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CC BY 4.0 · TH Open 2021; 05(03): e411-e414
DOI: 10.1055/a-1585-9536
Letter to the Editor

Thrombembolic Events in Hospitalized COVID-19 Patients: What is the Role of the Sex?

Irit Nachtigall
1   Helios Kliniken Ost and Klinikum Emil-von-Behring, Berlin, Germany
2   Heart Center Leipzig at University of Leipzig and Leipzig Heart Institute, Leipzig Germany
,
Sven Hohenstein
2   Heart Center Leipzig at University of Leipzig and Leipzig Heart Institute, Leipzig Germany
,
Andreas Bollmann
2   Heart Center Leipzig at University of Leipzig and Leipzig Heart Institute, Leipzig Germany
,
Marzia Bonsignore
3   Evangelische Kliniken Gelsenkirchen, Zentrum für Krankenhaushygiene und Infektiologie, Gelsenkirchen, Germany
,
Daniela Husser
2   Heart Center Leipzig at University of Leipzig and Leipzig Heart Institute, Leipzig Germany
,
Ralf Kuhlen
4   Helios Health, Berlin, Germany
,
Andreas Meier Hellmann
5   Helios Kliniken GmbH, Berlin, Germany
› Author Affiliations
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Over a year ago, the WHO declared COVID-19 a pandemic; from then on, all hopes were on the development of vaccines. So far, 4 vaccines have been approved in Europe. On March 11th, 2021, the European Medicines Agency (EMA) reported ∼30 cases of thromboembolic events (TE) that were observed within 2 weeks after vaccinations with the AstraZeneca vaccine Vaxzevria, mostly being cerebral venous sinus thromboses in women younger than 60 years. Ca. 5 million people had received Vaxzevria in the EEA by then. Several European countries stopped their vaccinations with Vaxzevria temporarily.

COVID-19 infections increase the risk of developing TE. It has not yet been reported whether women develop more TE under Covid-19 than men. The aim of the present study was to determine the frequency, sex distribution and risk factors of TE among SARS-CoV-2 positive patients.

Methods

We analyzed claims data from 83 hospitals in the Helios Group. All patient 19,501 cases admitted between February 1st, 2020 and February 8th, 2021 with the International Statistical Classification of Diseases and Related Health Problems (ICD-10) code U07.1 (= PCR-confirmed infection with SARS-CoV-2), were included.

The following ICD-10 codes were used as definitions: Thrombocytopenia: D69.5, D69.6, pulmonary embolism: I26, thrombosis: I80, I81, I82, sinus vein thrombosis: G08, I67.6, I63.6. Only cases which were completed in the hospital, were included for hospital mortality (n = 8,533).

We used the R software for statistical programming (version 4.0.2) for all analyses. The multivariable analyses of TE and in-hospital mortality were analyzed via logistic regression with log link function. In these models, we used sex, age (as numerical variable), comorbidities, and the frailty risk score[1] as predictors; in the models for in-hospital mortality, TE was an additional predictor.


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Results

19,501 patients aged 0 - 103y (median 74y, Q25 = 59y, Q75 = 83y), 9,537 women (48.91%) and 9,964 men (51.09%) were included for the whole analysis, for calculation of the mortality 8,533 cases (85.64%) were included. Patient characteristis of the total cohort and the subcohort with thromboembolic events are shown in [Table 1]. At least one TE was coded in 963 patients (4.94%) (433 pulmonary embolisms, 371 thrombocytopenias, 249 thromboses and 2 sinus vein thromboses, several events per patient being possible), incidence rate was 4,938 (per 100,000 cases; 95% CI: 4640–5254). TE occurred in 4.94% of all inpatients; men were affected by 5.73% (571 / 9.964) and women by 4.11% (392 / 9,537). The distribution of age and sex in thrmoboembolic events is shown in [Figure 1]. In the multivariate regression analysis, independent risk factors for developing TE were among others male sex, lymphomas, liver diseases and congestive heart failure ([Table 2]). TE were associated with an increased risk of death; the mortality rate was 20.7% in the group without TE and 39.8% in the group with such an event. (OR 2.28; 95% Cl 1.93–2.70).

