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Globalization and Health
Erschienen in: Globalization and Health 1/2021

Open Access 01.12.2021 | COVID-19 | Review

Mental burden and its risk and protective factors during the early phase of the SARS-CoV-2 pandemic: systematic review and meta-analyses

verfasst von: Angela M. Kunzler, Nikolaus Röthke, Lukas Günthner, Jutta Stoffers-Winterling, Oliver Tüscher, Michaela Coenen, Eva Rehfuess, Guido Schwarzer, Harald Binder, Christine Schmucker, Joerg J. Meerpohl, Klaus Lieb

Erschienen in: Globalization and Health | Ausgabe 1/2021

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Abstract

Background

Mental burden due to the SARS-CoV-2 pandemic has been widely reported for the general public and specific risk groups like healthcare workers and different patient populations. We aimed to assess its impact on mental health during the early phase by comparing pandemic with prepandemic data and to identify potential risk and protective factors.

Methods

For this systematic review and meta-analyses, we systematically searched PubMed, PsycINFO, and Web of Science from January 1, 2019 to May 29, 2020, and screened reference lists of included studies. In addition, we searched PubMed and PsycINFO for prepandemic comparative data. Survey studies assessing mental burden by the SARS-CoV-2 pandemic in the general population, healthcare workers, or any patients (eg, COVID-19 patients), with a broad range of eligible mental health outcomes, and matching studies evaluating prepandemic comparative data in the same population (if available) were included. We used multilevel meta-analyses for main, subgroup, and sensitivity analyses, focusing on (perceived) stress, symptoms of anxiety and depression, and sleep-related symptoms as primary outcomes.

Results

Of 2429 records retrieved, 104 were included in the review (n = 208,261 participants), 43 in the meta-analysis (n = 71,613 participants). While symptoms of anxiety (standardized mean difference [SMD] 0.40; 95% CI 0.15–0.65) and depression (SMD 0.67; 95% CI 0.07–1.27) were increased in the general population during the early phase of the pandemic compared with prepandemic conditions, mental burden was not increased in patients as well as healthcare workers, irrespective of COVID-19 patient contact. Specific outcome measures (eg, Patient Health Questionnaire) and older comparative data (published ≥5 years ago) were associated with increased mental burden. Across the three population groups, existing mental disorders, female sex, and concerns about getting infected were repeatedly reported as risk factors, while older age, a good economic situation, and education were protective.

Conclusions

This meta-analysis paints a more differentiated picture of the mental health consequences in pandemic situations than previous reviews. High-quality, representative surveys, high granular longitudinal studies, and more research on protective factors are required to better understand the psychological impacts of the SARS-CoV-2 pandemic and to help design effective preventive measures and interventions that are tailored to the needs of specific population groups.
Begleitmaterial
Hinweise

Supplementary Information

The online version contains supplementary material available at https://​doi.​org/​10.​1186/​s12992-021-00670-y.
Angela M. Kunzler and Nikolaus Röthke shared first authorship.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abkürzungen
COVID-19
Coronavirus disease 2019
LORA
Longitudinal Resilience Assessment
MOOSE
Meta-analyses Of Observational Studies in Epidemiology
NIH
National Institutes of Health
PHQ
Patient Health Questionnaire
PRISMA
Preferred Reporting Items for Systematic Reviews and Meta-Analysis
PROSPERO
International Prospective Register of Systematic Reviews
SARS-CoV(− 2)
Severe Acute Respiratory Syndrome Coronavirus (− 2)
SD
Standard deviation
SDS
Zung Self-Rating Depression Scale
SMD
Standardized mean difference

Introduction

The emergence of novel severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) was described for the first time in Wuhan, China [1, 2] and declared a public health emergency of international concern on 30 January 2020 [3]. The virus spread rapidly and, as of January 14, 2021, led to 90,759,370 confirmed infections and 1,963,169 deaths worldwide [4].
During the early phase of the pandemic, many countries adopted drastic measures, including testing, tracing, self-isolation, and quarantine measures as well as broader population measures ranging from travel bans, school closures, assembly restrictions, curfews, to full lockdowns [57]. Besides substantial stressors for individuals and the general public (eg, social isolation, reduced income, restructuring of school, university, and work life) and healthcare systems (eg, disruption of essential health services) [8, 9], the SARS-CoV-2 pandemic has had major socio-economic consequences for the affected countries (eg, global supply chain disruptions) [10, 11]. By drastically changing our way of social interaction (eg, social distancing), it continues to affect many areas of daily life and in line with this social life and participation.
The disease-related threats, containment measures, and associated stressors may have a negative psychological impact on the community at large and potentially even more so on specific risk groups [1217]. Given the work-related stressors in the context of disease outbreaks (eg, high workload, risk of infection, triage decisions), healthcare workers may suffer from a particularly high burden [18]1,2 [2022]. Patients with pre-existing physical or mental conditions (eg, chronically ill individuals, psychiatric patients, geriatric patients), people with confirmed COVID-19 diagnosis, those recovering from the infection, or suffering from long COVID-19, and subgroups with special risk exposure (eg, caregivers) may also be at risk of developing stress-related mental symptoms [15, 2228].
Various systematic reviews have synthesized the evidence on psychiatric symptoms associated with previous highly contagious infectious disease outbreaks (eg, Ebola, SARS-CoV) and the SARS-CoV-2 pandemic [20, 24, 2935], some of them also narratively summarizing risk and protective factors for mental health [20, 30, 31, 33, 34]. Several meta-analyses have been conducted, either calculating the pooled prevalence of mental symptoms or odds ratios for the risk of mental burden attributable to the SARS-CoV-2 pandemic [20, 24, 29, 32, 33, 36]. Potential moderators of the negative mental health impact were also partly investigated [32]. International evidence indicates an elevated level of mental symptoms in the general public, including symptoms of anxiety, depression, and stress [3033, 36]. Confirming the risk status of healthcare workers, several reviews also found an increased prevalence of mental symptoms in this group [18]1,2 [20, 29, 31, 32]. Finally, a few studies in patient populations (eg, COVID-19 patients, patients with pre-existing mental or physical conditions) show increased mental burden [24, 3133].
There are several shortcomings of reviews published to date. Most either focus on the general population, healthcare workers, or patients, with only few publications examining the level of mental burden across all three specified, most relevant population groups [3133]. Further limitations included a limited search strategy [31], language restrictions [24, 30, 31, 33], or a missing preregistration [20, 24, 2931, 33, 36]. Most importantly, all but one systematic review failed to compare the mental burden during an ongoing pandemic with the burden before the pandemic [31]. Such comparisons, however, are necessary to quantify the mental burden specifically attributable to the current pandemic. We therefore aimed to assess the mental health impact of the SARS-CoV-2 pandemic by comparing data from the early phase of the current pandemic with prepandemic data in the general population, healthcare workers, and patients. We aimed to identify population-specific risk and protective factors for mental health.

