Keywords
coronavirus - COVID-19 - pregnancy loss - abortion - pregnancy
Introduction
COVID-19 infection is spread by respiratory droplets and is highly contagious.[1] It was first reported in Wuhan, China in December 2019 and the COVID-19 pandemic
was declared by the World Health Organization on March 11, 2020.[2] COVID-19 enters the body via the nasal passage and infects pulmonary cells via the
severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) receptor angiotensin-converting
enzyme 2 (ACE2) and uses transmembrane serine protease 2 (TMPRSS2) for S protein priming.[3] Infection with SARS-CoV-2 is followed by viral replication and release of the virus,
causing pyroptosis (inflammation-mediated programmed cell death occurring in response
to a pathological stimulus).[4] Coronavirus is enveloped, nonsegmented, positive-sense ribonucleic acid usually
causing respiratory distress in the infected patient.[5] However, evidence shows that coronavirus can cause harmful clinical effects on a
wide spectrum of bodily systems. Since pregnancy is an immunocompromised state, a
pregnant woman is at a higher risk of getting infected as compared with a healthy
individual.[1] The modulations of the maternal immune system in pregnancy may affect the response
to infections, and specifically to viruses.[6]
Mechanisms of damages of COVID-19 during pregnancy could be: a decrease in circulating
natural killer (NK) cells[7]; increased progesterone hormone as a steroid hormone that has immunomodulatory properties[8]; alterations in the innate immune system, including the pattern recognition receptors
Toll-like receptors (TLRs)[9]; a shift in CD4+ T cell population toward the Th2 phenotype over Th1[10]; also pregnancy is a hypercoagulable state with increased thrombin production and
an increase in intravascular inflammation[11]; and the current reports indicate clinical manifestations of both widespread microvascular
as well as large vessel thrombosis in patients infected with COVID-19.[12] But the fetal damages are explained by SARS-CoV-2 found on reverse transcription-polymerase
chain reaction of swabs and biopsies following a spontaneous fetal loss at 19-week
gestation[13] and in placental and umbilical cord biopsies.[14] Mechanisms of viral invasion of the placenta have yet to be established.
Outcomes in pregnant women with SARS-CoV-2 infection appear less severe compared with
SARS and Middle East respiratory syndrome.[15] American Centers for Disease Control states that although hospitalization in the
intensive care unit of COVID-19 affected pregnant patient is higher than nonpregnant,
the mortality rate is similar to other nonpregnant patients. Since there is evidence
that COVID-19 affects blood coagulation factors, it has the potential of adverse effect
on pregnancy, particularly with the inherent hypercoagulability of gestation.[2] There had been a systematic review of published reports on COVID-19 which reported
higher rates of preterm birth, preeclampsia, and perinatal death. The lack of data
on spontaneous abortion due to COVID-19 in the first trimester prevents the inference
of conclusive evidence for the effects of this infection during early pregnancy. But
due to the scarcity of reliable data and misreporting of the information by the media
has led pregnant women to take drastic choices such as voluntary abortion.[5] The wide range of COVID-19 symptoms, high rate of asymptomatic forms, and poor accuracy
of nasopharyngeal swab testing have been the main barriers for understanding the prevalence
of its infection and impact on a pregnant woman and the fetus.[5] Though we are aware that many viral infections are harmful to the fetus during the
first trimester of pregnancy, what is the impact of COVID-19 on the fetus of the first
trimester is still unknown.[5] There was a lack of study and reliable data to find the effect of COVID-19 on the
first trimester and second trimester; however, there were some case reports of newborns
with fetal distress requiring intensive care unit and stillbirth of COVID-19 affected
pregnant women in the third trimester suggesting the possibility of pathology related
to the placenta.[16] According to Yan et al, a retrospective study where 116 pregnant women were included
resulted that SARS-CoV-2 infections during pregnancy is not associated with an increased
risk of spontaneous abortion and spontaneous preterm birth. There is no evidence of
vertical transmission of SARS-CoV-2 infection when the infection manifests during
the third trimester of pregnancy.[17] The same conclusion was reported by the Cosma et al case–control study where 225
women were studied. COVID-19 did not seem to predispose to early pregnancy loss; its
cumulative incidence did not show a difference between women with spontaneous abortion
and women with ongoing pregnancy. COVID-19 appears to have a favorable maternal course
at the beginning of pregnancy, consistent with what has been observed during the second
and third trimesters.[5] In the Baud et al case report, the miscarriage during the first trimester due to
SARS-CoV-2 infection appears related to placental infection as no other cause of miscarriage
was identified. Limited data are available regarding the impact of COVD-19 on pregnancy;
however, the case of miscarriage due to placental infection caused by SARS-CoV-2 in
the second trimester has already been reported more than once.[16]
[18] An increasing number of miscarriage cases were reported during this pandemic. These
cases of missed miscarriages were diagnosed clinically, supported by ultrasonographic
evidence, before being diagnosed with COVID-19 infection. This could happen even in
those cases where the patients were relatively asymptomatic or manifested mild symptoms
of COVID-19 infection. However, the cause of the miscarriage was unknown, and SARS-CoV-2
infection as the causal factor could not be completely ruled out.[19] The position for pregnant women on this spectrum is unclear. The immune system adapts
during pregnancy to allow for the growth of a semiallogenic fetus.[20]
Since December 2019 (when the pandemic started), several case studies and cohort studies
have described the presentation and clinical course of COVID-19 in pregnancy. Therefore,
the main aim of this study is to understand the role of COVID-19 infection in causing
pregnancy complications specifically fatal outcomes.
