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. 2020 Sep 17;82:29–37. doi: 10.1016/j.ejim.2020.09.006

Incidence of acute pulmonary embolism in COVID-19 patients: Systematic review and meta-analysis.

Loris Roncon a,1,⁎,1, Marco Zuin a,b,1, Stefano Barco c,d, Luca Valerio d, Giovanni Zuliani b, Pietro Zonzin a, Stavros V Konstantinides c,e
PMCID: PMC7498252  PMID: 32958372

Abstract

Background

Acute pulmonary embolism (PE) has been described as a frequent and prognostically relevant complication of COVID-19 infection.

Aim

We performed a systematic review and meta-analysis of the in-hospital incidence of acute PE among COVID-19 patients based on studies published within four months of COVID-19 outbreak.

Material and Methods

Systematic Reviews and Meta-Analyses (PRISMA) guidelines were followed in abstracting data and assessing validity. We searched Medline, Scopus and Web of Science to locate all articles published up to August 1, 2020 reporting the incidence of acute PE (or lung thrombosis) in COVID-19 patients. The pooled in-hospital incidence of acute PE among COVID-19 patients was calculated using a random effects model and presenting the related 95% confidence interval (CI). Statistical heterogeneity was measured using the Higgins I2 statistic.

Results

We analysed data from 7178 COVID-19 patients [mean age 60.4 years] included in twenty-three studies. Among patients hospitalized in general wards and intensive care unit (ICU), the pooled in-hospital incidence of PE (or lung thrombosis) was 14.7% of cases (95% CI: 9.9–21.3%, I2=95.0%, p<0.0001) and 23.4% (95% CI:16.7–31.8%, I2=88.7%, p<0.0001), respectively. Segmental/sub-segmental pulmonary arteries were more frequently involved compared to main/lobar arteries (6.8% vs18.8%, p<0.001). Computer tomography pulmonary angiogram (CTPA) was used only in 35.3% of patients with COVID-19 infection across six studies.

Conclusions

The in-hospital incidence of acute PE among COVID-19 patients is higher in ICU patients compared to those hospitalized in general wards. CTPA was rarely used suggesting a potential underestimation of PE cases.

Keywords: Pulmonary embolism, Covid-19, Epidemiology, Meta-analysis

1. Introduction

The outbreak of coronavirus disease 2019 (COVID-19) remains a severe public health emergency of international concern. Over the past months, several investigations have suggested an association between the COVID-19 pathogenesis and a pro-coagulant pattern that seems to be implicated in a higher risk of both arterial and venous thrombotic events [1], [2], [3], [4], [5], [6], [7]. In this regard, acute pulmonary embolism (PE) has emerged as a potential severe complication of the infection and both American and European consensus statement have suggested general recommendations to deal with these clinical events [8], [9], [10], [11]. However, the actual in-hospital incidence of acute PE in these patients has not yet been determined, but autopsy studies suggested that PE or lung thrombosis may represent a frequent cause of death in COVID-19 patients (Ref Ann Int Med). Indeed, radiological assessment with CT pulmonary angiography (CTPA) was not always feasible, especially in patients hospitalized in intensive care units (ICUs) during the first months of the pandemics, also due to critical illness and the frequent need of pronation during mechanical ventilation [12]. A more reliable estimation of the extent of this complication appears essential to guide the management of these patients. The aim of the present study is to perform a systematic review and meta-analysis on the in-hospital incidence of acute PE in COVID-19 patients hospitalized in general wards and ICUs based on studies published so far.

2. Material and methods

2.1. Study design and eligibility criteria

This study followed the Preferred Reporting Items for Systematic Reviews and Meta-analyses (PRISMA) reporting guideline (Supplementary file 1) [13]. Data were obtained searching MEDLINE, Scopus and Web of Science for all investigations published any time to August 1, 2020 reporting the occurrence of acute PE in COVID-19 patients during the hospitalization.

2.2. Outcomes

The in-hospital incidence of acute PE in COVID-19 patients hospitalized into intensive care unit (ICU) and general wards was chosen as the primary outcome. Conversely, the anatomic location of thromboembolism within the pulmonary arterial vasculature and the use of CTPA for the diagnosis of acute PE were selected as the secondary outcomes.