Methods

Review registration

This systematic review [37] was preregistered with PROSPERO (registration no. CRD42020193249) with the title ‘Psychological distress, protective factors and resilience during the SARS-CoV-2 pandemic: a systematic review and meta-analysis with comparison to standard data’. Details of the methods are presented in the Additional file 1. The MOOSE Checklist for Meta-analyses of Observational Studies and differences between the protocol and the final review are presented in eTables 1 and 2.

Search strategy and selection criteria

We searched three bibliographic databases from January 1, 2019 to May 29, 2020 (PubMed, PsycINFO, and Web of Science) and inspected the reference lists of included studies. The search strategy comprised terms associated with mental health, pandemics, and the populations of interest (see eMethods 1 in Additional file 1). There were no restrictions concerning language, publication date, or publication format. We did not consider preprint articles. If not reported within a study, we systematically searched for prepandemic comparative data in the same or a similar population (PubMed, PsycINFO; see eMethods 2).
The populations of interest comprised the general population, healthcare workers, and any patients (eg, COVID-19 patients, those with pre-existing physical or mental conditions; eTable 3). Participants were included irrespective of age, health, or employment status. We did not consider infectious disease outbreaks other than due to SARS-CoV-2. To be eligible for the review, studies had to assess at least one mental health outcome, with a broad range of eligible outcomes (ie, anxiety and worrying, depression, posttraumatic stress, sleep, stress, general psychological distress). These outcomes were also considered for a descriptive synthesis of the prevalence (see data analysis). We included original research articles reporting on cross-sectional and longitudinal surveys.
All pandemic studies meeting these criteria were included but were only taken forward to pairwise meta-analyses if using a validated outcome measure and if prepandemic comparative data were available (eTables 4, 5). These were defined as data collected before the exposure to the current pandemic, and in the absence of other disease outbreaks or macro-stressors (eg, disasters), in the same country and population group (if available) and using the same outcome measure. In contrast to the review, we only focused on the four most frequently reported mental health outcomes (primary outcomes), including symptoms related to stress, anxiety, depression, or sleep. Posttraumatic stress, although reported more often than sleep, was not considered for pairwise meta-analyses. As this outcome is usually measured in the aftermath of macro-stressors, we were not able to identify adequate comparative data as mentioned above. Comparative data were selected stepwise using four levels to ensure best available comparability between SARS-CoV-2 exposure (‘pandemic’) studies and prepandemic (‘comparative’) studies. If representative studies in the same country and population (level 1) were not available, we used prepandemic studies in the same (level 2) or an alternative population (level 3; eg, healthcare workers compared with the general population), before resorting to the best available data in a similar country (level 4).

Study selection, data extraction, and quality assessment

The study selection process for the pandemic studies at the level of titles/abstracts and full-texts was performed in duplicate by two reviewers independently (NR, LG). Any disagreements were resolved by discussion or by consulting a third reviewer (KL). At both title/abstract (κ = 0.90) and full-text level (κ = 0.97), excellent inter-rater reliability was achieved.
Relevant information for each included study was extracted in duplicate by two reviewers (NR, LG), working independently, using a customized spreadsheet (eTable 6), which was shortened for the extraction of comparative data. Discrepancies were resolved through discussion or by a third reviewer (KL).
Three independent reviewers (NR, JSW, LG) assessed the quality of included studies using the modified National Institutes of Health (NIH) Quality Assessment Tool for Observational Cohort and Cross-Sectional Studies [38] (eTable 7), with disagreements being resolved by discussion or a third reviewer (KL). The level of comparability between pandemic and comparative data was assessed using a self-developed tool with four levels based on the previously mentioned levels for the stepwise selection of comparative data (eTable 8).

Data analysis

The included studies were synthesized in narrative and tabular form, with a descriptive analysis of prevalence rates for mental health symptoms (ie, proportion of participants beyond a cut-off score reported in the included study) and of risk and protective factors. If adequate comparative data for any of the primary outcomes were available, pairwise meta-analyses were performed for the general population, healthcare workers, and patients, respectively (eMethods 3). Given the multiple uses of comparative studies, we used multilevel meta-analyses [39] for the general population and healthcare workers, with pandemic studies being clustered according to prepandemic comparators. For patients, the multilevel model reduces to the classic random-effects model as different comparative studies were available. Prediction intervals were calculated in meta-analyses with at least four studies to take the large between-study heterogeneity into account [40].
Two sensitivity analyses referred to the quality of pandemic studies and the level of comparability (see Search strategy and selection criteria), by limiting the analyses to very comparable pandemic and prepandemic studies (ie, level 1 and 2 mentioned above).
Subgroup analyses for each of the three groups were performed for the surveyed populations (eg, age), characteristics of the pandemic studies (eg, survey start) and of comparative data (eg, publication year), and the relationship of sample sizes in pandemic versus comparative studies, in order to identify potential sources of heterogeneity of the psychological impact of the SARS-CoV-2 pandemic.

