Extracorporeal membrane oxygenation in patients with severe respiratory failure from COVID-19.

PURPOSE: Limited data are available on venovenous extracorporeal membrane oxygenation (ECMO) in patients with severe hypoxemic respiratory failure from coronavirus disease 2019 (COVID-19).
METHODS: We examined the clinical features and outcomes of 190 patients treated with ECMO within 14 days of ICU admission, using data from a multicenter cohort study of 5122 critically ill adults with COVID-19 admitted to 68 hospitals across the United States. To estimate the effect of ECMO on mortality, we emulated a target trial of ECMO receipt versus no ECMO receipt within 7 days of ICU admission among mechanically ventilated patients with severe hypoxemia (PaO2/FiO2 < 100). Patients were followed until hospital discharge, death, or a minimum of 60 days. We adjusted for confounding using a multivariable Cox model.
RESULTS: Among the 190 patients treated with ECMO, the median age was 49 years (IQR 41-58), 137 (72.1%) were men, and the median PaO2/FiO2 prior to ECMO initiation was 72 (IQR 61-90). At 60 days, 63 patients (33.2%) had died, 94 (49.5%) were discharged, and 33 (17.4%) remained hospitalized. Among the 1297 patients eligible for the target trial emulation, 45 of the 130 (34.6%) who received ECMO died, and 553 of the 1167 (47.4%) who did not receive ECMO died. In the primary analysis, patients who received ECMO had lower mortality than those who did not (HR 0.55; 95% CI 0.41-0.74). Results were similar in a secondary analysis limited to patients with PaO2/FiO2 < 80 (HR 0.55; 95% CI 0.40-0.77).
CONCLUSION: In select patients with severe respiratory failure from COVID-19, ECMO may reduce mortality.

Take-home message

Introduction

Coronavirus disease 2019 (COVID-19) has caused nearly 1.5 million deaths globally as of November 29, 2020 [1]. Treatment of patients with severe hypoxemic respiratory failure from COVID-19 includes conventional therapies established for acute respiratory distress syndrome (ARDS), including invasive mechanical ventilation with lung protective strategies, prone positioning, neuromuscular blockade, and inhaled pulmonary vasodilators [2, 3]. For patients who experience progressive respiratory failure despite these conventional therapies, venovenous extracorporeal membrane oxygenation (ECMO) may be considered to support gas exchange and minimize ventilator-induced lung injury [4, 5]. ECMO has been used for decades in the treatment of severe ARDS of various etiologies. Recent clinical trials evaluated the efficacy and safety of ECMO in severe ARDS [6, 7], with a survival benefit demonstrated in a meta-analysis [8].

Early reports from China, Europe, and the United States on the use of ECMO in patients with respiratory failure from COVID-19 have been limited by modest sample sizes and short follow-up [9-17]. More recent studies report larger numbers of patients who received ECMO, yet still suffer from lack of a comparative non-ECMO control group [18, 19]. Additional data are urgently needed to inform the potential efficacy and safety of ECMO in critically ill adults with severe respiratory failure from COVID-19.

To address this knowledge gap, we used data from a multicenter cohort study of critically ill patients with COVID-19 admitted to intensive care units (ICUs) across the United States to describe the clinical characteristics, physiologic parameters, complications, and outcomes of patients who initiated treatment with ECMO in the first 14 days of ICU admission. To estimate the effect of ECMO on survival in patients with COVID-19, we emulated a target trial in which patients with severe hypoxemic respiratory failure were categorized as having initiated or not initiated ECMO in the first 7 days of ICU admission.

Methods

Study design and oversight

We used data from the Study of the Treatment and Outcomes in Critically Ill Patients with COVID-19 (STOP-COVID), a multicenter cohort study that enrolled consecutive adults (≥ 18 years old) with laboratory-confirmed COVID-19 admitted to participating ICUs at 68 geographically diverse hospitals across the United States [20]. The study was approved with a waiver of informed consent by the Institutional Review Board at each participating site.

Study sites and patient population

A total of 55 of the 68 participating hospitals in STOP-COVID were capable of treating patients with ECMO (Table E1). We included patients with COVID-19 who were admitted to an ICU at one of these 55 ECMO-capable participating hospitals between March 1 and July 1, 2020 (Fig. E1). Patients were considered to have received ECMO if they underwent cannulation for venovenous ECMO within 14 days following ICU admission (patients receiving venoarterial or veno-arterial-venous ECMO were excluded). We followed patients until hospital discharge, death, or September 1, 2020. All patients who remained hospitalized at the time of analysis had a minimum of 60 days of follow-up.

Data collection

Study personnel at each site collected data by manual chart review and used a standardized case report form to enter data using a secure, web-based platform [21]. Data included baseline information on demographics, coexisting conditions, symptoms, home medications, and vital signs on ICU admission, as well as daily data following ICU admission on laboratory and physiologic parameters (including the ratio of the partial pressure of arterial oxygen over the fraction of inspired oxygen [PaO2/FiO2]), medications, non-medication treatments, organ support, and outcome data on ICU and hospital length of stay and death. Among patients who received ECMO, additional data were collected on respiratory mechanics and ventilator parameters pre- and post-ECMO cannulation. Definitions of variables are provided in Table E2.

