), bacterial pneumonia (30.3%), status asthmaticus (1.8%), trauma/burn (1.8%), aspiration pneumonia (7.8%), other acute respiratory causes (28.9%) and non-respiratory or chronic respiratory causes (6.8%) and were distributed homogenously among the groups (p = 0.359). Patients in the high-dose group were younger (46 years [IQR 29–55] vs. 54 years [interquartile range (IQR) 44–62], P < 0.001) and had a lower BMI (26.2 kg/m2 [IQR 22.5–29.4] vs. 29.1 [IQR 26.0–33.2], P < 0.001. Sepsis was less frequently present in the high-dose group (75.2 vs. 95.1%, P < 0.001), and primary ARDS was more common in the high-dose group (88.9 vs. 68.3%, P < 0.001). While the SAPS-II score at day of ECMO implantation was comparable between the groups, the RESP-score was higher in the high-dose group (1 [IQR – 1 to 3] vs. −0 [−2 to 3], P = 0.002).

Fig. 1.

Fig. 1

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Flow chart for patient cohorts by centre / heparinization strategy. The need for written informed consent at the low-dose centre was waved by the institutional review board due to the retrospective nature of the study

Table 1.

Baseline characteristics

ALL
( n = 218)		 High-dose group
( n = 117)		 Low-dose group
( n = 101)		 P value
Baseline Characteristics
 Gender, n (%), male 153 (70.2) 85 (72.6) 68 (67.3) 0.392
 Age, median (IQR), years 49 (38–60) 46 (29–55) 54 (44–62)  < 0.001
 BMI, median (IQR), kg/m2 27.7 (24.2–30.9) 26.2 (22.5–29.4) 29.1 (26.0–33.2)  < 0.001
 SAPS II (IQR) 47 (37–56) 46 (36–57) 47 (37–55) 0.871
 SOFA Score (IQR) 9 (8–10) 9 (7–10) 9 (8–10) 0.650
  Respiration-sub-score 4 4 4
  Coagulation-sub-score 0 (0–1) 0 (0–1) 0 (0–2) 0.573
  Liver-sub-score 0 (0–1) 0 (0–2) 0 (0–1) 0.059
  Cardiovascular-sub-score 4 (3–4) 4 (3–4) 4 (3–4) 0.151
  Renal-sub-score 1 (0–4) 1 (0–4) 1 (0–2) 0.004
 RESP-Score (IQR) 1 (-2–3)) 1 (-1–3) 0 (-2–3) 0.002
 Sepsis, n (%) 184 (84.4) 88 (75.2) 96 (95.1)  < 0.001
 Primary ARDS, n (%) 173 (79.4) 104 (88.9) 69 (68.3)  < 0.001
 Immunocompromised, n (%) 68 (31.2) 31 (26.5) 37 (36.6) 0.107
 Liver failure* 53 (24.3) 34 (29.1) 19 (18.8) 0.079
Comorbidities, n (%)
  Diabetes mellitus 42 (19.4) 19 (16.4) 23 (22.8) 0.234
  Arterial hypertension 76 (35.0) 34 (29.3) 42 (41.6) 0.059
  Coronary artery disease 21 (9.6) 7 (6.0) 14 (13.9) 0.049
  Malignancy (solid) 8 (3.7) 2 (1.7) 6 (5.9) 0.098
  Malignancy (Hematologic) 14 (6.4) 8 (6.8) 6 (5.9) 0.788
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ARDS acute respiratory distress syndrome, BMI Body mass index, ECMO extracorporeal membrane oxygenation, IQR interquartile range, RESP Respiratory ECMO Survival Prediction score, SAPS II Simplified acute physiology score II, SOFA sequential organ failure assessment

*Defined by sequential organ failure assessment liver subscore of ≥ 2

Table 2.