Results

Details of the results are presented in the Additional file 2. The systematic search for studies performed during the SARS-CoV-2 pandemic identified 2429 records from database searches and 17 additional records from reference lists, of which 104 studies were included in the review and 43 studies in the meta-analyses (Fig. 1). Of the 104 eligible studies, most studies were performed in the general population (50 studies), followed by 30 studies in healthcare workers, and seven studies in various patient populations. Seventeen studies included mixed samples. Across the three population groups, a total of 208,261 participants ranging from 51 to 52,730 participants [41, 42]1 from the pandemic studies were included in the review, the number of participants considered in the meta-analyses, in total 71,613, ranged from 127 to 60,213 participants (eTable 9).
The study characteristics of the 104 included pandemic studies (early phase) are presented in Table 1.
Table 1
Study characteristics of included main studies
Study
Study design
Country
Sample size; female: No. (%); age: mean (SD) or alternative information on age (eg, mode)
Subgroups
Survey period
Assessed Outcomes
Instruments or scales
General Population
 Ahmad et al. (2020) [43]1
CS, OBS
Iraq (Kurdistan)
516; 222 (43%); NA (mode: 18–35 years [65.1%])
NA
NA
Anxiety and fear
Binary single itema
 Bacon et al. (2020) [44]1
CS, OBS
United Kingdom
202; 127 (62.9%), 1 diverse; 33.79 (12.48)
NA
March 18–19, 2020
Anxiety and fear
GAD-7
Depressive symptoms
BDI-II
 Bäuerle et al. (2020) [45]1, Teufel et al. (2020) [46]1
CS, OBS
Germany
15,037; 10,633 (70.7%), NA (mode: 25–34 years [24.8%])
NA
March 10–May 5, 2020
Anxiety and fear
GAD-7, single item 7-P LSa
Depressive symptoms
PHQ-2
Psychological Distress
DT
 Buzzi et al. (2020) [47]1
CS, OBS
Italy
2064; NA; NA
100% adolescents
March 2020
Anxiety and fear
4-P LSa
 Cao et al. (2020) [48]1
CS, OBS
China
7143; 4975 (69.7%); NA
NA
NA
Anxiety and fear
GAD-7
 Chang et al. (2020) [49]1
CS, OBS
China
3881; 2447 (63.1%); 20.00 (NA); P25=19.00, P75=22.00]
100% studentsb; medical students (n = 3359)
January 31, 2019–February 3, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
 Gao J et al. (2020) [50]1
CS, OBS
China
4872; 3267 (67.7%); 32.3 (10.0)
NA
January 31–February 02, 2020
Anxiety and fear
GAD-7
Depressive symptoms
WHO-5c
 Germani et al. (2020) [51]1
CS, OBS
Italy
1011; 720 (71.2%); 24.2 (3.6)
100% age between 18 and 29 years
March 17–24, 2020
Anxiety and fear
STAI-Y
Stress
PSS
Other Outcomes
SDQ
 González–Sanguino et al. (2020) [52]1
CS, OBS
Spain
3480; 2610 (75%); 37–92 (NA)
NA
March 21–28, 2020
Anxiety and fear
GAD-2
Depressive symptoms
PHQ-2
PTSS
PCL-C-2
Other outcomes
FACIT-Sp12, MSPSS, SCS
 Harper et al. (2020) [53]1
CS, OBS
UK
324; 162 (50%); 34–32 (11.71)
NA
March 27–28, 2020
Anxiety and fear
FCV-19S, PROMIS-SF Anxiety
Depressive symptoms
PROMIS-SF Depression
Other outcomes
WHOQOL-BREF
 Jahanshahi et al. (2020) [54]1
CS, OBS
Iran
1058; 569 (53–8%); NA (mode: 26–35 years)
NA
March 25–28, 2020
Psychological distress
CPDI
 Lauri Korajlija et al. (2020) [55]1
CS (repeated), OBS
Croatia
sample 1: 888; 738d (83–1%); 31.3 (10.45)
sample 2: 966; 732d (75.8%); 40 (11.94)
NA
1st period: February 24–NA
2nd period: March 19–NA
Anxiety and fear
11-items 5-P LS (based on Swine Flu Anxiety Items, Wheaton et al. 2012)a
 Lee SA et al. (2020) [56]1
CS, OBS
USA
398; 191 (49%); 35.91 (11.73)
NA
March 23–24, 2020
Anxiety and fear
2 single items 5-P LSa
Other outcomes
Passive suicidal ideation (single item 5-P LS)a
 Lei et al. (2020) [57]1
CS, OBS
China
1593; 976 (61.3%); 32.3 (9.8)
‘affected group’: quarantined / relatives quarantined (n = 420)b
February 04–10, 2020
Anxiety and fear
SAS
Depressive symptoms
SDS
 Li Y et al. (2020) [58]1
CS (part of longitudinal cohort study), OBS
China
1442; 891d (61.8%); NA (K-6 < 5: 20.0 [1.5]; K-6 ≥ 5: 20.0 [1.6])
medical students (n = 764), nursing students (n = 211), medical technology students (n = 467)
February 7–13, 2020
PTSS
IES-R
Psychological distress
K-6
 Liu N et al. (2020) [59]1,2
CS, OBS
China
285; 155 (54.4%); NA (47.7% < 35)
NA
January 30– February 08, 2020
PTSS
PCL-5
 Liu S et al. (2020) [60]1
CS, OBS
China
primary school: 209; 116 (56%d); NA
college: 198; 130 (62%); NA
primary school students, college students
February–March, 2020
Anxiety and fear
3 items, 4-P LSa
Other outcomes
SSS
 Lopez et al. (2020) [61]1
CS, OBS
Spain
878; 544d (62%) or 636 (72%d), data in text and Table 1 inconsistent; NA (mode: 60–70 years [71%d])
100% community-dwelling older adults;
age 60–70 (n = 626); age 71–80 (n = 252)
NA
Anxiety and fear
a
Other outcomes
BRCS, Ryff’s PWB (subscales for personal growth and purpose in life)
 Ma et al. (2020) [62]1
CS, OBS
China
123; 71d (57.7%d); 37.4 (10.6)
100% isolated peopleb
January 2020
Anxiety and fear