Statistical analysis for descriptive cohort

To describe baseline characteristics, treatment, and outcomes in patients who received ECMO within 14 days of ICU admission, continuous variables are expressed as median and interquartile range and categorical variables are presented as count and percentage. Among patients who received ECMO, differences between 60-day survivors and non-survivors were analyzed with a t test or Mann–Whitney U test for continuous data and with a Chi-square or Fisher’s Exact test for categorical data, as appropriate. Patients who were discharged prior to 60 days were considered to be alive at 60 days.

Eligibility criteria for the emulated trial

To estimate the effect of ECMO on survival, we emulated a target trial comparing patients who initiated ECMO in the first 7 days of ICU admission to those who did not. Seven days was chosen as the time period for treatment assignment to provide greater homogeneity between patients, to allow for more follow-up time, and to be consistent with major trial exclusion criteria and consensus guidelines [2, 6, 7, 22]. To emulate the eligibility criteria of a clinical trial of ECMO in patients with severe ARDS [23], we included patients with a PaO2/FiO2 ratio < 100 mmHg while receiving invasive mechanical ventilation, and we excluded patients if they had any of the following characteristics: over 70 years old; malignancy treated in the prior year; treatment with venoarterial ECMO; or admission to an ICU at a hospital incapable of providing ECMO. PaO2/FiO2 ratio was assessed as the lowest PaO2 value (with the corresponding FiO2 value) on the day of ECMO initiation/non-initiation or the day prior.

Target trial emulation

The primary analysis compares the survival among ECMO initiators versus ECMO non-initiators. On day 1 of ICU admission, patients were categorized in the ECMO group if they received ECMO and were categorized in the non-ECMO group if they did not receive ECMO. We repeated this procedure on days 2 through 7 for eligible patients who had not previously received ECMO. This approach eliminates the immortal time bias that would result from comparing patients initiating ECMO at a later time point (e.g., ICU day 5) to patients who did not receive ECMO at an earlier time point (e.g., ICU day 1) [24]. Patients were followed from the date of ECMO initiation or non-initiation until death, hospital discharge, or the end of follow-up, whichever occurred first. Hazard ratios (HRs) and 95% confidence intervals (CIs) were estimated using a Cox model. The final estimates of the effect of ECMO on survival were obtained by pooling the data from the emulation of the nested target trials on days 1 through seven of ICU admission.

Multivariable adjustment for confounding

We adjusted for confounding using a multivariable Cox model. The following covariates were prespecified based on clinical judgment and prior knowledge [20], as they were felt to potentially be associated with both ECMO receipt and with survival: age (18–49; 50–59; 60–70); sex; race (White; non-White); body mass index (< 40; ≥ 40; unknown); hypertension; diabetes mellitus; coronary artery disease; congestive heart failure; chronic obstructive pulmonary disease (COPD); PaO2/FiO2 ratio (< 80; 80–99 mmHg); shock (defined as receipt of at least one vasopressor); suspected or confirmed secondary infection; the renal, liver, and coagulation components of the Sequential Organ Failure Assessment score [25, 26]; and receipt of rescue therapies for hypoxemia (prone position ventilation, neuromuscular blockade, and inhaled vasodilators, each assessed separately). Acute severity of illness characteristics were assessed on the day of treatment assignment. Additional details are provided in the Supplementary Methods. We used a robust (sandwich) variance estimator to account for potential replications of patients induced by our nested target trial approach, which results in conservative (wider) 95% CIs. In addition to the time-to-death analyses describe above, we also estimated the difference in the risk of 60-day mortality in ECMO-treated versus ECMO non-treated patients using the marginal probabilities from a logistic regression model that included the covariates listed above.

Sensitivity analyses

We also conducted a series of sensitivity analyses. First, we treated hospital discharge as a competing risk rather than a censoring event. Second, as an alternative approach to the primary analysis to eliminate immortal time bias, we matched each patient who initiated ECMO on day 1 with two randomly selected eligible control patients (PaO2/FiO2 ratio < 100 mmHg while receiving invasive mechanical ventilation) who did not initiate ECMO. We then repeated the process on days 2 through 7, with ECMO non-treated patients only being included once. Third, we limited our analysis to a more homogeneous group of patients with the following characteristics: < 65 years old; absence of coronary artery disease, congestive heart failure, and COPD; mechanically ventilated and with a PaO2/FiO2 ratio < 80 mmHg; and receipt of at least one rescue therapy for hypoxemia (prone position ventilation, neuromuscular blockade, or inhaled vasodilators) prior to ECMO initiation or non-initiation. For each of the above analyses, we adjusted for confounding by indication using a multivariable Cox model, as described above.

We performed two additional analyses similar to the primary analysis, but using alternative PaO2/FiO2 thresholds (< 80 and < 150 mmHg) to define eligibility. Finally, to assess the potential for effect modification according to day of treatment assignment, we tested the significance of an interaction term (treatment assignment × day of treatment [defined as day 1–3 versus day 4–7]) introduced into the model. Analyses were performed using SAS software version 9.4 (SAS Institute).