Methods
This literature review is done for the period January 1, 2020 up to July 2021. We
searched for articles in PubMed, Science Direct, Cochrane, Scopus, and Embase. We
used the following search terms “Pregnancy complications and/or COVID-19” and/or Fetal
complications and/or SARS-CoV-2 and/or Pregnancy Complications and/or SARS-CoV-2.
The search terms were kept broad to encompass all possibilities for applicable studies.
Only articles published in the English language were included. Duplicates were removed
manually. After eliminating duplicates, three investigators (D.S., R.A., and O.A.)
independently reviewed all titles and abstracts. The full texts of articles regarded
as potentially eligible for consideration were extracted and screened for further
analysis. Thereafter, eligible articles were selected for final analysis according
to predefined inclusion and exclusion criteria. Disagreements between the authors
were resolved through consensus and active discussion. The exclusion criteria consisted
of review articles, animal studies, elective abortion, studies published in a language
other than English, and the absence or unclear reporting of pregnancy complication
status in COVID-19 pregnant patients.
Results
The literature search produced 90 relevant publications in the PubMed database, 5
on ScienceDirect, and 72 on Scopus, and no results of Embase or Cochrane. All Google
Scholar's results were repeated. After reviewing 167 articles manually by abstract
screening, 67 manuscripts were further excluded because they did not satisfy our inclusion
criteria. Out of the remaining 100 articles, 78 were excluded after full text screening.
Therefore, 22 articles were eligible for review in our study. Details of included
studies are listed in the table. The majority of papers arose from Asia. Of all of
the studies included, 4 were case series reports, 6 case reports, 7 cohort studies,
4 cross-sectional, and 1 case–control study. Please find the information on all fatal
outcome pregnancies reported in the literature that we included in our final quantitative
analysis in [Table 1].
Table 1
All eligible studies to be included in our review
|
Authors
|
Location
|
Number of patients
|
Age
|
Gestational age on admission
|
COVID-19 diagnosis
|
Number of cases
|
Time of presentation
|
Outcomes
|
|
Yan et al, 2020[17]
|
China
|
116
|
30.8 (IQR 24–41)
|
38 + 0
(IQR 36 + 0–39 + 1) weeks
|
65 cases of laboratory-confirmed (qRT-PCR) and 51 cases of clinically diagnosed COVID-19
pneumonia
|
1 missed spontaneous abortion
|
5 + 2 weeks at presentation with fever and fatigue
|
Survived 76 discharged
|
|
Wong et al, 2020[19]
|
Malaysia
|
2
|
34
|
10-week period of amenorrhea (COVID-19 diagnosis time)
|
NPS/OPS for SARS-CoV-2 RT-PCR was positive
|
2 missed miscarriages
|
7-week and 1-day period of amenorrhea
|
Passed out product of conception 27 days after onset of symptoms
|
|
38
|
12-week period of an amenorrhea
|
Antibody test for SARS-CoV-2 showed positive IgG and negative IgM NPS/OPS for SARS-CoV-2
RT-PCR which was positive
|
11-week period of an amenorrhea
|
Maternal survived
|
|
Buonsenso et al, 2020[21]
|
Italy
|
7
|
NA
|
6 patients < 37 weeks gestation
|
Positive (RT-PCR)
|
1 spontaneous abortion
|
8 weeks
|
Maternal survived
|
|
Chen et al, 2020[22]
|
Wuhan, China
|
118
|
31 years (IQR 28–34)
|
NA
|
84 (71%) had positive PCR testing for severe acute respiratory syndrome coronavirus
2 (SARS-CoV-2)
34 (29%) had suggestive findings on CT of the chest
|
9 (8%) abortion
Of them, 3 spontaneous abortions
|
75 (64%) had been infected with SARS-CoV-2 in the third trimester
|
109/116 (94%) had been discharged, including all women with severe or critical disease.