DASS-21 Anxiety
Depressive symptoms
DASS-21 Depression
Stress
DASS-21 Stress
Sleep-related symptoms
PSQI
Other outcomes
SF-36
 Mazza et al. (2020) [63]1
CS, OBS
Italy
2766; 1982 (71.7%); 32.94 (13.2)
NA
March 18–22, 2020
Anxiety and fear
DASS-21 Anxiety
Depressive symptoms
DASS-21 Depression
Stress
DASS-21 Stress
 McKay et al. (2020) [64]1
CS, OBS
China
908; 752 (82.8%); 40.37 (9.27)
NA
February 24–March 15, 2020
Anxiety and fear
CoVGAD-7, DASS-21 Anxiety
Depressive symptoms
DASS-21 Depression
 Moccia et al. (2020) [65]1
CS, OBS
Italy
500; 298 (59.6); NA (mode: 28–37 years, n = 129)
NA
April 10–13, 2020
Psychological distress
K-10
Other outcomes
TEMPS-A
 Odriozola-González et al. (2020) [66]1
CS, OBS
Spain
2530; 1672 (66.1%); 27.9 (12.4)
students (n = 1944); administrative staff (n = 247); faculty members and academic staff (n = 339)b
March 28–April 3, 2020
Anxiety and fear
DASS-21 Anxiety
Depressive symptoms
DASS-21 Depression
Stress
DASS-21 Stress
PTSS
IES
 Olagoke et al. (2020) [146]1
CS, OBS
USA
501; 277 (55.29%); 32.44 (11.94)
NA
March 25, 2020–NA
Depressive symptoms
PHQ-2
Other outcomes
Perceived self-efficacy (Ajzen 2002)
 Ozamiz-Etxebarria et al. (2020) [68]1
CS, OBS
Spain
976; 792 (81.1%); NA (mode: 18–25 years [56.5%])
NA
March 11–15, 2020
Anxiety and fear
DASS-21 Anxiety
Depressive symptoms
DASS-21 Depression
Stress
DASS-21 Stress
 Özdin et al. (2020) [69]1
CS, OBS
Turkey
343; 169 (49.2%); 37.2 (10.3)
NA
April 14–16, 2020
Anxiety and fear
HAI
Depressive symptoms
HADS
 Perez–Fuentes et al. (2020) [70]1
CS, OBS
Spain
1014; 681 (67.2%); 40.87 (12.42)
NA
March 18–23, 2020
Depressive symptoms
BIP-Q5
 Qiu et al. (2020) [41]1
CS, OBS
China, Hong Kong, Macao, Taiwan
52,730; 34,131 (64.7%)
NA
January 31–February 2, 2020
Psychological distress
CPDI
 Ren et al. (2020) [71]1
CS, OBS
China
1172; NA; NA
NA
February 14–March 29, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
Stress
PSS-10
Sleep-related symptoms
ISI
PTSS
PCL-5
Other outcomes
MINI suicidality module
 Reznik et al. (2020) [72]1
CS, OBS
Russia & Belarus
850; 622 (73.2%); 34.8 (13.0)
NA
after March 27, 2020
Anxiety and fear
FCV-19S
 Roy et al. (2020) [73]1,2
CS, OBS
India
662; 339 (51.2%); 29.09 (8.83)
NA
March 22–24, 2020
Anxiety and fear
18 items 5-P LSa
 Sakib et al. (2020) [74]1
CS, OBS
Bangladesh
8550; 3760 (44%); 26.5 (9.1)
NA
April 1–10, 2020
Anxiety and fear
FCV-19S
Depressive symptoms
PHQ-9
 Satici et al. (2020) [75]1
CS, OBS
Turkey
1304; 917 (70.3%); 29.5 (10.5)
NA
NA
Anxiety and fear
DASS-21 Anxiety, FCV-19S
Depressive symptoms
DASS-21 Depression
Stress
DASS-21 Stress
 Shammi et al. (2020) [76]1
CS, OBS
Bangladesh
1066; 405 (38.5%); 27.80 (10.05)
NA
March 28–30, 2020
Psychological distress
COVID-19 related mental distress (5 items 5-P LS)a
 Shevlin et al. (2020) [77]1
CS, OBS
UK
2025; 1047 (51.9%); 45.4 (15.9)
NA
March 23–28, 2020
Anxiety and fear
GAD-7, VAS on COVID-19 anxiety
Other outcomes
PHQ-15
 Soraci et al. (2020) [78]1
CS, OBS
Italy
249; 229 (92%); 34.50 (12.21)
NA
March 18–21, 2020
Anxiety and fear
FCV-19S, HADS
 Sutin et al. (2020) [147]1
CS, OBS
USA
2094; 1024 (48.9%)d; 51.03 (16.58)
overweight (n = 706); obesity (n = 587)
mid–March, 2020
Anxiety and fear
13 items 5-P LSa
 Tan W et al. (2020) [80]1
CS, OBS
China
673; 172d (25.6%d); 30.8 (7.4)
NA
February 24–252,020
Anxiety and fear
DASS-21 Anxiety
Depressive symptoms
DASS-21 Depression
Stress
DASS-21 Stress
Sleep-related symptoms
ISI
PTSS
IES-R
 Tian et al. (2020) [81]1
CS, OBS
China
1060; 511 (48.2%); 35.01 (12.8)
HCW (n = 42), students (n = 330)
January 31–February 02, 2020
Anxiety and fear
SCL-90 Anxiety
Depressive symptoms
SCL-90 Depression
Psychological distress
SCL-90 GSI
Other outcomes
SCL-90 subscales
 Tsipropoulou et al. (2020) [82]1
CS, OBS
Greece
2970; 2153 (72.5%); NA (mode: 18–30 years [52%])
NA
NA
Anxiety and fear
FCV-19S, GAD-7
Depressive symptoms
PHQ-9
 Tull et al. (2020) [79]1
CS, OBS
USA
500; 235d (47%); 40 (11.6)
NA
March 27–April 5, 2020
Anxiety and fear
DASS-21 Anxiety, SHAI
Depressive symptoms
DASS-21 Depression
Stress
DASS-21 Stress
 Voitsidis et al. (2020) [83]1
CS, OBS
Greece
2363; 1800 (76.2%); NA (mode: 18–30 years [55%])
NA
April 10–13, 2020
Anxiety and fear
a
Depressive symptoms
PHQ-2
Sleep-related symptoms
AIS
Other outcomes
IUS-12, JGLS
 Wang C et al. (2020a) [84]1,2, Wang C et al. (2020b) [85]1
2 CS (repeated), OBS
China
1738 not counting participants in both surveys; 333 in both
1st survey: 1210; 814d or 878d (67.3%); NA (mode: 21.4–30.8 years [53.1%])
2nd survey: 861; 646d (75%); NA (mode: 21.4–30.8 years [46.5%])
NA
January 31–February 2, 2020 and February 28–March 1, 2020
Anxiety and fear
DASS-21 Anxiety
Depressive symptoms
DASS-21 Depression
Stress
DASS-21 Stress
PTSS
IES-R
 Wang H et al. (2020) [86]1
CS, OBS
China
1599; 1068 (66.8%); 33.9 (12.3)
NA
February 1–4, 2020