Data completeness

Rates of missing data overall are shown in Table E3. With the exception of body mass index, data were complete for all covariates included in the multivariable models. Missing data for body mass index (8.5% of ECMO recipients and 3.3% of ECMO non-recipients) were not imputed. Rather, a separate missing category was used.

Results

Baseline characteristics

A total of 5122 critically ill patients with COVID-19 were admitted to ICUs during the study period. A total of 190 of the 5122 patients (3.7%) received ECMO during the 14 days following ICU admission at 35 of the 55 ECMO-capable sites (Figs. 1 and E1). The median age of patients who received ECMO was 49 years (IQR 41–58) and 137 patients (72.1%) were male (Tables 1, E3). No patients who received venovenous ECMO were converted to venoarterial ECMO.

Fig. 1

Study cohort. Two populations of patients are shown: the descriptive analysis, which includes all patients who initiated ECMO in the first 14 days following ICU admission, and the target trial emulation, which includes patients who did or did not initiate ECMO in the first 7 days following ICU admission. For the target trial emulation, patients who initiated ECMO appeared in the pooled dataset up to and including the day that ECMO was initiated. For example, a patient who initiated ECMO on ICU day one did not have a corresponding observation on ICU days two through seven. A patient who initiated ECMO on ICU day three, meanwhile, appeared as both an ECMO non-initiator on days one and two and as an ECMO initiator on day three. ECMO extracorporeal membrane oxygenation, ICU intensive care unit, PaO/FiO partial pressure of arterial oxygen over the fraction of inspired oxygen

Table 1

Characteristics of patients who received ECMO

Characteristic	All ECMO patients (N = 190)	ECMO 60-day survivors (N = 127)	ECMO 60-day non-survivors (N = 63)	p value
Baseline demographics
Age (year)—median (IQR)	49 (41–58)	47 (38–54)	53 (46 to 60)	0.002
18–39	45 (23.7)	35 (27.6)	10 (15.9)	0.01
40–49	56 (29.5)	41 (32.3)	15 (23.8)
50–59	54 (28.4)	35 (27.6)	19 (30.2)
60–70	35 (18.4)	16 (12.6)	19 (30.2)
Male sex—no. (%)	137 (72.1)	86 (67.7)	51 (81)	0.06
Body mass index (kg/m2)—median (IQR)	32.7 (29.1–38)	33.2 (29.5–38.3)	31.3 (29 to 37.5)	0.32
Healthcare worker—no. (%)	7 (3.7)	5 (3.9)	2 (3.2)	0.89
Coexisting conditions—no. (%)
Presence of any chronic condition	119 (62.6)	77 (60.6)	42 (66.7)	0.42
Presence of multiple chronic conditions	60 (31.6)	34 (26.8)	26 (41.3)	0.04
Chronic lung disease	13 (6.8)	6 (4.7)	7 (11.1)	0.13
Coronary artery disease	7 (3.7)	4 (3.2)	3 (4.8)	0.69
Chronic liver disease	4 (2.1)	1 (0.8)	3 (4.8)	0.11
End-stage renal disease	2 (1.1)	1 (0.8)	1 (1.6)	0.61
Active malignancy	3 (1.6)	1 (0.8)	2 (3.2)	0.26
Pregnancy or postpartum	5 (2.6)	4 (3.2)	1 (1.6)	0.53
Characteristics at ICU admission
Severity of illness indicators
Invasive mechanical ventilation—no. (%)	149 (78.4)	7.5	50 (79.4)	0.82
PEEP, cmH2O—median (IQR)	15 (12–18)	15 (12–18)	15 (13 to 16)	0.68
PaO2/FiO2 ratioa, mmHg—median (IQR)	85 (66–120)	82 (66–111)	87 (65 to 126)	0.86
Acute kidney injury requiring RRT—no. (%)	11 (5.9)	8 (6.4)	3 (4.8)	0.68
Shock—no. (%)	108 (56.8)	68 (53.5)	40 (63.5)	0.19
ICU therapies prior to ECMO cannulation
Rescue therapies for hypoxemia—no. (%)
Prone positioning	135 (71.1)	87 (68.5)	48 (76.2)	0.27
Neuromuscular blockade	149 (78.4)	96 (75.6)	53 (84.1)	0.18
Inhaled nitric oxide	30 (15.8)	23 (18.1)	7 (11.1)	0.21
Inhaled epoprostenol	36 (19)	24 (18.9)	12 (19.1)	0.98
Therapeutic anticoagulation—no. (%)	136 (71.6)	88 (69.3)	48 (76.2)	0.32
Acute organ injury and secondary infection within 24 h prior to ECMO cannulationb
Acute kidney injury requiring RRT—no. (%)	33 (17.6)	18 (14.3)	15 (24.2)	0.09
Shock—no. (%)	157 (82.6)	100 (78.7)	57 (90.5)	0.04
Acute liver injury—no. (%)	4 (2.1)	0 (0)	4 (6.4)	0.01
Secondary infection—no. (%)	11 (5.8)	5 (3.9)	6 (9.5)	0.18
Characteristics within 24 h prior to ECMO cannulationb
RESP score—median (IQR)	3 (1–5)	4 (2–5)	2 (− 1 to 4)	< 0.001
PaO2/FiO2 ratioa, mmHg—median (IQR)	72 (61–90)	74 (63–93)	69 (58 to 79)	0.02
< 80	118 (62.8)	72 (57.6)	46 (73)	0.14
80–99	39 (20.7)	28 (22.4)	11 (17.5)
100–149	28 (14.9)	23 (18.4)	5 (7.9)
150–200	3 (1.6)	2 (1.6)	1 (1.6)
PEEP, cmH2O—median (IQR)	15 (14–18)	16 (14–18)	15 (14 to 18)	0.66
FiO2—median (IQR)	100 (80–100)	100 (80–100)	100 (80 to 100)	0.82
PaCO2, mmHg—median (IQR)	55 (46–66)	55 (47–65)	55 (45 to 68)	0.73
Tidal volume, ml/kg IBW—median (IQR)	6 (5.3–7.1)	6 (5.3–7.1)	6.2 (5.2 to 7.1)	0.64
Respiratory rate, min−1—median (IQR)	27 (22–30)	26 (21–30)	28 (22 to 32)	0.26
Plateau pressure, cmH2O—median (IQR)	30 (28–35)	30 (28–35)	31 (28 to 34)	0.73
Driving pressure, cmH2O—median (IQR)	15 (11–18)	15 (12–18)	15 (11 to 17)	0.99
Compliance, cmH2O−1—median (IQR)	28 (21–36)	27 (19–38)	30 (22 to 36)	0.41
Laboratory values within 24 h prior to ECMO cannulationb
White cell count, per mm3	13.5 (9.2–18.8)	12.9 (9–16.7)	14.5 (9.6 to 21.9)	0.15
Lymphocyte count, per mm3	5 (3–8)	6 (3–8)	4 (3 to 7)	0.29
Hemoglobin, g/dl	10.8 (9.5–12)	11.1 (9.9–12.4)	10.2 (9.0 to 11.5)	0.01
Platelet count, per mm3	239 (172–302)	247 (191–313)	188 (133 to 274)	0.001
Albumin, g/dl	2.4 (2.1–2.8)	2.5 (2.2–3)	2.3 (2.0 to 2.6)	0.01
Arterial pH—median (IQR)	7.30 (7.23–7.36)	7.31 (7.26–7.36)	7.29 (7.21 to 7.36)	0.08
Lactate, mmol/l	1.9 (1.4–2.9)	1.9 (1.5–2.9)	2.2 (1.4 to 3.1)	0.20
d-dimer, ng/ml	3483 (1758–6860)	3502 (1758–7429)	3340 (1780 to 5744)	0.59
Timing characteristics—median (IQR)
Days from symptom onset to cannulation	13 (10–17)	12 (10–16)	13 (9 to 18)	0.41
Days from hospital admission to cannulation	6 (4–9)	5 (3–7)	6 (4 to 11)	0.01
Days from ICU admission to cannulation	3 (1–6)	3 (0–5)	4 (1 to 6)	0.10
Days from mechanical ventilation to cannulation	2 (0–5)	2 (0–5)	3 (1 to 6)	0.07
Hospital characteristics
Number of ICU beds—no. (%)				0.10
< 50	44 (23.2)	25 (19.7)	19 (30.2)
50–99		38 (20)	23 (18.1)	15 (23.8)
≥ 100	108 (56.8)	79 (62.2)	29 (46)