There were no deaths
|
|
Di Mascio et al, 2020[23]
|
73 centers from 22 countries
|
388
|
NA
|
30.6 ± 9.5 weeks
|
All pregnant women with laboratory-confirmed COVID-19
8% being diagnosed in the first, 22.2% in the second, and 69.8% in the third trimester
of pregnancy
|
6 (2.3%) spontaneous abortions
|
First trimester of pregnancy
|
11.1% were admitted to ICU, and 6.4% requiring intubation 3 cases of maternal deaths
|
|
Mattar et al, 2020[24]
|
Singapore
|
16
|
23–36
|
First trimester, n = 6; second trimester, n = 7; third trimester, n = 3
|
All pregnant women with COVID-19 diagnosed by (RT-PCR)
|
2 spontaneous miscarriages
|
11 and 23 weeks
|
No maternal mortalities
|
|
Hachem et al, 2020[25]
|
France
|
1
|
21 years
|
20 weeks
|
RT-PCR positive
|
1 spontaneous abortion
|
20 weeks
|
Maternal survived
|
|
Shmakov et al, 2020[26]
|
Russia
|
66
|
30.3 ± 6.25
|
31.3 ± 10.4 (5–38 weeks)
|
All with PCR - confirmed SARS-CoV-2
|
4 (6.1%) spontaneous abortions
|
Before 20 weeks of gestation (2 before 12 weeks, 1 at 18 weeks, 1 medical abortion
at 19th week for fetal abnormalities)
|
1 case of maternal death occurred on the 33rd day after the patient's admission to
the hospital
|
|
Mayeur et al, 2020[27]
|
France
|
104
|
33.6 ± 4.1
|
16.9 ± 4.6 weeks
|
10 (11.3%) had symptoms related to COVID-19.
2 were positive on PCR test
|
15 (14.4%) spontaneous miscarriage
|
2 late spontaneous miscarriages. Both have not been tested for COVID-19
|
The first one was caused by a large subchorionic hematoma with a miscarriage at 19
weeks of gestational age. The second one occurred at 18 weeks of gestational age in
a context of cervical insufficiency and chorioamnionitis
|
|
Sahin et al, 2021[28]
|
Turkey
|
533
|
28.04 ± 5.84 (17–47)
|
First trimester 130 (24.4) Second trimester 165 (30.9) Third trimester 238 (44.7)
|
All were laboratory-confirmed SARS-CoV-2 infection
|
12 (2.2%) miscarriages
|
NA
|
2 (0.4) maternal mortality
|
|
Michel et al, 2021[29]
|
France
|
1
|
40
|
16 weeks and 4 days
|
SARS-CoV-2 serology positive
|
1 spontaneous miscarriage
|
NA
|
Maternal survived
|
|
D'Antonio et al, 2021[30]
|
22 countries
|
887
|
208 (34.16 ± 6.8),679 (31.39 ± 5.5)
|
208 (30.26 ± 9.8),679 (29.65 ± 9.6)
|
All were laboratory-confirmed SARS-CoV-2 infection
|
11 spontaneous miscarriages
|
Before 22 weeks of gestation
|
3 cases of maternal deaths
|
|
Baud et al, 2020[16]
|
Switzerland
|
1
|
28
|
19 weeks' gestation
|
Nasopharyngeal swab was positive (RT-PCR)
|
1 miscarriage
|
2 days after admission
|
Maternal survived
|
|
Cosma et al, 2021[5]
|
Turin, Italy
|
225
|
125 (33.7 ± 4.7), 100 (35.5 ± 4.7)
|
12–13 weeks approximately
|
23 (10.2%) had a positive test result (anti-SARS-CoV-2 IgG and IgM antibodies)
|
100 spontaneous abortions (12 had COVID-19)
|
NA
|
No severe cases or hospital admission because of COVID-19-related symptoms were recorded,