2.3. Data extraction and quality assessment

The selection of studies to be included in our analysis was independently conducted by 2 authors (L.R., M.Z.) in a blinded fashion. Any discrepancies in study selection was resolved by consulting a third author (P.Z.). The following MeSH terms were used for the search: “COVID-19″ AND (“Pulmonary embolism” OR “Thrombosis” OR “Venous thromboembolism”). Moreover, we searched the bibliographies of target studies for additional references. Case reports, review articles, abstracts, editorials/letters, and case series with less than 10 participants were excluded. Data extraction was independently conducted by 2 authors (M.Z., P.Z). Studies were excluded from the meta-analysis if they did not provide data regarding the incidence of acute PE among COVID-19 patients. For all studies reviewed we extracted the number of patients enrolled, the mean age, male gender, prevalence of common cardiovascular comorbidities (if reported), the number of acute PE observed in patients hospitalized in ICU or general wards, the use of CTPA and the anatomic location of pulmonary emboli. The quality of included studies was graded using the Newcastle-Ottawa quality assessment scale [14].

2.4. Data synthesis and analysis

Continuous variables were expressed as mean ± standard deviation (SD) or as median with corresponding interquartile range, categorical variables as counts and percentages. The cumulative in-hospital incidence of acute PE (n/N), defined as the ratio between patients experiencing acute PE (n) and the number of patients enrolled in each study (N), hospitalized in general wards and ICUs were pooled using a random effects model and presented with the corresponding 95% confidence interval (CI). Statistical heterogeneity was measured using the Higgins I2 statistic. A I2=0 was considered to indicate no heterogeneity, values of I2 as <25%, 25–75% and above 75% to indicate low, moderate, and high degrees of heterogeneity, respectively [15]. To evaluate publication bias both Egger's test and funnel plots were computed. Data regarding the anatomical distribution of intraluminal pulmonary artery filling defects and the use of CTPA were calculated by extracting numerators and denominators separately and independently from the individual studies. The difference between the main/lobar versus segmental/subsegmental pulmonary arteries was compared using the Pearson's χ2 test. All meta-analyses were conducted using Comprehensive Meta-Analysis software, version 3 (Biostat, USA).

3. Results

3.1. Search results and included studies

A total of 486 articles were obtained with our search strategy. After excluding duplicates and preliminary screening, 151 full-text articles were assessed for eligibility and 130 studies were excluded for not meeting the inclusion criteria, leaving 23 investigation fulfilling the inclusion criteria (Fig. 1 ) [1,3,4,8,12,[16], [17], [18], [19], [20], [21], [22], [23], [24], [25], [26], [27], [28], [29], [30], [31], [32], [33].

Fig. 1.

Fig. 1

Flow diagram of selected studies for the meta-analysis according to the Preferred reporting items for systematic reviews and meta-analyses (PRISMA).

3.2. Characteristics of the population and quality assessment

Overall, 7178 COVID-19 patients [mean age 60.4 years] were included in the analysis. The general characteristics of the studies included are showed in Table 1 . Although the concomitant comorbidities were not systematically recorded by all investigations, active cancer and previous venous thromboembolic events were reported in a small percentage of cases. Fourteen studies considered ICU patients [1,3,4,8,[16], [17], [18], [19], [20],22,25,26,28] while fifteen provided data of subjects hospitalized in general wards [1,8,17,20,21,23,24,[26], [27], [28], [29], [30], [31], [32], [33]. Seven studies reported the data of both ICU and general wards patients [1,8,17,19,20,26,28]. Quality assessment showed that all studies were of moderate-high quality according to the NOS scale (Supplementary file 2) [14].

Table 1.

General characteristics of the population enrolled. The summary datarefer to the entire population of each study. Frequencies are reported as count (%). []: Interquartile range; ICU: Intensive care unit; NOS: Newcastle-Ottawa quality assessment scale; NR: Not reported; SD: Standard deviation: VTE: Venous Thromboembolism.