Psychological distress
K-6
 Wang Y et al. (2020) [87]1,2
CS, OBS
China
600; 333 (55.5%); 34 (12)
NA
February 6–9, 2020
Anxiety
SAS
Depressive symptoms
SDS
 Yang H et al. (2020) [88]1
CS (repeated), OBS
China
during COVID-19: 3000; 1500d (50%); 34.7 (NA)
NA
end of December 2019 and mid–February, 2020
Other outcomes
Emotional well-being (Kahneman and Deaton, 2010)
 Yuan R et al. (2020) [89]1
CS, OBS
China
parents of children hospitalised during the epidemic (EH): 50; 31 (62%d); 36.80 (5.20) parents of children hospitalised during the non-epidemic period (NEH): 50; 26 (52%d); 37.22 (5.40)
EH (n = 50)b, NEH (n = 50)b
NA
Anxiety
HADS Anxiety, VDAS
Depressive symptoms
HADS Depression
Other Outcomes
SF-36
 Zhang SX et al. (2020a) [90]1; Zhang SX et al. (2020b) [91]1
CS, OBS
China
369; 165 (44.7%); 36.6 (10.5)
NA
February 20–21, 2020
Psychological Distress
K6
Other outcomes
SF12, SWLS
 Zhang Y et al. (2020) [92]1,2
CS, OBS
China
263; 157 (60%); 37.7 (14.0)
NA
January 28–February 05, 2020
PTSS
IES
 Zhou SJ et al. (2020) [93]1
CS, OBS
China
8079; 4326 (53.5%); NA (median: 16, minimum 12, maximum 18 years)
100% senior high school studentsb
March 8–15, 2020
Anxiety
GAD-7
Depressive symptoms
PHQ-9
Healthcare workers
 Abdessater et al. (2020) [94]1
CS, OBS
France
275; 91d (33%) or 83d (30%), ambiguous data; 29.5 (0.47)
100% urologists
March 27–30, 2020
Stress
a
 Ahmed et al. (2020) [95]1
CS, OBS
multinational (Pakistan > Saudi Arabia > others)
650; 490 (75%); NA (mode: 20–30 years [54%])
100% dentists
March 10–17, 2020
Anxiety
8 binary itemsa
 Alhaj et al. (2020) [96]1
CS, OBS
multinational (Canada, USA, others)
52; 14 (27%); NA (mode: < 30 years [69%])
100% surgeons
April 14–28, 2020
Psychological distress
Affection of mental health (binary single item)a
 Amerio et al. (2020) [97]1
CS, OBS
Italy
131; 63 (48.1%); 52.3 (12.2)
100% physicians (general practitioners)
March 15–April 15, 2020
Anxiety
GAD-7
Depressive symptoms
PHQ-9
Sleep-related symptoms
ISI
Other outcomes
SF-12
 Badahdah et al. (2020) [98]1
CS, OBS
Oman
194; 116d (60%); 40.72 (8.53)
100% physicians
early April 2020
Anxiety
GAD-7
Stress
PSS-10
Other outcomes
WHO-5c
 Bohlken et al. (2020) [99]1
CS, OBS
Germany
396; NA; 165 (42%); 56.9 (7.6)
100% physicians
April 1–6, 2020
Anxiety and fear
Single items 5-P LSa
Sleep disorders
Single item 5-P LSa
 Cai H et al. (2020) [100]1,2
CS, OBS
China
534; 367 (69%); 36.4 (16.18)
physicians (n = 233), nurses (n = 248)
January–March, 2020
Anxiety and fear
Single items 4-P LSa
 Cai W et al. (2020) [101]1
CS, OBS
China
whole sample:
1521; 1149 (75.5%d); NA (mode: 18–30 years, [43.5%])
physicians (n = 511), nurses (n = 546)
NA
Anxiety and fear
SCL-90 anxiety
Depressive symptoms
SCL-90 depression
Psychological distress
SCL-90 positive items
Other outcomes
SCL-90 subscales, CD-RISC, SSRS
 Chew et al. (2020) [102]1
CS, OBS
multinational (Singapore, India)
906; 583 (64.3%); NA (median [IQR]: 29 [25–35] years)
physicians (n = 268), nurses (n = 355), allied healthcare professionals (n = 96), non-HCW (n = 187)
February 19–April 17, 2020
Anxiety and fear
DASS-21 anxiety
Depressive symptoms
DASS-21 depression
Stress
DASS-21 stress
Sleep-related symptoms
Single item 4-P LSa
PTSS
IES-R
 Consolo et al. (2020) [103]1
CS, OBS
Italy
356; 141 (39.6%); NA (mode: 35–55 years [48.6%])
100% dentists
April 2–21, 2020
Anxiety and fear
GAD-7
 Gan et al. (2020) [104]1
CS, OBS
China
11,183; 10,811 (96.7%); NA (mode: 20–29 years)
100% nurses
February 4–10, 2020
Anxiety and fear
VAS on anxiety
Stress
VAS on stress
 Huang JZ et al. (2020) [105]1,2
CS, OBS
China
230; 187 (81.3%); NA (mode: 30–39 years [53%])
physicians (n = 70), nurses (n = 160)
February 7–14, 2020
Anxiety and fear
SAS
PTSS
PTSD-SS
 Kang et al. (2020) [106]1,2
CS, OBS
China
994; 850 (85.5%); NA (mode: 30–40 years [63.4%])
physicians (n = 183), nurses (n = 811)
January 29–February 4, 2020
Anxiety and fear
GAD-7e
Depressive symptoms
PHQ-9e
Sleep-related symptoms
ISIe
PTSS
IES-Re
 Khusid et al. (2020) [107]1
CS, OBS
USA
332; 117 (35%); 30.5 (2.6)
100% urologists
April 7–11, 2020
Anxiety and fear
2 items 5-P LSa
Depressive symptoms
2 items 5-P LSa
 Lai et al. (2020) [18]1,2
CS, OBS
China
1257; 964 (76.7%); NA (mode: 26–40 years [64.7%])
physicians (n = 493), nurses (n = 764)
January 29–February 3, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
Sleep-related symptoms
ISI
PTSS
IES
 Mo et al. (2020) [108]1,2
CS, OBS
China
180; 162 (90%); 32.71 (6.52)
NA
end of February 2020
Anxiety and fear
SAS
Stress
SOS
 Pu et al. (2020) [109]1
CS, OBS
China
867: 829 (95.6%d); 30.8 (7.1)
100% nurses
NA
Anxiety and fear
SAS
Other outcomes
TAF
 Rossi et al. (2020) [110]1
CS, OBS
Italy
1379; 1064 (77.2%); 39.0 (6.0)
physicians (n = 433), general practitioners (n = 86), nurses (n = 472)
March 27–31, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
Stress