both in women who had ongoing pregnancies and in those with early pregnancy loss
|
|
Sentilhes et al 2020[31]
|
France
|
54
|
30.6 ± 6.2
|
37.4 ± 4.7 weeks
|
54 symptomatic pregnant women with COVID-19 during the study period; 38 had positive
RT-PCR results for SARS-CoV-2
|
1 miscarriage
|
NA
|
5 were (9.3%) admitted to the ICU, all owing to COVID-19 respiratory symptoms
|
|
Rana et al, 2021[18]
|
Rawalpindi, Pakistan
|
1
|
30
|
10 weeks and 6 days of gestation
|
rRT-PCR positive
|
1 miscarriage
|
14 days later admission
|
Maternal survived
|
|
la Cour et al, 2021[32]
|
Denmark
|
1,356
|
1,019 (31.71, SD 4.52), 36 (32.96, SD 5.22)
|
11–14 weeks
|
18 had SARS-CoV-2 antibodies
|
3 missed abortions at the nuchal translucency scan
|
First trimester
|
Maternal survived
|
|
Ayed et al, 2020[33]
|
Kuwait
|
185
|
31 years (IQR: 27.5–34)
|
29 weeks (IQR: 18–34)
|
All were positive by RT-PCR assay of nasopharyngeal swab specimens
|
3 miscarriages
|
2 cases at 14 weeks and 1 case at 13 weeks
|
Maternal survived
|
|
Shende et al, 202q[34]
|
India
|
1
|
26-year- old
|
7.6 weeks
|
Nasopharyngeal swab by RT-PCR
|
1 fetal demise
|
8 weeks
|
Maternal survived. Presence of SARS-CoV-2 in the placenta from an asymptomatic mother
in the first trimester
|
|
de Vasconcelos Gaspar and Santos Silva, 2021[35]
|
Portugal
|
1,962
|
36 (SD 4.100)
|
40 weeks (IQR 3)
|
12 (0.61%) SARS-CoV-2 positive
|
1 stillbirth
|
20 weeks
|
None had severe or critical illness due to SARS-CoV-2
|
|
Martinez-Perez et al, 2021[36]
|
Spanish
|
1,009
|
32.6 (246 cases) and 32.5 (763 cases)
|
38 + 1 (246 cases) and 38 + 6 (763 cases)
|
246 positive cases, n = 218 were asymptomatic at delivery
|
3/246 stillbirth
|
NA
|
The infected group had 4.5% miscarriage risk
|
|
Pulinx et al, 2020[37]
|
Belgium
|
1 (gravida 2 para 1)
|
30-year-old
|
22 weeks
|
Positive for SARS-CoV-2 RT-PCR on a nasopharyngeal swab
|
1 fetal demise, fetus two showed fetal heart rate decelerations
|
24 weeks
|
Both placental tissue samples and amniotic fluid tested positive for SARS-CoV-2 RT-PCR
|
Abbreviations: CT, computed tomography; ICU, intensive care unit; IgG, immunoglobulin
G; IgM, immunoglobulin M; IQR, interquartile range; NPS/OPS, nasopharyngeal swabs
and oropharyngeal swabs; PCR, polymerase chain reaction; qRT-PCR, quantitative reverse
transcriptase-polymerase chain reaction; RT-PCR, reverse transcription-polymerase
chain reaction; SARS-CoV-2, severe acute respiratory syndrome coronavirus 2; SD, standard
deviation.
Overall, these 22 studies included a total of 7,034 participants: 2,689 (38.23%) SARS-CoV-2
positive pregnant women, of which 2,578 (95.87%) were laboratory confirmed and 111
(4.13%) were clinically diagnosed. The clinical symptoms among pregnant women with
laboratory-confirmed SARS-CoV-2 infection are presented in the table.