ECMO settings and relevant coagulation factors

ALL
( n = 218)		 High-dose group
( n = 117)		 Low-dose group
( n = 101)		 P value
ECMO device  < 0.001
 CardioHelp 31 (26.5) 99 (98)
 RotaFlow 86 (73.5) 2 (2)
Canula site out
 Jugular vein 3 (1.4) 3 (2.6) 0
 Femoral vein 215 (98.6) 114 (97.4) 101 (100)
Canula site in
 Jugular vein 135 (61.9) 113 (96.6) 22 (21.8)
 Subclavian vein 2 (0.9) 2 (1.7) 0
 Femoral vein 81 (37.2) 2 (1.7) 79 (78.2)
Canula size out 23 (23–35) 23 (23–23) 25 (25–25)  < 0.001
Canula size in 17 (17–23) 17 (17–17) 23 (21–25)  < 0.001
ECMO runtime, median (IQR), days 9 (5–14) 8 (5–12) 11 (7–17) 0.003
ECMO flow, median (IQR), liter per minute 3.8 (3.3–4.4) 3.5 (2.8–3.9) 4.4 (3.8–4.9)  < 0.001
Days from mechanical ventilation to ECMO implantation, median (ICR) 1 (0–3) 1 (0–3) 1 (0–4) 0.185
Antiplatelet therapy pre-ECMO
Aspirin 31 (14) 13 (11) 18 (18) 0.157
P2Y12-inhibitors 6 (3) 2 (2) 4 (4) 0.311
Antiplatelet therapy during ECMO, n (%)
Aspirin 27 (12) 9 (8) 18 (18) 0.024
P2Y12-inhibitors 5 (2) 0 5 (5) 0.015
Baseline fibrinogen, g/L (IQR) 4.7 (3.3–6.2) 6.7 (3.3–6.4) 4.8 (3.4–6.1) 0.611
Minimal fibrinogen, g/L (IQR) 2.2 (1.4–3.4) 2.5 (1.6–3.5) 2.0 (1.2–3.4) 0.030
Baseline d-dimers, mg/L (IQR) 7.6 (3.6–15.4) 5.4 (2.6–12.7) 8.3 (4.4–16.5) 0.010
Maximum d-dimers, mg/L (IQR) 30 (19.3–35) 28.5 (13–30) 35 (33.4–35)  < 0.001
Baseline antithrombin III, % (IQR) 67 (53–86) 79 (60–93) 60 (44–75)  < 0.001
Minimum antithrombin III, % (IQR) 59 (45–76) 69 (56–84) 48 (37–62)  < 0.001
Antithrombin III substitution, n (%) 29 (13.3) 8 (6.8) 21 (21) 0.002
Baseline thrombocyte count, thousand / µL (IQR) 174 (101–265) 167 (109–269) 183 (97–263) 0.878
Minimum thrombocyte count, thousand / µL (IQR) 62 (36–88) 65 (33–106) 60 (40–81) 0.868
Received PCC, n (%) 36 (16.5) 8 (6.8) 26 (25.7)  < 0.001
Received tranexamic acid, n (%) 113 (51.8) 61 (52.1) 52 (51.5) 0.924
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ECMO extracorporeal membrane oxygenation, IQR interquartile range, PCC prothrombin complex centrates

Primary endpoint

Overall, there were 14 oxygenator changes in the high-dose group versus 48 in the low-dose group in 13 versus 32 patients. Freedom from oxygenator change at 15 days was 73% in the high-dose group versus 55% in the low-dose group (adjusted hazard ratio (HR) 3.34 [95% confidence interval 1.2–9.4 with low-dose heparinization], P = 0.023) (Fig. 2), with the entire regression model displayed in Fig. 3. Reasons for oxygenator changes were decreasing post-filter paO2 (86% and 59%), thrombus formation with increasing D-dimers (14% and 39%), and overt haemolysis (0% and 2%). The results were similar when analysing freedom from oxygenator change without censoring data at 15 days (adjusted HR 3.28 [95% confidence interval 1.2–8.6] with low-dose heparinization, P = 0.016).

Fig. 2.

Fig. 2

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Freedom of oxygenator-change at 15 days between high-dose and low-dose heparinization groups. Data is censored for decannulation or mortality. HR hazard ratio, CI confidence interval. aAdjusted for age, gender, body-mass-index, Respiratory ECMO Survival Prediction (RESP) score, Simplified acute physiology score II, sequential organ failure assessment renal sub-score, ECMO runtime, sepsis, coronary artery disease, prior aspirin use, mean ECMO blood flow, baseline fibrinogen, d-dimer and antithrombin III levels.

Fig. 3.