PSS
Sleep-related symptoms
ISI
PTSS
GPS–PTSD
 Sahu et al. (2020) [111]1
CS, OBS
India
611; NA; NA (mode: 30–40 years, n = 192 [31·4%])
100% orthopedic surgeons
March 31–April 4, 2020
Stress
Single-itema
 Shacham et al. (2020) [112]1
CS, OBS
Israel
338; 198 (586%); 46.39 (11.2)
dentists (n = 198), dental hygienists (n = 140d)
March 30–April 10, 2020
Psychological distress
K-6
 Suleiman et al. (2020) [113]1
CS, OBS
Jordan
308; 113 (36.7%); 30.3 (5.8)
100% physicians
March 23–27, 2020
Anxiety and fear
Binary single itemsa
 Tan B et al. (2020) [114]1
CS, OBS
Singapore
470; 321 (68.3%); NA (median: 31, IQR: 28–36 years)
physicians (n = 135), nurses (n = 161), allied hospital personnel (n = 174)
February 19–March 13, 2020
Anxiety and fear
DASS-21 anxiety
Depressive symptoms
DASS-21 depression
Stress
DASS-21 stress
PTSS
IES-R
 Wang S et al. (2020) [115]1
CS, OBS
China
123; 111 (90%); 33.75 (8.41)
100% pediatricians;
physicians (n = 48), nurses (n = 75)
January 30–February 07, 2020
Anxiety and fear
SAS
Depressive symptoms
SDS
Sleep-related symptoms
PSQI
 Wu K et al. (2020) [116]1
CS, OBS, controlled
China
experimental group: 60; 44 (73%); 33.5 (12.4)
comparison group: 60; 45 (75%) 33.8 (11.9)
COVID-19 hospital (n = 60), non-designated hospital = comparison group (n = 60)
NA
Anxiety and fear
SAS, SCL-90 anxiety
Depressive symptoms
SCL-90 depression, SDS
Sleep-related symptoms
PSQI
PTSS
PCL-C
Psychological distress
SCL-90 total score
Other outcomes
SCL-90 subscales
 Xiao et al. (2020a) [117]1,2
CS, OBS
China
180; 129 (71.7%); 32.31 (4.88)
physicians (n = 82), nurses (n = 98)
January–February, 2020
Anxiety and fear
SAS
Sleep-related symptoms
PSQI
Other outcomes
GSES, SASR, SSRS
 Xu J et al. (2020) [118]1
CS, OBS, controlled
China
outbreak period: 60; 38 (63.3%); 36.68 (9.67)
‘post-epidemic’: 60; 32 (53.3%); 35.77 (7.06)
100% surgeons
January 28–February 29, 2020 and March 2–21, 2020
Anxiety and fear
‘Anxiety scale’, dream anxiety score
Depressive symptoms
‘Depression score’
Other outcomes
SF-36
 Yin et al. (2020) [119]1
CS, OBS
China
371; 228 (61.5%); 35.3 (9.5)
physicians: NA
nurses: NA
physicians (n = 67), nurses (n = 264)
February 01–05, 2020
Sleep-related symptoms
PSQI
PTSS
PCL-5
 Zhang C et al. (2020) [120]1
CS, OBS
China
1563; 1293 (83%d); NA (mode: 26–40 years, n = 495 [31.7%d])
physicians: NA
nurses: NA
physicians (n = 454), nurses (n = 984), administrative staff (n = 30), other medical staff (n = 95)
January 29–February 03, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
Sleep-related symptoms
ISI
PTSS
IES-R
 Zhang SX et al. (2020c) [121]1
CS, OBS
Iran
304; 178 (58.6%); 35.1 (9.1)
NA
April 5–20, 2020
Anxiety and fear
GAD-2d
Depressive symptoms
PHQ-2d
Psychological distress
K6
Other outcomes
SF-12
 Zhu J et al. (2020) [122]1
CS, OBS
China
156; 137 (83%); 34.16 (8.06)
physicians: 79; 51d (65%d)
physicians (n = 79), nurses (n = 86)
February 1–29, 2020
Anxiety and fear
SAS
Depressive symptoms
SDS
Patients
 Cai X et al. (2020) [123]1, Yuan B et al. (2020) [124]1
CS, OBS
China
126; 66 (52.4%); 45.7 (14.0)
100% cured COVID-19 patients
March 2–12, 2020
Anxiety and fear
SAS
Depressive symptoms
SDS
PTSS
PTSD-SS
 Durankus et al. (2020) [125]1
CS, OBS
Turkey
260; 260 (100%); 29.6 (3.8)
100% pregnant women
NA
Anxiety and fear
BAI
Depressive symptoms
EPDS, BDI
Psychological distress
Single item 11-P LSa
 Li X et al. (2020) [126]1
CS, OBS
China
76; 35 (46%); 36 (15)
suspected COVID-19 patients
January 31–February 22, 2020
Anxiety and fear
HAMA
Depressive symptoms
HAMD
 Liu X et al. (2020a) [42]1
CS, OBS
China
COVID-19 suspected patients:
21; 12 (57.1%); 43.1 (2.6):
not COVID-19 suspected patients: 30; 15 (50%); 45.0 (9.2)
100% schizophrenia patients; COVID-19 suspected patients (n = 21), not COVID-19 suspected patients (n = 30)
January 30–February 21, 2020
Anxiety and fear
HAMA
Depressive symptoms
HAMD
Stress
PSS
Sleep-related symptoms
PSQI
Other outcomes
PANSS
 Wu Y et al. (2020) [127]1,3
CS, OBS, controlled
China
4124; 4124 (100%d), NA (median: 30, range = 17–32 years)
100% pregnant women;
before (group 1: n = 2839)/after (group 2: n = 1284) January 20, 2020
January 1–February 9, 2020
Anxiety and fear
EPDS-3A
Depressive symptoms
EPDS
 Xu H et al. (2020) [128]1
CS, OBS
China
350; 199 (54.1%); NA (mode: 40–60 years [51%])
100% lung cancer patients
March 4–6, 2020
Depressive symptoms
Single itema
Sleep-related symptoms
Single itema
 Yassa et al. (2020) [129]1
CS, OBS
Turkey
172; 172 (100%); 27.5 (5.3)
100% pregnant women
ten days after first confirmed COVID-19 death in Turkey
Anxiety and fear
Single ternary itema
Mixed groups
 Büntzel et al. (2020) [130]1
CS, OBS
Germany
193; NA; NA (mode: > 60 years)
physicians (n = 47), cancer patients (n = 146)
April 16–19, 2020
Anxiety and fear
Single itema
Stress
Single itema
 Guo et al. (2020) [131]1
CS, OBS, controlled
China