Table 1

Patient characteristics of the total cohort and the subcohort of patients with thromboembolic events (TE)

Group

Total cohort

TE cohort

Proportion (n)

Sex

 Male

51.1% (9,964)

59.3% (571)

 Female

48.9% (9,537)

40.7% (392)

Age

Mean (SD)

69.2 ± 18.7

69.9 ± 14.4

 ≤ 17 years

1.5% (290)

0.2% (2)

 18 − 29 years

3.2% (616)

0.8% (8)

 30 − 39 years

3.9% (762)

3.2% (31)

 40 − 49 years

5.6% (1,099)

4.5% (43)

 50 − 59 years

11.5% (2,238)

13.0% (125)

 60 − 69 years

15.1% (2,952)

21.8% (210)

 70 − 79 years

21.7% (4,229)

26.8% (258)

 80 − 89 years

30.2% (5,894)

24.8% (239)

 ≥ 90 years

7.3% (1,421)

4.9% (47)

Elixhauser comorbidity index

Mean (SD)

10.6 ± 11.2

21.3 ± 12.8

 < 0

13.3% (2,586)

2.5% (24)

 0

17.3% (3,365)

1.8% (17)

 1–4

5.4% (1,050)

1.5% (14)

 ≥ 5

64.1% (12,500)

94.3% (908)

Congestive heart failure

 no

76.2% (14,863)

68.0% (655)

 yes

23.8% (4,638)

32.0% (308)

Cardiac arrhythmias

 no

74.1% (14,443)

68.8% (663)

 yes

25.9% (5,058)

31.2% (300)

Valvular disease

 no

92.6% (18,052)

89.5% (862)

 yes

7.4% (1,449)

10.5% (101)

Pulmonary circulation disorders

 no

95.3% (18,594)

52.6% (507)

 yes

4.7% (907)

47.4% (456)

Peripheral vascular disorders

 no

92.6% (18,054)

90.4% (871)

 yes

7.4% (1,447)

9.6% (92)

Hypertension, uncomplicated

 no

56.2% (10,955)

59.4% (572)

 yes

43.8% (8,546)

40.6% (391)

Hypertension, complicated

 no

88.5% (17,265)

85.9% (827)

 yes

11.5% (2,236)

14.1% (136)

Paralysis

 no

95.1% (18,552)

95.2% (917)

 yes

4.9% (949)

4.8% (46)

Other neurological disorders

 no

91.2% (17,785)

89.9% (866)

 yes

8.8% (1,716)

10.1% (97)

Chronic pulmonary disease

 no

88.5% (17,267)

89.8% (865)

 yes

11.5% (2,234)

10.2% (98)

Diabetes, uncomplicated

 no

83.2% (16,221)

80.9% (779)

 yes

16.8% (3,280)

19.1% (184)

Diabetes, complicated

 no

88.4% (17,231)

88.7% (854)

 yes

11.6% (2,270)

11.3% (109)

Hypothyroidism

 no

87.7% (17,109)

88.6% (853)

 yes

12.3% (2,392)

11.4% (110)

Renal failure

 no

69.0% (13,460)

70.6% (680)

 yes

31.0% (6,041)

29.4% (283)

Liver disease

 no

96.0% (18,725)

87.7% (845)

 yes

4.0% (776)

12.3% (118)

Peptic ulcer disease excluding bleeding

 no

99.9% (19,487)

99.8% (961)

 yes

0.1% (14)

0.2% (2)

AIDS/HIV

 no

100.0% (19,494)

99.9% (962)

 yes

0.0% (7)

0.1% (1)

Lymphoma

 no

99.3% (19,358)

97.0% (934)

 yes

0.7% (143)

3.0% (29)

Metastatic cancer

 no

97.7% (19,044)

95.2% (917)

 yes

2.3% (457)

4.8% (46)

Solid tumor without metastasis

 no

95.1% (18,547)

92.3% (889)

 yes

4.9% (954)

7.7% (74)

Rheumatoid artritis/collaged vascular disease

 no

98.2% (19,157)

97.6% (940)

 yes

1.8% (344)

2.4% (23)

Coagulopathy

 no

95.5% (18,625)

57.7% (556)

 yes

4.5% (876)

42.3% (407)

Obesity

 no

88.3% (17,216)

85.6% (824)

 yes

11.7% (2,285)

14.4% (139)

Weight loss

 no

89.4% (17,436)

80.0% (770)

 yes

10.6% (2,065)

20.0% (193)

Fluid and electrolyte disorders

 no

57.4% (11,198)

42.8% (412)

 yes

42.6% (8,303)

57.2% (551)

Blood loss anemia

 no

99.5% (19,403)

98.5% (949)

 yes

0.5% (98)

1.5% (14)

Deficiency anemia

 no

96.6% (18,845)

94.7% (912)

 yes

3.4% (656)

5.3% (51)

Alcohol abuse

 no

98.1% (19,134)

96.2% (926)

 yes

1.9% (367)

3.8% (37)

Drug abuse

 no

99.6% (19,430)

99.9% (962)

 yes

0.4% (71)

0.1% (1)

Psychoses

 no

98.7% (19,256)

99.1% (954)

 yes

1.3% (245)

0.9% (9)

Depression

 no

94.0% (18,334)

94.6% (911)

 yes

6.0% (1,167)

5.4% (52)
Table 2

Results of multivariable analyses of thromboembolic complications

Variable

OR (95% CI)