Fig. 3

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Multivariable cox regression model for oxygenator change. BMI body mass index, CAD coronary artery disease, RESP Respiratory ECMO Survival Prediction score, SAPS simplified acute physiology score, SOFA sequential organ failure assessment

Secondary endpoints

The overall median of the individual mean ACT in the high-dose group was 158 s (IQR 151–165) and the median of the mean PTT in the high-dose group was 48 s (IQR 41–57) versus 38 s (IQR 34–42) in the low-dose group (P < 0.001) (Fig. 4b, c). The corresponding mean units of heparin administered while on ECMO were 17,495 (IQR 10,971–24,327) vs. 11,185 (IQR 4,372–16,750) (P < 0.001) (Fig. 4a). The centre-defined ACT and PTT corridors were well-represented in the groups. Additional baseline coagulation parameters are shown in Table 2. In the patients who received an oxygenator change, the d-dimer foldchange compared to baseline was 2.97 (IQR 1.5–8.2) compared to 1.5 (IQR 0.4–4.5), in patients who did not undergo oxygenator change (P = 0.002).

Fig. 4.

Fig. 4

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Mean units of UFH administered per day (a); mean partial thromboplastin time (PTT) during ECMO (b) and mean activated clotting time (ACT) in the high-dose (HD) UFH group (c). ECMO extracorporeal membrane oxygenation, HD high dose heparin groups, LD low dose heparin group, PTT partial thromboplastin time, ACT activated clotting time, UFH unfractionated heparin

Severe bleeding was not different and occurred in 23 (19.7%) of patients in the high-dose group and in 14 (13.9%) in the low-dose group (P = 0.256) (Table 3). Of note, severe intracranial bleeding only occurred in the high-dose group with fatal outcome in 5 of 7 cases, while 3 events of intracranial bleeding in the low-dose group were incidental findings on CT without overt neurological deficit (and where thus not categorized as severe bleeding events).

Table 3.

Secondary outcomes

ALL
(n = 218)		 High-dose group
(n = 117)		 Low-dose group
(n = 101)		 P value
Severe bleeding events, n (%) 37 (17.0) 23 (19.7) 14 (13.9) 0.256
 Gastrointestinal / intrabdominal 12 (5.5) 5 (4.3) 7 (6.9)
 Intracranial 7 (3.2) 7 (6.0) 0
 Intrathoracic 16 (7.3) 10 (8.5) 6 (5.9)
 Cannula site 2 (0.9) 1 (0.9) 1 (1.0)
 Ear-nose-throat 1 (0.5) 1 (0.8) 0
RBC transfusions 7 (3–13) 6 (2–10) 8 (6–19)  < 0.001
Platelet transfusions 1 (0–5) 0 (0–1) 4 (0–10)  < 0.001
Thromboembolic events, n (%) 27 (12.4) 8 (6.8) 19 (19) 0.007
 Intraabdominal embolism / thrombosis 5 (2.3) 3 (2.5) 2 (2.0)
 Venous thrombosis 12 (5.5) 4 (3.4) 7 (6.9)
 Pulmonary embolism 3 (1.8) 1 (0.9) 2 (2.0)
 Peripheral arterial embolism 2 (0.9) 0 2 (2.0)
 ECMO filter embolism 3 (1.8) 0 3 (3.0)
 ECMO cannula thrombosis 1 (0.5) 0 1 (1.0)
 Ischemic stroke 2 (0.9) 0 2 (2.0)
 Heparin-induced thrombocytopenia, n (%) 3 (1.4) 1 (0.9) 2 (2.0)
30-day ICU mortality 70 (32.1) 39 (33.3) 31 (30.7) 0.110
Overall ICU mortality 91 (41.7) 47 (40.2) 44 (43.6) 0.612
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ECMO extracorporeal membrane oxygenation, ICU intensive care unit, RBC red blood cells, UFH unfractionated heparin

Applying different in-house standards of transfusion procedures, the number of RBC unit transfusions were significantly lower in the high-dose group compared to the low-dose group (6 [IQR 2–10] vs. 8 [IQR 6–19] P < 0.001), as were units of platelet transfusions (0 [IQR 0–1] vs. 4 [0–10], P < 0.001). More patients in the low-dose group received prothrombin complex concentrates (26 [25.7%] vs. 8 [6.8%], p < 0.001) and antithrombin III substitution (21 [21%] vs. 8 [6.9%], p = 0.002), while administration of tranexamic acid was similar (Table 2). All patients who received prothrombin complex concentrates had severe coagulopathy in the context of planned intervention with high bleeding risk (high-dose group: 2/8; low-dose group: 15/26) or significant haemoglobin-relevant bleeding (high-dose group: 6/8; low-dose group 11/26). Pre-ECMO use of antiplatelet therapy was not associated with oxygenator change or severe ECMO-related bleeding events.