P:103; 44 (42.7%); 42.5 (12.5);
control (GP): 103; 49 (47.6%); 41.5 (13.1)
COVID-19 patients (n = 103), not infected control group (n = 103)
February 10–28, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
Stress
PSS-10
PTSS
PCL-5
 Hao F et al. (2020) [132]1
CS, OBS, controlled
China
P: 76; 51 (37.1%); 32.8 (11.8);
control (GP): 109; 68 (62.4%); 33.1 (11.2)
psychiatric patients (n = 76), control group (n = 109)
February 19–22, 2020
Anxiety and fear
DASS-21 anxiety
Depressive symptoms
DASS-21 depression
Stress
DASS-21 stress
Sleep-related symptoms
ISI
PTSS
IES-R
 Hao X et al. (2020) [133]1
CS, OBS, controlled
China
P: 252; 132d (52.4%d); 29.3 (11.6);
control (GP): 252; 132d (52.4%d); 29.4 (11.5)
epilepsy patients (n = 252), control group (n = 252)
February 1–29, 2020
Psychological distress
K-6
 Huang Y et al. (2020) [134]1,2
CS, OBS
China
7236; 3952 (54.6%); 35.3 (5.6)
GP (n = 4986), HCW (n = 2250)
February 3–17, 2020
Anxiety and fear
GAD-7
Depressive symptoms
CES-D
Sleep-related symptoms
PSQI
 Iasevoli et al. (2020) [135]1
CS, OBS, controlled
Italy
461; NA; NA
P: 205; NA; NA
caregivers: 51; NA; NA
control (GP): 205; NA; NA
psychiatric patients (n = 205), caregivers (n = 51), non-psychiatric persons (n = 205)
April 13–17, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
Stress
PSS
Other outcomes
SPEQ
 Jin YH et al. (2020) [136]1
CS, OBS
China
103; 64 (62.1%); NA (median [IQR]: 35 [14.0])
100% infected with SARS-CoV-2; physicians, nurses
February 15–29, 2020
Anxiety and fear
Single item multiple choicea
 Ko et al. (2020) [137]1
CS, OBS
Taiwan
1904; 1282 (67.3%); 38.0 (10.8)
GP (n = NA), HCW (n = NA)
April 10–20, 2020
Other outcomes
Psychological wellbeing (single item 5-P LS)a
 Li Z et al. (2020) [138]1,2
CS, OBS
China
740; 128 (59.8%); 25 (IQR: 22–38.3 years]
GP (n = 214), HCW (n = 526)
February 17–21, 2020
PTSS
Vicarious Traumatization Questionnaire
 Lu W et al. (2020) [139]1,2
CS, OBS
China
2299; 1785 (77.6%); NA (78% < 40 years)
HCW (n = 2042), GP (n = 257)
February 25.26, 2020
Anxiety and fear
HAMA, NRS on fear
Depressive symptoms
HAMD
 Ni et al. (2020) [140]1
CS, OBS
China
total: 1791; NA; NA
GP: 1577; 1218 d (60.8%); NA (mode: 18–34 years [38.6%])
HCW: 214; 147d (68.8%); NA (mode: 18–34 years [58.9%])
GP (n = 1577), HCW (n = 214)
February 18.24, 2020
Anxiety and fear
GAD-2
Depressive symptoms
PHQ-2
 Sanchez et al. (2020) [67]1
CS, OBS
USA
1051; 0 (0%); 35 (15.83)
100% men who have sex with men; HIV-patients (n = 122)
April 2–13, 2020
Anxiety and fear
Single itema
Other outcomes
Quality of life (single item)a
 Wu W et al. (2020) [141]1
CS, OBS
China
4268; 2930d (68.7%d); NA
HCW: 2110; 1598d (76%d); NA
Students: 2158; 1332 (62%); NA
students (n = 2158), HCW (n = 2110)
February 10–21, 2020
Anxiety and fear
Single itema
Sleep-related symptoms
Single itema
 Yuan S et al. (2020) [142]1,2
L, OBS
China
939; 582 (61.98%); NA (mode: 18–39 years [71.5%])
HCW (n = 249), students (n = 312)
2 survey periods in February, 2020
Sleep-related symptoms
PSQI
Other outcomes
SRQ
 Zhang J et al. (2020) [143]1
CS, OBS
China
205; 115 (56.1%d); NA (for infected: 46.9 [15.4]; for quarantined: 36.2 [10.9]; for general public: 29.6 [12.7])
P, infected (n = 57),
GP, quarantined (n = 50),
GP, general public (n = 98)
February 15–29, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
 Zhang WR et al. (2020) [144]1,2
CS, OBS
China
2182; 1401 (64.2%); NA (mode: 18–60 years [96.3%])
HCW (n = 927), GP (n = 1255)
February 19–March 6, 2020
Anxiety and fear
GAD-2
Depressive symptoms
PHQ-2
Sleep-related symptoms
ISI
Other outcomes
SCL-90-R subscales
 Zhu S et al. (2020) [145]1
CS, OBS
China
2279d; 1361 d; NA
HCW (n = 858), GP (n = 1421)
Feb 12–Mar 17, 2020
Anxiety and fear
GAD-7
Depressive symptoms
PHQ-9
Psychological distress
SRQ-20
Abbreviations: AIS Athens Insomnia Scale, BAI Beck Anxiety Inventory, BDI Beck Depression Inventory, BDI(−II) Beck Depression Inventory(−II), BIP-Q5 Brief Illness Perception Questionnaire 5, BRCS Brief Resilience Coping Scale, CD-RISC Connor-Davidson Resilience Scale, CES-D Center for Epidemiologic Studies Depression Scale, CoVGAD-7 Generalized Anxiety Disorder Scale-7 for COVID-19 Anxiety, CPDI CoViD-19 Peritraumatic Distress Index, CS cross-sectional, DASS-21 Depression Anxiety Stress Scale-21, DT Distress Thermometer, EPDS Edinburgh Postnatal Depression Scale, EPDS-3A Edinburgh Postnatal Depression Scale-Anxiety subscale, FACIT-Sp12 Functional Assessment of Chronic Illness Therapy-Spiritual Well-Being Scale, FCV-19S Fear of COVID-19 scale, GAD-2(−7) Generalized Anxiety Disorder Scale-2(/−7), GP general population, GPS-PTSD Global Psychotrauma Scale-posttraumatic stress disorder subscale, GSES General Self-Efficacy Scale, GSI Global Severity Index, HADS Hospital Anxiety and Depression Scale, HAI Health Anxiety Inventory, HAMA Hamilton Anxiety