Symptoms
Symptoms most commonly reported were four: fever, cough, fatigue, and anosmia. Out
of 3,512 patients, 15.19% had fever.[5]
[16]
[17]
[18]
[22]
[23]
[24]
[26]
[27]
[28]
[30]
[31] Out of 2,155, 28.19% presented with a cough and 16.6% developed fatigue from 307
cases.[5]
[16]
[17]
[19]
[22]
[23]
[24]
[26]
[27]
[28]
[30]
[31] Also, from 2,360 cases, 4.32% reported anosmia.[5]
[16]
[18]
[24]
[26]
[27]
[30] Six studies reported asymptomatic patients with COVID-19, so 34.3% from 1,892 cases.[19]
[23]
[24]
[26]
[28] There were three studies in which 89.11% reported mild disease of COVID-19.[24]
[26]
[28]
Only one study compared clinical symptoms between COVID-19 positive early pregnancy
loss and pregnant group during the first trimester: fever, anosmia, ageusia, cough,
arthralgia, diarrhea, and no cases of pneumonia were reported. Also, was noted no
difference in the incidence of symptoms between the two groups.[5]
Vertical Transmission of SARS-COV-2 and Spontaneous Abortion
Martinez-Perez et al observed a significant increase in the stillbirth rate in the
univariate analysis. It is an important point to highlight that two case reports confirmed
positive SARS-CoV-2 in placental tissue samples and amniotic fluid.[34]
[37] Among the positive patients, there were 174 (6.47%) cases of abortion, of them 168
(96.55%) were spontaneous abortions and 6 (3.45%) were missed abortions. Comparing
to United States 2021 abortion rate, which is reported as 20.8%,[38] there were also four cases of induced abortion owing to patient's concerns about
COVID-19 and two cases of ectopic pregnancy. We have excluded these 6 cases from the
analysis. Otherwise, three studies reported the use of lopinavir-ritonavir as therapy,
so 6.23% of 593 cases.[21]
[28]
[31]
Assessment of Study Quality
For the quality assessment of included studies the Newcastle–Ottawa Scale was employed
to ascertain the quality of studies by two reviewers (D.S.) and (R.A.). They independently
assessed the methodologic quality of each study included: 7 cohort studies, 4 cross-sectional,
and 10 observational studies were evaluated for the following three domains: quality
of selection of cohorts (4 stars), comparability of cohorts (2 stars), and assessment
of outcome (3 stars). One case–control study was assessed for quality of selection
of cases and controls (4 stars), comparability of cases and controls (2 stars), and
ascertainment of exposure (3 stars). We considered a total of 7 out of 9 stars to
be a low risk of bias, 4 to 6 stars to be a moderate risk, and less than 4 stars to
be a high risk of bias. In case of a disagreement, reviewers reached consensus by
discussion with a third reviewer. The risk of bias assessment is shown in [Table 2].
Table 2
Risk of bias assessment for included studies
|
Newcastle–Ottawa Scale: cohort studies
|
|
|
Study ID
|
Selection
|
Comparability
|
Outcome
|
Total score
|
Judgment
|
Support of judgment
|
|
Di Mascio et al, 2020 [23]
|
****
|
*
|
**
|
******* (7)
|
Low risk
|
Quote: “multinational, cohort study on all consecutive pregnant women with laboratory-
confirmed COVID-19 from February 1, 2020 to April 30, 2020 from 73 centers from 22
different countries,” comment: this type of cohort study according to AHRQ standard
has good quality, and they had the maximum of selection criteria
|
|
Mattar et al, 2020 [24]
|
****
|
|
***
|
******* (7)
|
Low risk
|
Quote: “Prospective observational study of 16 pregnant patients admitted for COVID-19
to 4 tertiary hospitals in Singapore,” comment: this type of cohort study according
to AHRQ standard has good quality, and they had the maximum of selection criteria
|
|
Sahin et al, 2021 [28]
|
***
|
|
***
|
****** (6)
|
Low risk
|
Quote: “prospective cohort study was conducted on pregnant women,” comment: this type
of cohort study according to AHRQ standard has good quality, and they explained data
with statistical analysis
|
|
D'Antonio et al, 2021 [30]
|
****
|
*
|
***
|
******** (8)
|
Low risk
|
Quote: “multinational retrospective cohort study involving women with laboratory-confirmed
severe acute respiratory syndrome coronavirus 2 infection from 76 centers from 25
countries,” comment: this type of cohort study according to AHRQ standard has good
quality, and they had a sufficient follow-up