Fewer thromboembolic events occurred in the high-dose group (8 [6.8%]) than in the low-dose group (19 [19%], P = 0.007). Of note, direct thrombotic events of the ECMO circuit (cannula thrombosis n = 1; coagulation of the oxygenator n = 2) occurred only in the low-dose group (Table 3).

The 30-day ICU mortality was comparable with 33.3% (n = 39) in the high-dose versus 30.7% (n = 31) in the low-dose group (P = 0.11). The main reasons for mortality in the high-dose versus low-dose group were cessation of therapy due to medical futility in 23 (59%) versus 12 (38.7%); refractory multiorgan failure in 11 (28.2%) versus 18 (58.1%), intracranial bleeding in 5 (12.8%) versus 0; abdominal bleeding complications in 0 versus 1 (3.2%).

Discussion

The key finding of this study is that when compared to an ACT-guided high dose heparinization strategy aiming for 140–180 s, a low dose heparin strategy adjusted by PTT aiming for 35–40 s is associated with a three-fold higher need for oxygenator changes during VV-ECMO support. Although all oxygenator changes in this study were uneventful, these procedures are resource-intensive and may be potentially life-threatening in patients fully dependent on ECMO support.

We initially hypothesized that lower heparin doses might be as efficient as therapeutic high dose anticoagulation regarding ECMO oxygenator durability with similar rates of bleeding events and thromboembolic events. However, in our study, low-dose anticoagulation was not only associated with a higher need for oxygenator changes but also with a higher rate of thromboembolic events. Contrarily, bleeding complications, foremost intracerebral bleeding events were less common in the low-dose group.

Between the two centres, there were overt and significant differences regarding number of transfusions for both RBC and platelet transfusions with considerably greater amounts given in the low-dose group. It is important to point out that these changes rather reflect the more liberal transfusion strategy in the low-dose centre than bleeding severity. At the same time, prothrombin complex concentrates and antithrombin III preparations were also more commonly administered in the low-dose group, where peri-operative patients were treated more often. In studies unrelated to ECMO, RBC transfusion have been shown to increase platelet responsiveness especially with decreased platelet counts and overall incidence of thromboembolic events [1517]. With ECMO support, both transfusions of platelets and RBC have been reported as independent risk factors for mortality [18, 19]. Therefore, differences in the transfusion strategy might have influenced the outcome in the current study and are not exclusively explained by heparinization. Future prospective RCT evaluating the optimal anticoagulation strategy in patients receiving ECMO support should be planned with pre-specified transfusions strategies.

The findings from our study contradict previous results from a small prospective trial (n = 10) where heparinization aiming for a PTT of 45–55 s (vs. 35–40 s in the present study) was compared to a standardized dose of 10U / kg / hour summing up to comparable mean doses in the high-dose group of the present study [20] showing no differences in oxygenator changes and bleeding events with considerable chances for underpowering. A longitudinal single-centre pre-post designed retrospective trial (n = 40) showed similar survival to decannulation rates, bleeding events and thromboembolic complications [21], but interestingly the ACTs in both groups were rather high (167 s vs. 189 s) compared to our cohort. Another mixed cohort including 22 patients with VV-ECMO compared heparinization guided by ACT (140–160 s vs. 180–220) and consistently found fewer bleeding events and similar rates of oxygenator changes [22], also aiming for higher ACT-prolongation than in our cohort. The lack of uniform anticoagulation strategies and outcome definitions across all studies render comparison of event rates difficult [23].

Beside mere heparin dosage, temporary interruption of heparin (e.g. in response to bleeding) may create a hypercoagulable milieu, thereby increasing the risk of clotting and oxygenator failure [24, 25], which might have influenced the results of the present study. Case series and smaller retrospective studies reported feasibility of heparin-free ECMO support in cases of trauma or severe bleeding [2629] and intermittent subcutaneous administration of heparin to avoid heparin pauses [25], but the optimal management strategies in these particularly challenging situations needs to be prospectively investigated and lies beyond the scope of the current retrospective study.