Variable definitions are presented in Supplementary Table 2. Rates of missing data are reported in Table E3

ECMO extracorporeal membrane oxygenation, FiO fraction of inspired oxygen, ICU intensive care unit, IBW ideal body weight, IQR interquartile range, PaO partial pressure of arterial oxygen, PaCO partial pressure of carbon dioxide, PEEP positive end expiratory pressure, RESP respiratory extracorporeal membrane oxygenation survival prediction, RRT renal replacement therapy

aPaO2/FiO2 refers to the ratio of the partial pressure of arterial oxygen (PaO2) over the fraction of inspired oxygen (FiO2) and was only assessed in patients receiving invasive mechanical ventilation. Values are recorded prior to ECMO initiation

bIncludes values from the day prior to cannulation and the day of ECMO cannulation

Characteristics prior to ECMO

Patients were cannulated at a median of 3 days (IQR 1–6) following ICU admission, and 83% of patients who received ECMO were cannulated in the first 7 days of ICU admission (Figure E2). Among the 188 patients with a PaO2/FiO2 ratio recorded in the 24 h prior to ECMO cannulation, 118 (62.8%) had a PaO2/FiO2 ratio less than 80 mmHg, and 157 (83.5%) had a PaO2/FiO2 ratio less than 100 mmHg (Figure E3). PaO2/FiO2 ratio, positive end expiratory pressure, and receipt of therapies for hypoxemia were similar between 60-day survivors and non-survivors (Table 1). Survivors had a lower incidence of shock and a higher Respiratory ECMO Survival Prediction (RESP) score [27] in the 24 h prior to ECMO cannulation compared to non-survivors (Table 1).