Author Study design Mean age (years) Number of patients Males N, (%) Arterial hypertension N, (%) Diabetes N, (%) Active cancer N, (%) Cerebrovascular disease Previous VTE Setting NOS
ICU General wards
Lodigiani et al. [1] Retrospective
Single center
66 [55–75] 388 264
(58)
183
(47)
88
(23)
25
(6)
20
(5)
12
(3)
X X 8
Poissy et al. [16] Retrospective
Single center
57 107 13/22⁎⁎
(59.1)
NR NR NR NR NR X 7
Grillet et al. [17] Retrospective
Single center
66 (SD:13) 100 70
(70)
NR 20
(20)
20
(20)
NR NR X X 7
Leonard-Lorant [8] Retrospective
Double-center
63.5 106 70
(66)
NR NR NR NR NR X X 7
Llitjos et al. [3] Retrospective
Double-center
68 [51.7–74.5] 26 20
(77)
22
(85)
NR 0 NR 1
(4)
X 7
Klok et al. [18] Retrospective multicenter 64 (SD:12) 184 139
(76)
NR NR 5
(3)
NR NR X 8
Thomas et al. [19] Retrospective Single center 59 (SD:13) 63 44
(69)
NR NR NR NR NR X X 7
Middeldorp et al. [20] Retrospective single center 61 (SD:14) 198 130
(66)
NR NR 7
(3)
NR 11
(5)
X X 8
Helms et al. [4] Retropsective Multicenter 63 [53–71] 150 122
(81)
NR 30
(20)
9
(6)
72
(48)
8
(5)
X 8
Galeano-Valle et al. [21] Prospective
Single center
64.3 (SD:14.4) 24 14
(58.)
NR NR 1
(4)
NR NR X 8
Bompard et al. [12] Retrospective
Double center
64 [64–76] 135 94
(70)
NR NR NR NR NR X * 7
Soumagne et al. [22] Retrospective
Multicenter
63.5
(SD:10.1)
375 288
(77)
216
(58)
99
(26)
44
(12)
NR NR X 7
Freund et al. [23] Retrospective
Multicenter
61.0
(SD: 19)
3253 1558
(47.8)
1294
(40)
NR 442
(13.5)
NR
385
(11.8)
7
Chen et al. [24] Retrospective
Single center
65 [56.5–70] 25 15
(60)
10
(40)
5
(20.0)
0 NR NR X 7
Longhcamp et al. [25] Retrospective
Single center
68
(SD: 11)
25 16
(64)
10
(40)
1
(4)
2
(8)
NR 0 X 6
Whyte et al. [26] Retrospective
Single center
61.5 214 129
(60.2)
NR NR 16
(7)
NR 21
(10)
X X 7
Marone et al. [27] Retrospective
Single center
NR 101 NR NR NR NR NR NR X 5
Fauvel et al. [28] Retrospective
Multicenter
64
(SD:17)
1240 721
(58)
559
(45)
268
(22)
167
(13.5)
94
(8)
98
(8)
X X 8
Van den Heuvel [29] Retrospective
Single center
63
[51–68]
51 41
(80)
21
(41)
9
(18)
NR 2
(4)
NR X 6
Mestre-Gomez et al. [30] Retrospective
Single center
65
[56–73]
29 21
(72)
12
(41)
3
(10.0)
5
(17)
1
(3)
1
(3.4)
X 7
van Dam et al. [31] Retrospective
Single center
63
(SD:6.4)
23 16
(70)
NR NR 1
(4)
NR 1
(4)
X 7
Gervaise et al. [32] Retrospective
Single center
62.3
(SD:17.8)
72 54
(75)
NR NR NR NR NR X 6
Trimaille et al. [33] Retrospective
Single center
62.2
(SD:17.0)
289 171
(59)
132
(46)
59
(20)
8
(3)
NR 28
(10)
X 8

Only ICU patients were considered in the analysis since some cases of acute pulmonary embolism in non-ICU setting were also observed in outpatients.

⁎⁎

Referred to patients with acute Pulmonary embolism.° Emergency department (ED).

3.3. Pooled in-hospital incidence of acute pulmonary embolism in icu and general wards

The cumulative in-hospital rate of acute PE in COVID-19 patients hospitalized in general wards ranged between 1.6 to 62.5% among six studies [1,8,17,20,21,23,24,[26], [27], [28], [29], [30], [31], [32], [33]. A random effect model revealed a pooled incidence of acute PE in 14.7% of cases (95% CI: 9.9–21.3%, I2=95.0%) (Fig. 2 , panel A). Higher rates were reported in ICU patients, ranging between 4.2 to 75.0% in the ten studies reviewed [1, 3,4,8,[16], [17], [18], [19], [20],22,25,26,28]. In these patients, a pooled cumulative incidence rate of acute PE was 23.4% (95% CI:16.7–31.8%, I2=88.7%) (Fig. 2, panel B).