In recent years, more centres integrated anti-Xa levels alongside ACT or PTT in their routine coagulation monitoring during ECMO support following promising results mainly in paediatric populations and better reflection of heparin concentrations [3033]. Since inflammation can influence ACT measurements [34] the ECMO centres of the current study also utilize anti-Xa levels alongside thromboelastography and single clotting factor analysis where coagulation state is uncertain, and PTT or ACT seems out of line with heparin dosing. However, longer turn-around time and varying 24/7 availability of anti-Xa measurements are limiting factors and 97% of ECMO centres were still using ACT for heparin dose adjustments in 2014 [35]. Since current ELSO guidelines recommend ACT and PTT for measuring heparin effects [6], the analysis of different heparinization strategies based on these assays provide valuable information for intensivists caring for ECMO patients. Yet, we acknowledge that anti-Xa levels may be a more appropriate measurement of heparin effects than ACT or PTT in critically ill patients.

Limitations of this study were inherent to the retrospective design and the comparison of two centres, which render the data subject to substantial potential bias, including different bleeding management strategies, different ECMO devices, cannulation sites and patient populations. Our data thus needs prospective validation with uniform strategies for bleeding management, transfusion strategies and ECMO configuration to derive solid recommendations.

Conclusion

In this two-centre cohort study, the institutional strategy with a high-dose heparinization during ECMO support was associated with lower rates of oxygenator changes and thromboembolic events, compared to the strategy with low-dose heparinization. Prospective randomized validation with standardized bleeding management and ECMO settings is needed to confirm these findings.

Acknowledgements

None

Abbreviations

ACT

Activated clotting time

ARDS

Acute respiratory distress syndrome

ARF

Acute respiratory failure

ECMO

Extracorporeal membrane oxygenation

HR

Hazard ratio

ICU

Intensive care unit

IQR

Interquartile range

PTT

Partial thromboplastin time

RBC

Red blood cells

RESP

Respiratory ECMO Survival Prediction

SAPS

Simplified acute physiology score

SOFA

Sequential organ failure assessment

UFH

Unfractionated heparin

VV-ECMO

Venovenous extracorporeal membrane oxygenation

Authors' contributions

BS, SD and CB designed this study and data acquisition strategy. BS, MD, RF and CB were responsible for the data collection. BS, MD, AT, SD and CB were responsible for data analysis. BS and SD conducted the manuscript writing. KS, CK, JB, FS, SE, JCS, CP, TW, MMH, AT and CB critically revised the manuscript. BS, MD, SD and CB provided final approval for this version to be published. All authors agreed to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. All authors read and approved the final manuscript.

Funding

Open Access funding enabled and organized by Projekt DEAL. There was no specific funding for this study. BS is supported by PRACTIS – Clinician Scientist Programme of Hannover Medical School, funded by the Deutsche Forschungsgemeinschaft (DFG, ME 3696/3–1) and the German Center for Lung Research (DZL). JB, CK and MMH are supported by the DFG (KFO311, BA 1742/9–1, HO 1599/2–2). The laboratory of SD received funding from the DFG (DA 1209/4–3) and the DZL. The laboratory of CB received funding from the University of Bonn (BONFOR), and the B. Braun Foundation (D-17-00098).

Availability of data and materials

The data used for this research are available from the corresponding author on reasonable request and subject to Institutional Review Board guidelines.

Ethics approval and consent to participate

This study was reviewed and approved by the Institutional Review Board of Hannover Medical School (8715_BO_K_2019) and University of Bonn (398/19).

Consent for publication

Not applicable.

Competing interests

The authors declare they have no competing interests.

Footnotes

Publisher's Note

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Benjamin Seeliger and Michael Döbler contributed equally and are both considered first authors

Sascha David and Christian Bode contributed equally and are both considered last and corresponding authors

Contributor Information

Sascha David, Email: David.sascha@mh-hannover.de.

Christian Bode, Email: Christian.bode@ukbonn.de.