|
|
Sentilhes et al 2020 [31]
|
****
|
|
***
|
******* (7)
|
Low risk
|
Quote: “retrospective, single-center study includes all consecutive pregnant women,”
comment: this type of cohort study according to AHRQ standard has good quality, and
they had the maximum of selection criteria
|
|
la Cour et al, 2021[32]
|
****
|
*
|
***
|
******** (8)
|
Low risk
|
Quote: “Cohort study of 1,019 women with a double test,” comment: this type of cohort
study according to AHRQ standard has good quality, and they had the maximum of selection
criteria
|
|
Martinez-Perez et al, 2021 [36]
|
****
|
*
|
***
|
******** (8)
|
Low risk
|
Quote: “multicenter prospective study in pregnancy based on a universal antenatal
screening program for SARS-CoV-2 infection,” comment: this type of cohort study according
to AHRQ standard has good quality, and they had the maximum of selection criteria
|
|
Newcastle–Ottawa Scale: case–control study
|
|
|
Study ID
|
Selection
|
Comparability
|
Exposure
|
Total score
|
Quality
|
Support of judgment
|
|
Cosma et al, 2021 [5]
|
**
|
*
|
***
|
****** (6)
|
Low risk
|
Quote: “women with spontaneous abortion (case group, n = 100) and those with ongoing pregnancy (control group, n = 125),” comment: this type of case–control study according to AHRQ standard has
fair quality, but they had an acceptable response rate
|
|
Newcastle–Ottawa Scale: cross-sectional studies
|
|
|
Study ID
|
Selection
|
Comparability
|
Outcome
|
Total score
|
Quality
|
Support of judgment
|
|
Shmakov et al, 2020 [26]
|
**
|
*
|
***
|
****** (6)
|
Low risk
|
Quote: “66 women with polymerase chain reaction (PCR) - confirmed SARS-CoV-2 and their
42 neonates were included in the prospective observational study,” comment: this type
of cross- sectional study according to AHRQ standard has fair quality, but they mentioned
the sample size and percentage of respondents and explained data with statistical
analysis
|
|
Mayeur et al, 2020 [27]
|
*****
|
|
*
|
****** (6)
|
Low risk
|
Quote: “single center, retrospective study from December 2019 to March 2020 based
on a phone call interview using a specific questionnaire sheet,” comment: this type
of cross-sectional study according to AHRQ standard has fair quality, but they mentioned
the sample size and percentage of respondents and explained data with statistical
analysis
|
|
Ayed et al, 2020 [33]
|
**
|
|
***
|
***** (5)
|
High risk
|
Quote: “retrospective national-based study, we analyzed the medical records of all
pregnant women infected with SARS-CoV-2 and their neonates,” comment: this type of
study is only descriptive and not have comparable group
|
|
de Vasconcelos Gaspar and Santos Silva, 2021 [35]
|
|
|
***
|
*** (3)
|
High risk
|
Quote: “retrospective descriptive study, in order to evaluate the obstetric results
on pregnant women,” comment: this type of cross-sectional study does not justify the
sample size and only descriptive
|
|
Newcastle–Ottawa Scale: other observational studies
|
|
|
Study ID
|
Selection
|
Comparability
|
Exposure
|
Total score
|
Quality
|
Support of judgment
|
|
Yan et al, 2020[17]
|
**
|
|
***
|
***** (5)
|
High risk
|
Quote: “Clinical records were retrospectively reviewed for 116 pregnant women,” comment:
this type is a case series study, and it is only a group selected of patients and
only descriptive
|
|
Wong et al, 2020[19]
|
*
|
|
*
|
** (2)
|
High risk
|
Quote: “We would like to highlight 2 cases of first trimester miscarriage in COVID-19
infected pregnant mothers,” comment: this type of two patients in a case series does
not have sufficient data about selection and no applied to comparability
|
|
Buonsenso et al, 2020[21]
|
|
|
*
|
* (1)
|
High risk
|
Quote: “observational study of neonates born to mothers,” comment: this type of study
does not have sufficient data
|
|
Chen et al, 2020[22]
|
*
|
|
*
|
* (2)
|
High risk
|
Quote: “pregnant patients represented 0.24% of all reported patients with COVID-19,”
comment: this type is a case series study with 118 patients, but is only a group selected
of patients and only descriptive
|
|
Hachem et al, 2020[25]
|
|
|
|
0
|
High risk
|
Quote: “We report an unusual case of a second-trimester miscarriage,” comment: this
type of one case report in the report study does not have sufficient statistical data