Fig. 2.

Fig. 2

Forest plots investigating the pooled incidence of acute pulmonary embolism in COVID-19 patients hospitalized in ICU (A) and in general wards (B).

3.4. Assessment of publication bias

The Egger's tests revealed no evidences of publication bias in estimating the pooled incidence of acute PE among patients admitted in general wards or ICU (t = 0.065, p = 0.978 and t = 0.591, p = 0.565, respectively). A visual assessment of the funnel plot cannot reassure about the presence of an asymmetry with studies characterized by higher PE rate being missing at the basis of the triangle (Supplementary file 3).

3.5. Imaging techniques adopted and deep vein thrombosis

Most of the studies reviewed used CTPA for the diagnosis of PE. Only one study reported the use of transthoracic echocardiography in two patients for the diagnosis [3]. Prophylactic and therapeutic anticoagulation resulted largely used in the studies reviewed using different drugs such as enoxaparin, dalteparin and unfractionated heparin (UFH) as well as different regimens. However, very few investigations reported the number of PE patients treated before the diagnosis of acute PE, as shown in Table 2 . The analysis of the prevalence of concomitant DVT [1,[21], [22], [23], [24], [25], [26], [27], [28],30,33] ranged between 1.5% [8] to 33.3% [27].

Table 2.

Anatomical sites of acute pulmonary embolism and percentages of imaging assessment performed to assess pulmonary thromboembolic events.NR not reported; NA: not applicable (retrospective studies); CTPA: Computed tomography pulmonary angiography; CUS: Compression ultrasonography. Follow-up was available only in prospective studies but one of this did not reported the length [21].

Author Imaging techniques Thromboprophylaxis DVT Follow-up Sites of intraluminal pulmonary arterial filling defects Imaging test performed (CTPA)
Main (%) Lobar (%) Segmental (%) Subsegmental (%) (%)
Lodigiani et al. [1] CTPA
Two
point CUS in ICU
Whole
leg ultrasound in general wards
Enoxaparin
or
Nadroparin
NR for PE patients
(only reported 100% of ICU patients)
PE±DVT and isolated DVT reported separately NA NR 30.0 10.0 33
Poissy et al. [16] CTPA LWMH
or
UFH
In 20/22 patients
NR for PE patients
3/22 (13.6) NA 10.0 *
40.0⁎⁎
55.0 NR 31.8
Grillet et al. [17] CTPA NR NR for PE patients NA 0 43.4 100 0 35.7
Leonard-Lorant [8] CTPA LMWH
25/32 (78%)
NR for PE patients NA 21.8 34.3 28.1 15.6 63.0
Llijtos et al. [3] CTPA (in 4 patients)
TEE (in 2 patients)
Limb ultrasound
8 (31%) prophylactic anticoagulation
18 (69%) therapeutic anticoagulation
NR for PE patients
NR for PE patients NA NR NR NR NR NR
Klok et al. [18] CTPA
Limb Ultrasound
Nadroparin in all patients with different regimens NR for PE patients NA 70.7 29.2 NR
Thomas et al. [19] CTPA
Limb Ultrasound
Prophylactic dalteparin in all patients
NR for PE patients
NR for PE patients NA 20 0 60.0 20 17.4
Middeldorp et al. [20] CTPA
Limb ultrasound
Thromboprophylaxis with nadroparin in
167 patients (84%)
19 patients (9.6%) continued therapeutic anticoagulation
Defined as PE±DVT 17 7.6 76.9 15.3 NR
Helms et al. [4] CTPA LMWH or UFH
Prophylactic dose 105 (70)
Therapeutic dose 45 (60)
NR for PE patients 7 37.5 33.3 20.8 12.5 NR
Galeano-Valle et al. [21] CTPA
CUS
Enoxaparin or Bemiparin
In 19/24 patients
4/11 (36.3) NR 13.3 46.6 86.6 46.6 NR
Bompard et al. [12] CTPA Enoxaparin in all patients at prophylactic dose NR for PE patients 26 31.2 65.2 12.5 53 °
Soumagne et al. [22] CTPA NR 35
(9.3)
NR NR NR NR 14.6
Freund et al. [23] CTPA NR 101
(11)
NR NR NR NR 15
Chen et al. [24] CTPA NR 1
(4)
NR 0 25 (100) 25 (100) 0 100
Longhcamp et al. [25] CTPA Intravenous
heparin infusion
or
enoxaparin
6
(24)
0 3
(60)
2
(40)
0 28
Whyte et al. [26] CTPA Enoxaparing or
UFH
7
(8.7)
NR 3
(3.7)
NR 28
(35)
13
(16.2)
14.4
Marone et al. [27] CTPA
CUS
LMWH 8
(33.3)
10 NR NR NR NR NR
Fauvel et al. [28] CTPA LMWH
738 (63.0)
18
(1.5)
NR NR NR NR NR 43.0
Van den Heuvel [29] CTPA NR NR NR NR NR NR NR 92
Mestre-Gomez et al. [30] CTPA LMWH
23 (79.3)
2
(6.9)
NR 9
(31)
20
(69)
NR
van Dam et al. [31] CTPA (100)
Not specified the drug
0 NR 4
(17)
16
(70)
3
(13)
NR
Gervaise et al. [32] CTPA NR NR NR 2
(15)
4
(30)
7
(55)
0 49.3
Trimaille et al. [33] CTPA Enoxaparin 12
(24.5)
NR NR NR NR NR 34.6