References

  • 1.Combes A, Hajage D, Capellier G, Demoule A, Lavoué S, Guervilly C, et al. Extracorporeal membrane oxygenation for severe acute respiratory distress syndrome. N Engl J Med. 2018;378:1965–1975. doi: 10.1056/NEJMoa1800385. [DOI] [PubMed] [Google Scholar]
  • 2.Sy E, Sklar MC, Lequier L, Fan E, Kanji HD. Anticoagulation practices and the prevalence of major bleeding, thromboembolic events, and mortality in venoarterial extracorporeal membrane oxygenation: A systematic review and meta-analysis. J Crit Care. 2017;39:87–96. doi: 10.1016/j.jcrc.2017.02.014. [DOI] [PubMed] [Google Scholar]
  • 3.Kreyer S, Muders T, Theuerkauf N, Spitzhüttl J, Schellhaas T, Schewe J-C, et al. Hemorrhage under veno-venous extracorporeal membrane oxygenation in acute respiratory distress syndrome patients: a retrospective data analysis. J Thorac Dis. 2017;9:5017–5029. doi: 10.21037/jtd.2017.11.05. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 4.Lubnow M, Philipp A, Foltan M, Bull Enger T, Lunz D, Bein T, et al. Technical complications during veno-venous extracorporeal membrane oxygenation and their relevance predicting a system-exchange–retrospective analysis of 265 cases. PLoS ONE. 2014;9:e112316. doi: 10.1371/journal.pone.0112316. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 5.Esper SA, Welsby IJ, Subramaniam K, John Wallisch W, Levy JH, Waters JH, et al. Adult extracorporeal membrane oxygenation: An international survey of transfusion and anticoagulation techniques. Vox Sang. 2017;112:443–452. doi: 10.1111/vox.12514. [DOI] [PubMed] [Google Scholar]
  • 6.Extracorporeal Life Support Organization. ELSO Guidelines for Cardiopulmonary Extracorporeal Life Support Version 1.4. August 2017. https://www.elso.org/Portals/0/ELSO%20Guidelines%20For%20Adult%20Respiratory%20Failure%201_4.pdf. Accessed 8 Mar 2020.
  • 7.Mazzeffi MA, Tanaka K, Roberts A, Rector R, Menaker J, Kon Z, et al. Bleeding, thrombosis, and transfusion with two heparin anticoagulation protocols in venoarterial ECMO patients. J Cardiothorac Vasc Anesth. 2019;33:1216–1220. doi: 10.1053/j.jvca.2018.07.045. [DOI] [PubMed] [Google Scholar]
  • 8.Raman J, Alimohamed M, Dobrilovic N, Lateef O, Aziz S. A comparison of low and standard anti-coagulation regimens in extracorporeal membrane oxygenation. J Heart Lung Transpl. 2019;38:433–439. doi: 10.1016/j.healun.2019.01.1313. [DOI] [PubMed] [Google Scholar]
  • 9.Aubron C, McQuilten Z, Bailey M, Board J, Buhr H, Cartwright B, et al. Low-dose versus therapeutic anticoagulation in patients on extracorporeal membrane oxygenation: a pilot randomized trial. Crit Care Med. 2019;47:e563–e571. doi: 10.1097/CCM.0000000000003780. [DOI] [PubMed] [Google Scholar]
  • 10.Derek L, Zivkovic M, Hasperger D, Juricek J, Romic Z. Comparability of Pathromtin SL, Dade Actin FS i STA Cephascreen reagens for activated partial thromboplastin time measurement. Biochem Med. 2008;2008:81–87. doi: 10.11613/BM.2008.009. [DOI] [Google Scholar]
  • 11.Philipp A, de Somer F, Foltan M, Bredthauer A, Krenkel L, Zeman F, Lehle K. Life span of different extracorporeal membrane systems for severe respiratory failure in the clinical practice. PLoS ONE. 2018;13:e0198392. doi: 10.1371/journal.pone.0198392. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 12.Le Gall J-R. A New Simplified Acute Physiology Score (SAPS II) Based on a European/North American Multicenter Study. JAMA. 1993;270:2957. doi: 10.1001/jama.1993.03510240069035. [DOI] [PubMed] [Google Scholar]
  • 13.Schmidt M, Bailey M, Sheldrake J, Hodgson C, Aubron C, Rycus PT, et al. Predicting survival after extracorporeal membrane oxygenation for severe acute respiratory failure the respiratory extracorporeal membrane oxygenation survival prediction (RESP) score. Am J Respir Crit Care Med. 2014;189:1374–1382. doi: 10.1164/rccm.201311-2023OC. [DOI] [PubMed] [Google Scholar]