P value

Age

1.00 (0.99 − 1.00)

0.10

Female sex

0.73 (0.63 − 0.83)

< 0.01

Frailty risk score

1.04 (1.02 − 1.05)

< 0.01

Congestive heart failure

1.40 (1.17 − 1.68)

< 0.01

Cardiac arrhythmias

1.06 (0.90 − 1.24)

0.51

Valvular disease

1.22 (0.96 − 1.54)

0.10

Peripheral vascular disorders

1.07 (0.84 − 1.36)

0.59

Hypertension, uncomplicated

0.81 (0.69 − 0.94)

< 0.01

Hypertension, complicated

0.87 (0.69 − 1.11)

0.26

Paralysis

0.67 (0.48 − 0.93)

0.02

Other neurological disorders

0.92 (0.73 − 1.16)

0.47

Chronic pulmonary disease

0.75 (0.60 − 0.93)

< 0.01

Diabetes, uncomplicated

1.05 (0.89 − 1.26)

0.55

Diabetes, complicated

0.85 (0.67 − 1.07)

0.18

Hypothyroidism

0.93 (0.75 − 1.15)

0.48

Renal failure

0.66 (0.56 − 0.78)

< 0.01

Liver disease

2.94 (2.33 − 3.70)

< 0.01

AIDS/HIV

2.36 (0.27 − 20.89)

0.44

Lymphoma

5.19 (3.36 − 8.00)

< 0.01

Metastatic cancer

1.65 (1.07 − 2.55)

0.02

Solid tumor without metastasis

1.22 (0.86 − 1.71)

0.26

Rheumatoid artritis/collaged vascular disease

1.43 (0.92 − 2.21)

0.11

Obesity

1.24 (1.02 − 1.51)

0.03

Weight loss

1.57 (1.32 − 1.88)

< 0.01

Fluid and electrolyte disorders

1.43 (1.23 − 1.67)

< 0.01

Deficiency anemia

1.27 (0.93 − 1.72)

0.13

Alcohol abuse

0.96 (0.65 − 1.41)

0.84

Quality of regression model tested with the Hosmer-Lemeshow test, indicating good calibration (χ2 = 23.556; p = 0.428).


Zoom Image
Fig. 1 Proportion of patients with at least one thromboembolic event in Covid-19 inpatients by age and sex.

#

Discussion

In our cohort of Covid-19 inpatients, TE occurred in approx. 5%; involved mostly pulmonary embolisms and affected mainly men in their 60ies. In addition to various pre-existing conditions, we found the male sex to be a major independent risk factor for the development of TE. TE are a common complication of COVID-19 and have been reported to occur in ca. 7% of inpatients treated with thromboembolism prophylaxis.[2] Several possible pathomechanisms have been discussed, including a direct endothelial damage[3] as well as an antibody-mediated activation of platelets via the Fcγ-IIa receptor.[4] Men are at an increased risk of a severe course of Covid-19[5]; TE are presumably part of this multifactorial, gender-specific risk.

The antibody-mediated activation of platelets via the Fcγ-IIa receptor has also been suggested as pathomechanism for TE after Vaxzevria.[6] It is unclear, why younger women seem to be affected more often by this complication. In general, sinus vein thromboses occur mostly in younger women.[7] The EMA reviewed 62 cases of cerebral venous sinus and 24 of splanchnic vein thromboses reported until March 22th, 2021. Although most of the cases reported have occurred in women <60y, no specific risk factors like sex or age were confirmed; the risk for TE after the vaccinations was estimated at 1: 100 000.

In summary, we found that a large number of Covid-19 inpatients have thromboembolic complications, at a frequency that is 5000 times higher than the one of TE after Vaxzevria. Although similar pathomechanisms have been discussed for both, the development of TE in Covid-19 and after vaccination, these two phenomena differ clearly in the type of thromboses that occur and in the sex distribution. The observational design of our study based on claims data are a strong limitation; at best, the results can provide a signal, especially information on medications and their different impact on both sexes need to be addressed. To our opinion, the sex aspect of thromboembolic events in Covid-19 and after Vaxzevria has not been adequately addressed so far and needs further investigation.


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Conflict of Interest

RK declares to hold shares of Fresenius, all other authors declare not to have any conflicts of interest.