Defined as proximal;.

⁎⁎

Defined as bilateral. °Performed due to clinical deterioration.

3.6. Anatomical location of acute pulmonary embolism and use of ctpa

The studies reviewed did not systematically report the anatomical location of the pulmonary emboli in the arterial tree or classified the anatomical location heterogeneously. In fifteen studies that reported the former information, arterial filling defects at CTPA, calculated by extracting numerators and denominators separately and independently from the individual studies, involved the main, lobar, segmental and subsegmental pulmonary arteries in 8.3% (n = 85/1023), 7.8%, (n = 102/1299), 12.2% (n = 189/1544) and 11.4 (n = 107/1025) of cases, respectively [1,4,8,[16], [17], [18], [19], [20], [21],24,25,27,30,31]. Segmental/sub-segmental were more frequently involved compared to main/lobar arteries (6.8% vs18.8%, p<0.001) (Fig. 3 ). Moreover, in the thirteen studies that reported how many patients underwent CTPA, it was used only in 35.3% (n = 1957/5532) of patients with COVID-19 infection (Table 2) [1,8,12,16,17,19,[24], [25], [26],28,[31], [32], [33].

Fig. 3.

Fig. 3

Comparison of the proximal and distal distribution of intraluminal pulmonary arterial filling defects.

4. Discussion

We performed a pooled analysis of the rate of acute PE in COVID-19 patients including data collected during the first months after the COVID-19 outbreak. The in-hospital rate of acute PE was higher in ICU patients than in those hospitalized in general wards. The most common sites in which pulmonary filling defect were observed using CTPA appeared to be the lobar and segmental pulmonary arteries. However, CTPA was only used in a selected group of patients, approximately one-third of total, indicating that underdiagnosis was likely and, consequently, missed PE events may have contributed to the high mortality recorded among COVID-19 hospitalized patients. This uncertainty is reflected by the extreme clinical and statistical heterogeneity of these results.

Previous analyses have estimated a significant lower incidence of acute PE in the ICU population, which generally increase in mechanically ventilated patients [34,35]. The high incidence of acute PE in critically ill patients may reflect a more severe pro-coagulant state [36], [37], [38], [39]. Indeed, as shown by the general characteristics of the patients reviewed, both active cancer and previous venous thromboembolic events were uncommon and unlikely to explain the burden of thromboembolic complications beyond a contributing role.