  • 14.Vincent JL, Moreno R, Takala J, Willatts S, de Mendonça A, Bruining H, et al. The SOFA (Sepsis-related Organ Failure Assessment) score to describe organ dysfunction/failure. On behalf of the Working Group on Sepsis-Related Problems of the European Society of Intensive Care Medicine. Intensive Care Med. 1996;22:707–710. doi: 10.1007/BF01709751. [DOI] [PubMed] [Google Scholar]
  • 15.Silvain J, Abtan J, Kerneis M, Martin R, Finzi J, Vignalou J-B, et al. Impact of red blood cell transfusion on platelet aggregation and inflammatory response in anemic coronary and noncoronary patients: the TRANSFUSION-2 study (impact of transfusion of red blood cell on platelet activation and aggregation studied with flow cytometry use and light transmission aggregometry) J Am Coll Cardiol. 2014;63:1289–1296. doi: 10.1016/j.jacc.2013.11.029. [DOI] [PubMed] [Google Scholar]
  • 16.Valles J, Santos MT, Aznar J, Marcus AJ, Martinez-Sales V, Portoles M, et al. Erythrocytes metabolically enhance collagen-induced platelet responsiveness via increased thromboxane production, adenosine diphosphate release, and recruitment. Blood. 1991;78:154–162. doi: 10.1182/blood.V78.1.154.154. [DOI] [PubMed] [Google Scholar]
  • 17.Goel R, Patel EU, Cushing MM, Frank SM, Ness PM, Takemoto CM, et al. Association of perioperative red blood cell transfusions with venous thromboembolism in a North American Registry. JAMA Surg. 2018;153:826–833. doi: 10.1001/jamasurg.2018.1565. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 18.Aubron C, Cheng AC, Pilcher D, Leong T, Magrin G, Cooper DJ, et al. Factors associated with outcomes of patients on extracorporeal membrane oxygenation support: a 5-year cohort study. Crit Care. 2013;17:R73. doi: 10.1186/cc12681. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 19.Mazzeffi M, Greenwood J, Tanaka K, Menaker J, Rector R, Herr D, et al. Bleeding, transfusion, and mortality on extracorporeal life support: ECLS working group on thrombosis and hemostasis. Ann Thorac Surg. 2016;101:682–689. doi: 10.1016/j.athoracsur.2015.07.046. [DOI] [PubMed] [Google Scholar]
  • 20.Deatrick KB, Galvagno SM, Mazzeffi MA, Kaczoroswki DJ, Herr DL, Rector R, et al. Pilot study evaluating a non-titrating, weight-based anticoagulation scheme for patients on veno-venous extracorporeal membrane oxygenation. Perfusion. 2020;35:13–18. doi: 10.1177/0267659119850024. [DOI] [PubMed] [Google Scholar]
  • 21.Carter KT, Kutcher ME, Shake JG, Panos AL, Cochran RP, Creswell LL, Copeland H. Heparin-sparing anticoagulation strategies are viable options for patients on veno-venous ECMO. J Surg Res. 2019;243:399–409. doi: 10.1016/j.jss.2019.05.050. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 22.Yeo HJ, Kim DH, Jeon D, Kim YS, Cho WH. Low-dose heparin during extracorporeal membrane oxygenation treatment in adults. Intensive Care Med. 2015;41:2020–2021. doi: 10.1007/s00134-015-4015-7. [DOI] [PubMed] [Google Scholar]
  • 23.Oude Lansink-Hartgring A, de Vries AJ, Droogh JM, van den Bergh WM. Hemorrhagic complications during extracorporeal membrane oxygenation: the role of anticoagulation and platelets. J Crit Care. 2019;54:239–243. doi: 10.1016/j.jcrc.2019.09.013. [DOI] [PubMed] [Google Scholar]
  • 24.Kasirajan V, Smedira NG, McCarthy JF, Casselman F, Boparai N, McCarthy PM. Risk factors for intracranial hemorrhage in adults on extracorporeal membrane oxygenation1. Eur J Cardiothorac Surg. 1999;15:508–514. doi: 10.1016/S1010-7940(99)00061-5. [DOI] [PubMed] [Google Scholar]