  • References

  • 1 Gilbert T, Neuburger J, Kraindler J. et al. Development and validation of a Hospital Frailty Risk Score focusing on older people in acute care settings using electronic hospital records: an observational study. Lancet 2018; 391 (10132): 1775-1782 DOI: 10.1016/S0140-6736(18)30668-8.
    CrossrefPubMedGoogle Scholar
  • 2 Aktaa S, Wu J, Nadarajah R. et al. Incidence and mortality due to thromboembolic events during the COVID-19 pandemic: Multi-sourced population-based health records cohort study. Thromb Res 2021; 202: 17-23 DOI: 10.1016/j.thromres.2021.03.006.
    CrossrefPubMedGoogle Scholar
  • 3 Harenberg J, Violi F. Waves of SARS-CoV-2 Infection and Blood Coagulation-A Link and Beyond. Thromb Haemost 2021; 121 (01) 4-6
    Article in Thieme ConnectPubMedGoogle Scholar
  • 4 Althaus K, Marini I, Zlamal J. et al. Antibody-induced procoagulant platelets in severe COVID-19 infection. Blood 2021; 137 (08) 1061-1071 DOI: 10.1182/blood.2020008762.
    CrossrefPubMedGoogle Scholar
  • 5 Nachtigall I, Lenga P, Jóźwiak K. et al. Clinical course and factors associated with outcomes among 1904 patients hospitalized with COVID-19 in Germany: an observational study. Clin Microbiol Infect 2020; 26 (12) 1663-1669 DOI: 10.1016/j.cmi.2020.08.011.
    CrossrefPubMedGoogle Scholar
  • 6 Greinacher A, Thiele T, Warkentin TE, Weisser K, Kyrle PA, Eichinger S. Thrombotic Thrombocytopenia after ChAdOx1 nCov-19 Vaccination. N Engl J Med 2021; 384 (22) 2092-2101 DOI: 10.1056/NEJMoa2104840.
    CrossrefPubMedGoogle Scholar
  • 7 Ferro JM, Canhão P, Stam J, Bousser MG, Barinagarrementeria F. ISCVT Investigators. Prognosis of cerebral vein and dural sinus thrombosis: results of the International Study on Cerebral Vein and Dural Sinus Thrombosis (ISCVT). Stroke 2004; 35 (03) 664-670
    CrossrefPubMedGoogle Scholar

Address for correspondence

Irit Nachtigall, MD
Helios Kliniken Ost and Klinikum Emil-von-Behring
Walterhöfer Str 11, Berlin
Germany   

Publication History

Accepted Manuscript online:
12 August 2021

Article published online:
21 September 2021

© 2021. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution License, permitting unrestricted use, distribution, and reproduction so long as the original work is properly cited. (https://creativecommons.org/licenses/by/4.0/)

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

  • References

  • 1 Gilbert T, Neuburger J, Kraindler J. et al. Development and validation of a Hospital Frailty Risk Score focusing on older people in acute care settings using electronic hospital records: an observational study. Lancet 2018; 391 (10132): 1775-1782 DOI: 10.1016/S0140-6736(18)30668-8.
    CrossrefPubMedGoogle Scholar
  • 2 Aktaa S, Wu J, Nadarajah R. et al. Incidence and mortality due to thromboembolic events during the COVID-19 pandemic: Multi-sourced population-based health records cohort study. Thromb Res 2021; 202: 17-23 DOI: 10.1016/j.thromres.2021.03.006.
    CrossrefPubMedGoogle Scholar
  • 3 Harenberg J, Violi F. Waves of SARS-CoV-2 Infection and Blood Coagulation-A Link and Beyond. Thromb Haemost 2021; 121 (01) 4-6
    Article in Thieme ConnectPubMedGoogle Scholar
  • 4 Althaus K, Marini I, Zlamal J. et al. Antibody-induced procoagulant platelets in severe COVID-19 infection. Blood 2021; 137 (08) 1061-1071 DOI: 10.1182/blood.2020008762.
    CrossrefPubMedGoogle Scholar
  • 5 Nachtigall I, Lenga P, Jóźwiak K. et al. Clinical course and factors associated with outcomes among 1904 patients hospitalized with COVID-19 in Germany: an observational study. Clin Microbiol Infect 2020; 26 (12) 1663-1669 DOI: 10.1016/j.cmi.2020.08.011.
    CrossrefPubMedGoogle Scholar
  • 6 Greinacher A, Thiele T, Warkentin TE, Weisser K, Kyrle PA, Eichinger S. Thrombotic Thrombocytopenia after ChAdOx1 nCov-19 Vaccination. N Engl J Med 2021; 384 (22) 2092-2101 DOI: 10.1056/NEJMoa2104840.
    CrossrefPubMedGoogle Scholar
  • 7 Ferro JM, Canhão P, Stam J, Bousser MG, Barinagarrementeria F. ISCVT Investigators. Prognosis of cerebral vein and dural sinus thrombosis: results of the International Study on Cerebral Vein and Dural Sinus Thrombosis (ISCVT). Stroke 2004; 35 (03) 664-670
    CrossrefPubMedGoogle Scholar

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Zoom Image
Fig. 1 Proportion of patients with at least one thromboembolic event in Covid-19 inpatients by age and sex.