Complications after ECMO cannulation

The most common complications after ECMO cannulation were bacterial pneumonia (34.7%), bleeding (27.9%), thrombotic events (22.6%), and acute kidney injury requiring renal replacement therapy (21.8%). Eight patients (4.2%) had intracranial hemorrhage and three patients (1.6%) had an ischemic stroke. Additional outcomes are shown in Table 2. Respiratory and laboratory parameters 24 h post-ECMO cannulation are shown in Table E4.

Table 2

Outcomes of patients who received ECMO

Outcome measure	All ECMO patients (N = 190)	ECMO 60-day survivors (N = 127)	ECMO 60-day non-survivors (N = 63)	p value
60-day outcomes—no. (%)
Mortality status				< 0.001
Death	63 (33.2)	0 (0)	63 (100)
Survival to hospital discharge	94 (49.5)	94 (74)	0 (0)
Still hospitalized	33 (17.4)	33 (26)	0 (0)
Length of stay
ICU—median (IQR)	31 (20–43)	34 (23–48)	25 (14–25)	< 0.001
Hospital—median (IQR)	39 (28–53)	46 (34–61)	29 (17–39)	< 0.001
28-day outcomes—no. (%)
Decannulated from ECMO	102 (53.7)	93 (73.2)	9 (14.3)	< 0.001
Liberation from mechanical ventilation	59 (31.1)	57 (44.9)	2 (3.2)	< 0.001
Days of ECMO—median (IQR)	16 (10–23)	16 (10–24)	16 (9–22)	0.28
Days of ventilation—median (IQR)	26 (17–28)	26 (19–28)	23 (14–28)	0.03
28-day complications—no. (%)
Acute kidney injury requiring RRTa	41 (21.8)	19 (15.1)	22 (35.5)	0.001
Pneumothorax requiring chest tube placement	24 (12.6)	14 (11)	10 (15.9)	0.34
Thrombotic event	43 (22.6)	32 (25.2)	11 (17.5)	0.23
Pulmonary embolism	3 (1.6)	1 (0.8)	2 (3.2)	0.26
Deep vein thrombosis	35 (18.4)	29 (22.8)	6 (9.5)	0.03
Ischemic stroke	3 (1.6)	0 (0)	3 (4.8)	0.04
Other thrombotic event	4 (2.1)	3 (2.4)	1 (1.6)	0.73
Bleeding complication	53 (27.9)	23 (18.1)	30 (47.6)	< 0.001
Intracranial hemorrhage	8 (4.2)	1 (0.8)	7 (11.1)	0.002
Other systemic bleeding events	47 (24.7)	23 (18.1)	24 (38.1)	0.003
Both thrombotic and bleeding events	14 (7.4)	7 (5.5)	7 (11.1)	0.24
Bacterial pneumonia	66 (34.7)	41 (32.3)	25 (39.7)	0.31
Other culture-documented infections	35 (18.4)	28 (22.1)	7 (11.1)	0.07

Outcome definitions are defined in Supplementary Table 2

ECMO extracorporeal membrane oxygenation, ICU intensive care unit, IQR interquartile range, RRT renal replacement therapy

aValues are only reported for patients without end-stage renal disease at baseline

Mortality and length of stay after ECMO cannulation

Among the 190 patients who received ECMO, 63 (33.2%) died, 94 (49.5%) were discharged alive, and 33 (17.4%) were still hospitalized at day 60 (Table 2). Among the survivors, the median ICU and hospital length of stay was 34 days (IQR 23–48) and 46 days (IQR 34–61), respectively (Table 2). When followed until the last date of follow-up, 67 patients (35.3%) had died, 114 (60%) were discharged alive, and only 9 (4.7%) were still hospitalized. Of those who were discharged alive, 57 (50.4%) were discharged home, 53 (46.5%) were discharged to a rehabilitation facility, 3 (2.7%) were transferred to another hospital, and 1 (0.9%) was missing data on discharge location (Table E5). Of the 53 patients discharged to a rehabilitation facility, only 18 (34%) went to a long-term acute care facility capable of providing invasive mechanical ventilation.

Early vs. late cannulation

Characteristics and outcomes of patients cannulated in the first compared to the second week following ICU admission are shown in Table E6.

Among 5122 patients examined, a total of 2068 were excluded from the target trial emulation (Fig. 1). Of the remaining 3054 patients, 1297 were eligible for inclusion in the target trial on at least 1 of the 7 days following ICU admission, 130 (10%) of whom received ECMO and 1167 (90%) of whom did not. The characteristics of ECMO-treated and non-treated patients are shown in Table 3. Patients treated with ECMO were younger, more likely to be male, and less likely to have chronic cardiovascular and respiratory disease compared to patients not treated with ECMO, but were more likely to have shock and a lower PaO2/FiO2 ratio (Table 3). Patients treated with ECMO were also more likely to have received rescue therapies for hypoxemia compared to those not treated with ECMO (Table 3).