  • 25.Kurihara C, Walter JM, Karim A, Thakkar S, Saine M, Odell DD, et al. Feasibility of venovenous extracorporeal membrane oxygenation without systemic anticoagulation. Ann Thorac Surg. 2020 doi: 10.1016/j.athoracsur.2020.02.011. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 26.Herbert DG, Buscher H, Nair P. Prolonged venovenous extracorporeal membrane oxygenation without anticoagulation: a case of Goodpasture syndrome-related pulmonary haemorrhage. Crit Care Resusc. 2014;16:69–72. [PubMed] [Google Scholar]
  • 27.Seeliger B, Stahl K, Schenk H, Schmidt JJ, Wiesner O, Welte T, et al. Extracorporeal membrane oxygenation for severe ARDS due to immune diffuse alveolar hemorrhage: a retrospective observational study. Chest. 2020;157:744–747. doi: 10.1016/j.chest.2019.10.021. [DOI] [PubMed] [Google Scholar]
  • 28.Takagaki M, Yamaguchi H, Ikeda N, Takeda K, Kasai F, Yahagi K, et al. Post-cardiotomy venovenous extracorporeal membrane oxygenation without heparinization. Gen Thorac Cardiovasc Surg. 2019;67:982–986. doi: 10.1007/s11748-018-0990-2. [DOI] [PubMed] [Google Scholar]
  • 29.Muellenbach RM, Kredel M, Kunze E, Kranke P, Kuestermann J, Brack A, et al. Prolonged heparin-free extracorporeal membrane oxygenation in multiple injured acute respiratory distress syndrome patients with traumatic brain injury. J Trauma Acute Care Surg. 2012;72:1444–1447. doi: 10.1097/TA.0b013e31824d68e3. [DOI] [PubMed] [Google Scholar]
  • 30.Northrop MS, Sidonio RF, Phillips SE, Smith AH, Daphne HC, Pietsch JB, Bridges BC. The use of an extracorporeal membrane oxygenation anticoagulation laboratory protocol is associated with decreased blood product use, decreased hemorrhagic complications, and increased circuit life. Pediatr Crit Care Med. 2015;16:66–74. doi: 10.1097/PCC.0000000000000278. [DOI] [PubMed] [Google Scholar]
  • 31.Liveris A, Bello RA, Friedmann P, Duffy MA, Manwani D, Killinger JS, et al. Anti-factor Xa assay is a superior correlate of heparin dose than activated partial thromboplastin time or activated clotting time in pediatric extracorporeal membrane oxygenation*. Pediatr Crit Care Med. 2014;15:e72–e79. doi: 10.1097/PCC.0000000000000028. [DOI] [PubMed] [Google Scholar]
  • 32.Ranucci M, Cotza M, Isgrò G, Carboni G, Ballotta A, Baryshnikova E. Anti-factor Xa-based anticoagulation during extracorporeal membrane oxygenation: potential problems and possible solutions. Semin Thromb Hemost. 2020;46:419–427. doi: 10.1055/s-0039-1697950. [DOI] [PubMed] [Google Scholar]
  • 33.Chlebowski MM, Baltagi S, Carlson M, Levy JH, Spinella PC. Clinical controversies in anticoagulation monitoring and antithrombin supplementation for ECMO. Crit Care. 2020;24:19. doi: 10.1186/s13054-020-2726-9. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 34.Papageorgiou C, Synetos A, Tampakis K, Anninos H, Kontogiannis C, Kapelouzou A, et al. Activated clotting time as a marker of inflammation in hospitalized patients. Clin Appl Thromb Hemost. 2020;26:1076029620929090. doi: 10.1177/1076029620929090. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 35.Bembea MM, Annich G, Rycus P, Oldenburg G, Berkowitz I, Pronovost P. Variability in anticoagulation management of patients on extracorporeal membrane oxygenation: an international survey. Pediatr Crit Care Med. 2013;14:e77–84. doi: 10.1097/PCC.0b013e31827127e4. [DOI] [PMC free article] [PubMed] [Google Scholar]

Associated Data

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Data Availability Statement

The data used for this research are available from the corresponding author on reasonable request and subject to Institutional Review Board guidelines.

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