|
|
Michel et al, 2021[29]
|
|
|
|
0
|
High risk
|
Quote: “Data about obstetric complications of maternal infection by SARS-CoV-2 remain
sparse,” comment: this type of one case report in the report study does not have sufficient
data
|
|
Baud et al, 2020[16]
|
|
|
|
0
|
High risk
|
Quote: “We present a case of miscarriage,” comment: this type of one case report in
the report study does not have sufficient data
|
|
Rana et al, 2021[18]
|
|
|
|
0
|
High risk
|
Quote: “report a case of miscarriage during the first trimester due to SARS-CoV-2
infection,” comment: this type of one case report in the report study does not have
sufficient data
|
|
Shende et al, 2021[34]
|
|
|
|
0
|
High risk
|
Quote: “report a case of a pregnant woman in the first trimester who tested positive
for SARS-CoV-2 at 8 weeks of gestation,” comment: this type of one case report in
the report study does not have sufficient data
|
|
Pulinx et al, 2020[37]
|
|
|
|
0
|
High risk
|
Quote: “we describe a case of a known SARS-CoV-2-positive woman giving preterm birth
to two fetuses with SARS-CoV-2 positive testing in placental tissue and amniotic fluid,”
comment: this type of one case report in the report study does not have sufficient
data
|
Abbreviations: AHRQ, Agency for Healthcare Research and Quality; SARS-CoV-2, severe
acute respiratory syndrome coronavirus 2.
Discussion
SARS-CoV-2 Complicates the Pregnancy Utilizing ACE2 Receptor and Consequent Activation
of the TMPRSS2 Enzyme
Coronavirus disease's clinical spectrum can range from asymptomatic presentation to
pneumonia, heart failure, kidney injury, and eventually death. The SARS-CoV-2 utilizes
the ACE2 receptor and consequent activation of the TMPRSS2 enzyme to gain entry into
host cells and trigger an exaggerated inflammatory response via the release of cytokines
(“cytokine storm”). These results in a severe form of COVID-19 infection which is
associated with increased mortality and morbidity. An intact immune system is responsible
for clearing infected cells and preventing further replication of the virus. A weakened
immune system in pregnancy impacts viral clearance and therefore increases the susceptibility
to develop an infection with SARS-CoV-2. Factors such as a preference of the humoral
response over the cell-mediated response, a decrease in circulating NK cells, and
alterations in the immune system and pattern recognition receptors such as the TLRs
result in a decreased response to coronavirus disease.[7]
[8]
[9]
[10]
[39] During pregnancy, the presence of a fetus alters respiratory function as there is
an increase in tidal volume, decreased functional residual capacity due to a reduction
in chest volume, and a reduction in the total lung capacity. A reduced total lung
capacity impairs the lung's ability to clear infections, therefore increasing the
susceptibility to develop severe respiratory secretions.[39]
Miscarriage Likely Occurred due to Placental Abruption and Maternal Preeclampsia with
Thrombocytopenia and Coagulopathy
Pregnant women demonstrated enhanced levels of the ACE 2 receptors on organs, such
as the placenta, uterus, and kidneys, to allow for proper fetal growth and regulation
of angiotensin-II levels. This high expression of ACE2 reveals that the SARS-CoV-2
virus can potentially infect the placenta and result in placental dysfunction and
severe pregnancy complications.[40] Wong et al discuss two cases of first trimester miscarriages in pregnant mothers
infected with COVID-19. Although SARS-CoV-2 follows vertical transmission and interacts
with fetal ACE2 receptors resulting in fetal death and abortion, the two patients
in the study by Wong et al reported no signs of vertical transmission. Reports indicate
that the spontaneous miscarriage in both these patients resulted from SARS-related
hypoxic respiratory illness.[19] In addition, Wastnedge et al discuss a series of case reports studying the placentas
of pregnant women infected with COVID-19 sustaining miscarriage in the second trimester.
A high number of SARS-CoV-2 receptors were expressed in the placental and umbilical
cord biopsies in these patients. Reports indicate that the miscarriage likely occurred
due to placental abruption and maternal preeclampsia with thrombocytopenia and coagulopathy.