Table 3

Characteristics of patients included in the target trial emulation of ECMO versus no ECMO

	Unique patients		Final cohorta
	ECMO (N = 130)	No ECMO (N = 1167)	ECMO (N = 130)	No ECMO (N = 3565)
Demographic characteristics
Age (years)
Median (IQR)	49 (41–58)	58 (49–64)	49 (41–58)	58 (48–64)
18–49—no. (%)	66 (50.8)	308 (26.4)	66 (50.8)	1015 (28.5)
50–59—no. (%)	41 (31.5)	350 (30)	41 (31.5)	1060 (29.7)
60–70—no. (%)	23 (17.7)	509 (43.6)	23 (17.7)	1490 (41.8)
Male sex—no. (%)	95 (73.1)	757 (64.9)	95 (73.1)	2337 (65.6)
White race—no. (%)	51 (39.2)	402 (34.4)	51 (39.2)	1252 (35.1)
Body mass index (kg/m2)
Median (IQR)	32.5 (29.5–37.9)	32.5 (28.1–39.1)	32.5 (29.5–37.9)	32.8 (28.4–39.5)
< 40—no. (%)	98 (75.4)	867 (74.3)	98 (75.4)	2618 (73.4)
≥ 40—no. (%)	21 (16.2)	261 (22.4)	21 (16.2)	831 (23.3)
Unknown—no. (%)	11 (8.5)	39 (3.3)	11 (8.5)	116 (3.3)
Coexisting conditions
Hypertension	62 (47.7)	682 (58.4)	62 (47.7)	2067 (58)
Diabetes mellitus	38 (29.2)	516 (44.2)	38 (29.2)	1524 (42.7)
Coronary artery disease	4 (3.1)	120 (10.3)	4 (3.1)	350 (9.8)
Congestive heart failure	2 (1.5)	108 (9.3)	2 (1.5)	324 (9.1)
Chronic obstructive pulmonary disease	4 (3.1)	86 (7.4)	4 (3.1)	264 (7.4)
Severity of illnessb
PaO2/FiO2, mmHg—median (IQR)	80 (65–99)	90 (70–128)	69 (60–80)	78 (66–89)
PEEP—median (IQR)	15 (12–18)	14 (10–16)	15 (12–18)	14 (12–18)
Shockc—no. (%)	81 (62.3)	622 (53.3)	104 (80)	2352 (66)
Lactate, mmol/l—median (IQR)	1.7 (1.2–2.5)	1.6 (1.1–2.3)	2.0 (1.4–3.1)	1.5 (1.1–2.1)
Arterial pH—median (IQR)	7.35 (7.29–7.45)	7.36 (7.28–7.42)	7.33 (7.28–7.39)	7.34 (7.27–7.39)
Secondary infection—no. (%)	11 (8.5)	83 (7.1)	26 (20)	595 (16.7)
Renal SOFA score—no. (%)d
0 (Cr < 1.2 mg/dl)	84 (64.6)	664 (56.9)	67 (51.5)	1595 (44.7)
1 (Cr 1.2–1.9 mg/dl)	29 (22.3)	250 (21.4)	34 (26.2)	752 (21.1)
2–4 (Cr > 2 mg/dl, UOP < 500 ml, RRTe)	17 (13.1)	253 (21.7)	29 (22.3)	1218 (34.2)
Liver SOFA score—no. (%)d
0 (Bilirubin < 1.2 mg/dl)	114 (87.7)	1058 (90.7)	109 (83.8)	3088 (86.6)
1 (Bilirubin 1.2– 1.9 mg/dl)	11 (8.5)	80 (6.9)	13 (10)	292 (8.2)
2–4 (Bilirubin ≥ 2 mg/dl)	5 (3.8)	29 (2.5)	8 (6.2)	185 (5.2)
Coagulation SOFA score—no. (%)d
0 (Platelet count ≥ 150 K/mm3)	109 (83.8)	995 (85.3)	108 (83.1)	3111 (87.3)
1 (Platelet count 100–149 K/mm3)	15 (11.5)	135 (11.6)	17 (13.1)	335 (9.4)
2–4 (Platelet count < 100 K/mm3)	6 (4.6)	37 (3.2)	5 (3.8)	119 (3.3)
Rescue therapies for hypoxemia—no. (%)f
Prone position ventilation	56 (43.1)	249 (21.3)	92 (70.8)	1651 (46.3)
Neuromuscular blockade	52 (40)	234 (20.1)	100 (76.9)	1678 (47.1)
Inhaled vasodilators	23 (17.7)	49 (4.2)	47 (36.2)	479 (13.4)

PaO partial pressure of arterial oxygen over the fraction of inspired oxygen, PEEP positive end expiratory pressure, RRT renal replacement therapy, SOFA Sequential Organ Failure Assessment, UOP urine output

aThe number of observations in the final cohort differs from the number of unique patients because more than one observation per patient was used, thereby creating a pseudo-cohort. This approach (described further in the supplemental methods) was used to eliminate the potential for immortal time bias

bSeverity of illness data are shown on the day of ICU admission for the unique patients and on the day of ECMO initiation or non-initiation for the final cohort

cShock is defined as the requirement for at least one vasopressor

dCategories 2, 3, and 4 of the renal, liver, and coagulation components of the SOFA score were binned due to low frequency of events

eIncludes both acute RRT as well as end-stage renal disease requiring RRT

fRescue therapies for hypoxemia were assessed on the day of ICU admission for the unique patients and up to and including the day of ECMO initiation or non-initiation for the final cohort