Our results have several implications for clinical practice. First, the high rate of acute PE in COVID-19 patients makes it urgent to establish the optimal antithrombotic regimen that may minimize the risk of thromboembolic events in these patients. In this regard, recent analyses and perspectives have proposed different therapeutic and prophylactic regimens but the debate is still ongoing [40,41]. Second, it appears clear that the diagnosis of acute PE is largely underestimated in COVID-19 patients. Indeed, only one third of patients underwent CTPA for diagnostic purposes. Yet, recent autoptic studies performed in COVID-19 patients have demonstrated the presence of arterial emboli involving both major pulmonary arteries and microthrombi involving the more distal arterial vessels [42], [43], [44]. Indeed, these two scenarios may coexist: local “immunothrombosis” triggered by the viral infection and “classic” venous thromboembolism caused by major transient provoking risk factors, including bed rest, the presence of catheters, and hypoxemia, as well as age and the presence of concomitant conditions. Moreover, local endothelial cell dysfunction in the pulmonary microvasculature also seems to play a substantial role in the thromboinflammatory processes. In this regard, both cytokine storm and/or macrophage activation syndrome (MAS) could trigger the expression of active tissue factor (TF) within the lungs, further activating the coagulation cascade [45]. It remains to be elucidated whether “immunotrombosis” can be prevented by standard thromboprophylaxis and can be cured by available anticoagulant regiments.

During the current COVID-19 pandemic, the traditional diagnostic algorithms have been frequently overturned to limit the risk of infection for both operators and outpatients, limiting the execution of radiological examinations to minimize intrahospital transfers [46]. Indeed, there are obvious difficulties in perform CTPA in mechanical ventilated patients, especially when it requires pronation. Some of the reviewed studies evidenced that CTPA was performed in the event of further clinical and/or respiratory deterioration in ICU patients [3,12]. To reduce the burden of acute PE in these patients it seems essential to promote serial assessment using bedside transthoracic echocardiographic (TTE), electrocardiograms, assessment of myocardial injuries biomarkers [47,48] and compression ultrasonography (CUS), which may detect early, indirect signs that raise the suspicion of acute PE. A low threshold to suspect PE appears reasonable in this setting. At the same time, separate intra-hospital paths for the transfer of patients to radiological wards would permit the diagnosis of acute PE while minimizing the risk of infection.

A multinational registry, the COVID-19 Registry on Thrombosis and Thromboembolic complications (CORE-THROMBOSIS), is recruiting to provide representative data on the magnitude of the problem and enable us to formulate robust hypotheses to be tested in future trials [49].

4.1. Limitations

Our study has several limitations related to the observational nature of the studies reviewed and their own limitations with all inherited biases. In particular, potential underestimation could derive from detection bias if PE was not searched systematically or suspected based on systematic criteria, and CTPA may only have been carried out in patients with a clinical condition severe enough to raise the suspicion that other factors than the infection were at play. Sampling bias by the competing risk of death may also have led to underestimation of the real cumulative incidence of PE. At the same manner, we cannot assess if an adequate prophylactic anticoagulation was consistently administered in each study because these data were not systematically provided in the review investigations. Moreover, the hospitalization length can represent another potential source of bias since is strictly related immobilization [50]. This late aspect could explain the higher pooled cumulative in-hospital PE incidence in ICUs compared to general wards since ICU hospitalization, and immobilization, is generally longer. Few investigations on the COVID-19 infection have analysed the incidence of acute PE as a complication of COVID-19 infection, limiting the number of the studies included into the meta-analysis and the corresponding number of patients.

5. Conclusions

The pooled incidence of acute PE among COVID-19 patients was higher in ICU patients compared with patients hospitalized in general wards. Available data may underestimate the real incidence of acute PE as a complication of COVID-19 infection. A clinical and radiological distinction between acute PE and local “immunothrombosis” is impossible based on the available data and its therapeutic consequences remain to be investigated. Appropriate diagnostic strategies must be promoted to enhance the diagnosis of acute PE in these patients to reduce the mortality rate [51].

Declaration of Competing Interest

S.B. reports personal fees from Biocompatibles Group UK and Bayer HealthCare, non-financial support from Bayer HealthCare and Daiichi Sankyo, outside the submitted work.

S.V.K. reports grants and non-financial support from Bayer AG; grants and personal fees from Boehringer Ingelheim, personal fees from Bayer AG, grants and personal fees from Actelion, grants and personal fees from Daiichi-Sankyo, grants and personal fees from Biocompatibles Group UK, personal fees from Pfizer—Bristol-Myers Squibb, grants and personal fees from MSD, outside the submitted work

The other authors have no conflicts of interest to report.

Footnotes

Supplementary material associated with this article can be found, in the online version, at doi:10.1016/j.ejim.2020.09.006.

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