Also, electron microscopy in these patients revealed particles of the virus in the
cytosol of placental cells.[39] In addition, Poisson and Pierone's case report indicates extensive fetal vascular
malperfusion and parenchymal infarcts resulting in a severe loss of a significant
percentage of chorionic villi in the placental examination.[41]
Chowdhury et al's study evaluate 12 cases of miscarriage, diagnosed by an ultrasound
scan, at 11 weeks or more due to COVID-19 from March 2020 to July 2020 in a single
hospital in Dhaka, Bangladesh. The miscarriage was supposed to be due to SARS-CoV-2
virus-induced damage of the placental barrier via hypoxemia. The miscarriage resulted
from viral damage and the consequent induction of a placental inflammatory reaction,
acute chorioamnionitis, and intervillous.[1] Yet, the effect sizes of all of these studies are too small to statistically conclude
that the SARS-CoV-2 virus is the main culprit in causing miscarriages in pregnant
women.
As discussed earlier, SARS-CoV-2 utilizes the ACE2 and the resultant activation of
the TMPRSS2 enzyme to gain entry into host cells leading to the coronavirus disease.
COVID-19 Infection in Pregnant Women May More Likely Cause Late Pregnancy Complications
and Vertical Transmission
However, overall, evidence reported so far regarding COVID-19 infection and pregnancy
demonstrates that the TMPRSS2 enzyme may only be expressed after 24 weeks of pregnancy
and only in the extravillous trophoblast. As a result, COVID-19 infections in pregnant
women may more likely cause late pregnancy complications and vertical transmission
as opposed to problems in the first trimester, such as spontaneous or missed abortions.
Furthermore, the mild increase in the spontaneous or missed abortions rate may not
be because of the SARS-CoV-2 virus itself but due to individual's intense physical
and mental stresses from the pandemic. These stressors then cause a release of large
amounts of cortisol, which could potentially affect the pregnancy, especially in the
early trimester. Yet, at this time, there is limited data available regarding the
vertical transmission of SARS-CoV-2 infection. Although recent studies have reported
cases of anti-SARS-CoV-19 immunoglobulins in newborns, there are limitations, such
as the lack of placental and amniotic fluid examination.[42]
Pregnancy is a vulnerable period, particularly the early period; therefore, it is
essential to be vigilant and provide the best maternal care to ensure successful maternal
and fetal outcomes. However, as the COVID-19 pandemic is still in progress worldwide,
it is vital to assess more extensive studies from a wide range of patient populations
and health care settings.
Lessons Learned
One of the main crucial lessons learned from conducting this comprehensive literature
review is that the early pregnancy complications, such as spontaneous or missed abortions,
may not have been increased by the COVID-19 infection. As demonstrated by a few studies,
the main reason for an increased rate of spontaneous or missed abortions, if any,
is due to the environment of the pandemic itself, affecting health care quality and
access.[43] As a result, this increased rate was mainly observed in minority populations, such
as African American populations, where there already exists a severe health care disparity.[43] Thus, to effectively lower the rate of fatal fetal complications in COVID-19-infected
pregnant women and maternal mortality, it is best to address the public health aspect
of the COVID-19 pandemic instead of clinical management of COVID-19 itself.
Strengths
We conducted a sensitive and comprehensive search strategy to reduce the risk of missing
relevant studies. We adhered to rigorous quality appraisal, which was independently
assessed by pairs of reviewers and discrepancies solved by consensus.
Limitations
Our literature search was restricted to publications in English. Although we included
a comprehensive number of outcomes, we cannot rule out the possibility that some associations
were spurious.
Conclusion
In conclusion, many current studies included in our comprehensive literature review
have shown that there is no increased risk of fetal fatal outcomes in pregnant women
infected with COVID-19 infection. Pregnant patients can present with mild disease
symptoms such as fever, cough, fatigue, and anosmia. However, almost half of the infected
pregnant women were asymptomatic. The expressions of the TMPRSS2 enzyme are higher
during the third trimester. There is a theoretical possibility of an increased risk
of late pregnancy complications and vertical transmission due to the COVID-19 infection.
Recent case reports indicate extensive fetal vascular malperfusion and parenchymal
infarction resulting in a severe loss of a significant percentage of chorionic villi
in the placental examination. However, additional investigation and rigorous research
are warranted to confirm placental pathology mechanisms concerning COVID-19 to protect
maternal and fetal health.