Among the 1297 patients included in the target trial, during a median follow-up of 38 days (IQR 25–55), a total of 598 patients (46.1%) died, including 45 of the 130 (34.6%) who received ECMO and 553 of the 1167 (47.4%) who did not (unadjusted HR 0.52; 95% CI 0.4–0.69). Figure 2a shows the unadjusted survival curves (log-rank p < 0.001). In the primary analysis, patients who received ECMO had a lower risk of death compared to those who did not (adjusted HR 0.55; 95% CI 0.41–0.74). Results of the full multivariable model are shown in Table E7. The estimated 60-day mortality was 35.3% (95% CI 27.2–43.5%) in the ECMO-treated patients and 47.9% (95% CI 44.9–50.8%) in the ECMO non-treated patients (risk difference 12.5%; 95% CI 4–21%). Interpretations were unchanged across all three sensitivity analyses, as well as analyses using alternative PaO2/FiO2 thresholds to define eligibility (Fig. 2b; Tables E8–E11). No interaction was observed between treatment assignment and the day of treatment initiation (p value for interaction 0.15).

Fig. 2

The estimated effect of ECMO on mortality. a Shows the unadjusted survival curves for ECMO-treated versus ECMO non-treated patients. b Shows the hazard ratios for survival for ECMO-treated versus ECMO non-treated patients. The following covariates were included in the multivariable models: age; sex; race; body mass index; hypertension; diabetes mellitus; coronary artery disease; congestive heart failure; chronic obstructive pulmonary disease; shock; suspected or confirmed secondary infection; the renal, liver, and coagulation components of the Sequential Organ Failure Assessment score [25, 26]; and receipt of rescue therapies for hypoxemia (prone position ventilation, neuromuscular blockade, and inhaled vasodilators, each assessed separately). Sensitivity analysis #1 treated hospital discharge as a competing risk rather than as a censoring event. Sensitivity analysis #2 matched each ECMO-treated patient on day 1 with two randomly selected eligible control patients (PaO2/FiO2 ratio < 100 mmHg while receiving invasive mechanical ventilation) who did not initiate ECMO, and the process was then repeated on days 2 through 7, with ECMO non-treated patients only being used once. Sensitivity analysis #3 was limited to patients with the following characteristics: < 65 years old; absence of coronary artery disease, congestive heart failure, and COPD; mechanically ventilated and with a PaO2/FiO2 ratio < 80 mmHg; and receipt of at least one rescue therapy for hypoxemia (prone position ventilation, neuromuscular blockade, or inhaled vasodilators) prior to ECMO initiation or non-initiation. ECMO extracorporeal membrane oxygenation, PaO/FiO partial pressure of arterial oxygen over the fraction of inspired oxygen

Discussion

This multicenter cohort study of 190 critically ill adults with COVID-19 who received ECMO at 35 sites across the United States found that nearly 70% of patients survived to hospital discharge or 60 days following ICU admission. In a target trial emulation, severely hypoxemic patients who received ECMO in the first 7 days of ICU admission had a considerably lower risk of death compared to those who did not.

The current study presents data from a large, geographically diverse cohort from the United States. ECMO was used in 3% of critically ill adults with COVID-19 in our study; in a recent multicenter European cohort study, 8% of critically ill patients with COVID-19 received ECMO [28]. The 60-day mortality rate of 33% that we observed for patients with COVID-19 treated with ECMO is similar to short-term mortality rates observed in ECMO-treated patients during prior pandemics, including mortality rates ranging from 28 to 37% among patients with H1N1 influenza [29, 30]. Our observed 60-day mortality rate is also similar to the 60-day mortality rate of 36% reported by a single-center study of 83 ECMO-treated patients with COVID-19 in France, and to the 90-day mortality rate of 37% reported in a large multinational ELSO study of over 1000 ECMO patients [18, 19].

The median age in our ECMO cohort was 49 years, and no patients over 70 were treated with ECMO. Patient selection guidelines for use of ECMO in COVID-19 are limited, and experts have suggested adhering to previously established protocols [2]. Over 70% of ECMO patients in our study underwent prone positioning prior to receiving ECMO, perhaps reflecting that the pandemic has spurred adoption of therapies that have been shown to have benefit but have previously been underutilized. The median pre-cannulation PaO2/FiO2 ratio in patients from our cohort was 72 mmHg, with over 80% of patients having a PaO2/FiO2 ratio below 100 mmHg, indicating severe hypoxemia, albeit not as severe as patients in the EOLIA trial. In the EOLIA trial, criteria for ECMO initiation included a PaO2/FiO2 ratio < 50 mmHg for more than 3 h or a PaO2/FiO2 ratio < 80 mmHg for more than 6 h [7]. Importantly, our sensitivity analyses performed in patients with PaO2/FiO2 < 80 and < 150 mmHg demonstrated similar hazard ratios for survival as our primary analysis.

The high rates of complications we observed in patients with COVID-19 who received ECMO underscores the importance of patient selection. The most common complications were secondary infections, acute kidney injury, thrombotic events, and bleeding. Furthermore, half of the patients who survived to hospital discharge required some form of rehabilitation post-discharge, suggesting high morbidity in these patients. On the other hand, our finding that half of the patients who survived to hospital discharge were discharged home is reassuring that favorable outcomes can be achieved with ECMO with proper selection of patients.

We also sought to determine the effect of ECMO on survival. When data from randomized trials are not available, observational analyses may be used to guide practice by adopting a target trial emulation approach [31-34]. Accordingly, we conducted a target trial emulation in which severely hypoxemic patients were categorized according to receipt or no receipt of ECMO in the first 7 days of ICU admission. We used analytic approaches to adjust for confounding and prevent immortal time bias. We found that severely hypoxemic patients treated with ECMO had a considerably lower risk of death compared to patients not treated with ECMO, with similar results across multiple sensitivity and subgroup analyses. Since randomized controlled trials of ECMO use in COVID-19 are unlikely to be feasible in the foreseeable future due to logistical challenges and inevitable cross-over, target trial emulation may offer the best available evidence on which to base current practice. Nevertheless, the findings from our target trial emulation, which are based on observational data, should be interpreted cautiously since we cannot exclude the potential for residual confounding.

Our study has several strengths. We collected granular data (over 800 unique data elements per patient) from a large number of consecutive critically ill patients with laboratory-confirmed COVID-19, thereby minimizing selection or surveillance bias at each center. We included patients from 55 geographically diverse sites from across the United States, thereby increasing the generalizability of our findings, and we excluded patients from centers not capable of performing ECMO. All data were obtained by detailed chart review rather than reliance on administrative or billing codes, which have well-described limitations [31, 35]. Whereas some prior studies of ECMO in COVID-19 have had limited follow-up, we followed patients until hospital discharge, death, or a minimum of 60 days, which allowed us to ascertain a definitive outcome (dead or discharged) in 95% of the patients who received ECMO. Finally, the results of our target trial emulation were consistent across multiple sensitivity analyses that used alternative methodological approaches, along with alternative thresholds of hypoxemia to define eligibility.

We also acknowledge several limitations. First, as with all observational analyses, we cannot rule out the possibility of residual confounding. For example, we did not account for varying degrees of hospital strain, which could affect outcomes in critical care during dynamic surges in patient volumes. Second, we acknowledge that sites may have varied in the criteria they used to determine ECMO candidacy. For example, use of rescue therapies for hypoxemia (prone positioning, neuromuscular blockade, and inhaled vasodilators) prior to ECMO initiation, and use of therapeutic anticoagulation during ECMO, were based on institutional standards of care during the pandemic and reflect site variation in practice. Importantly, our sensitivity analysis limited to a more homogeneous group of patients, including those who received at least one rescue therapy prior to ECMO initiation or non-initiation, found similar findings as our primary analysis. Third, inclusion criteria for our target trial emulation included assessment of the lowest PaO2/FiO2 in the 24 h preceding ECMO cannulation, unlike the EOLIA trial, which used a set duration of time below a PaO2/FiO2 threshold. Fourth, we did not collect longitudinal data on respiratory mechanics beyond 24 h or prone positioning during ECMO [36, 37], which could have been used to further assess lung rest, recovery, and recruitability. It should also be acknowledged that only modest reductions in tidal volumes and driving pressures were observed in the immediate post-ECMO period, somewhat in contrast with other studies demonstrating ultraprotective lung ventilation on ECMO [18, 38]. We also did not collect data on lung compliance in patients who did not receive ECMO. Fifth, for our descriptive analyses patients discharged prior to 60 days were assumed to still be alive at day 60, an assumption that may have overestimated the 60-day survival rate of ECMO recipients. However, we note that 97% of those discharged were either discharged home or to a rehabilitation facility, with only 3% having been transferred to another hospital.

Using data from a nationally representative and geographically diverse multicenter cohort study of critically ill adults with COVID-19 in the United States, we found that 190 patients were treated with ECMO. Among those treated with ECMO, two-thirds survived to hospital discharge or 60 days. Using target trial emulation, we found that selected patients with severe hypoxemic respiratory failure treated with ECMO in the first 7 days of ICU admission had a considerable reduction in mortality compared to those not treated with ECMO. Although clear indications for ECMO in COVID-19 patients are not explicitly provided in this cohort study, it is evident that a proportion of patients with severe COVID-19 respiratory failure may well benefit from ECMO. Further investigation is warranted to identify which COVID-19 patients may derive the greatest benefit from ECMO.

Below is the link to the electronic supplementary material.

Supplementary file1 (PDF 723 KB)

In this multicenter cohort study of critically ill adults with COVID-19, 190 of 5122 patients (3.7%) received ECMO, 127 (66.8%) of whom survived to hospital discharge or 60 days. After accounting for differences between groups, patients with severe hypoxemia (PaO2/FiO2 < 100) who received ECMO in the first 7 days of ICU admission had lower in-hospital mortality than patients who did not (hazard ratio 0.55; 95% CI 0.41–0.74).