Rating Scale, HAMD Hamilton Depression Rating Scale, HCW healthcare workers, IES Impact of Event Scale, IES-R Impact of Event Scale-Revised, IQR interquartile range, ISI Insomnia Severity Index, IUS-12 Intolerance of Uncertainty Scale-Short Form, JGLS De Jong Gierveld Loneliness Scale, K-6(/− 10) Kessler Psychological Distress Scale-6(/− 10), L longitudinal, MINI Mini International Neuropsychiatric Interview, MSPSS Multidimensional Scale of Perceived Social Support, NA not available, NRS Numeric Rating Scale, OBS observational, P patients, PANSS Positive and Negative Syndrome Scale, PCL-5(−C) Post-traumatic Stress Disorder Checklist-5(/−Civilian Version), PHQ-2(/−4/−9/− 15) Patient Health Questionnaire-2(/−4/−9/− 15), PROMIS-SFs Patient Reported Outcomes Measurement Information System short forms, PSQI Pittsburgh Sleep Quality Index, PSS(− 10) Perceived Stress Scale(− 10), PTSD-SS Post-traumatic Stress Disorder Self-rating Scale, PTSS post-traumatic stress symptoms, Ryff’s PWB Ryff’s Psychological Wellbeing Scales, SAS Self-Rating Anxiety Scale, SASR Stanford Acute Stress Reaction, SCL-90 Symptom Checklist-90, SCS Self-Compassion Scale, SD standard deviation, SDQ Strengths and Difficulties Questionnaire, SDS Self-Rating Depression Scale, SF-12(/−36) Short Form 12 Health Survey, SHAI Short Health Anxiety Inventory, SOS Stress Overload Scale, SPEQ Specific Psychotic Experience Questionnaire, SRQ Stress Response Questionnaire, SRQ-20 20-item Self-Report Questionnaire, SSRS Social Support Rating Scale, SSS Somatic Symptom Scale, STAI-Y State Trait Anxiety Inventory-Y, SWLS Satisfaction With Life Scale, TAF Triage Assessment Form, TEMPS-A Temperament Evaluation of Memphis, Pisa, Paris and San Diego-Anxious, VAS Visual Analogue Scale, VDAS Van Dream Anxiety Scale, WHO-5 World Health Organization- Five Well-Being Index, WHOQOL-BREF abbreviated World Health Organization Quality of Life, 4−/5−/7−/11-P LS 4−/5−/6−/11-point Likert-scale
a developed by study authors
b included in main analyses for general population but considered separately in subgroup-analyses
c in Gao J et al. WHO-5 is used to assess depressive symptoms, in Badahdah et al. it is used to assess psychological distress
d not directly reported
e k-means-clustering method for the 4 tools summarized to ‘mental health’
Although we imposed no restrictions on the age limits, we identified no studies conducted in children but did find some studies in the general population that included participants below the age of 18 years [47, 58]1. Thus, the mean age of participants in the pandemic studies ranged from 20 (SD not reported) to 56.9 (SD 7.6) years [49, 99]1. The studies covered Asia (67 studies [26, 4143, 49, 50, 54, 57, 58, 60, 62, 64, 71, 74, 76, 80, 81, 85, 86, 8891, 93, 98, 101, 102, 104, 109, 111116, 118123, 126, 124, 128, 131133, 136, 137, 140, 141, 143, 145]1 [18, 48, 59, 73, 84, 87, 92, 100, 105, 106, 108, 117, 134, 138, 139, 142, 144]1,2 [127]1,3) thereof from China [42, 49, 50, 57, 58, 60, 62, 64, 71, 80, 81, 85, 86, 8891, 93, 101, 104, 109, 115, 116, 118120, 122124, 126, 128, 131133, 136, 140, 141, 143, 145][18, 48, 59, 84, 87, 92, 100, 105, 106, 108, 117, 134, 138, 139, 142, 144]1,2 [127]1,3, Europe (24 studies) [47, 99, 4446, 5153, 55, 61, 63, 65, 66, 68, 70, 110, 77, 78, 82, 83, 94, 97, 130, 103, 135]1, North America (six studies) [56, 67, 79, 107, 146, 147]1, or different continents (seven studies) [69, 72, 75, 95, 96, 125, 129]1. For 13 studies investigating more than one population, several samples were considered [130133, 135, 140, 141, 143, 145]1 [134, 138, 139, 144]1,2. We identified 47 matching prepandemic comparative studies (eTable 10), including one pandemic study reporting adequate comparative data [127]1,3 [148193]3.
Prevalence rates of the six mental health symptoms, that were considered for the review, were available for a varying number of included pandemic studies (Table 2). The proportion of participants beyond a cut-off value in the included studies varied considerably (eg, anxiety in general population: 0.7–64.0%). Based on cut-off values reported in the primary studies (eTable 11), we found increased levels of mental burden during the SARS-CoV-2 pandemic in the general population, healthcare workers, and patients regarding each of the symptoms observed during the current pandemic, that is, without considering the prepandemic situation.
Table 2
Narrative synthesis of prevalence based on scores above cut-off values for different mental health outcomes
 
Number of studiesa
Lowest reported prevalence (%)
Highest reported prevalence (%)
General population
 Anxiety, worries, fear
24 (18 GP, [45, 47, 49, 50, 52, 57, 63, 66, 68, 69, 71, 77, 93]1 [73, 84, 87]1,2
6 M [132, 140, 145]1 [134, 139, 144]1,2)
0.67 (63)
64.0 (46)
 Depressive symptoms
18 (13 GP [45, 49, 50, 52, 57, 63, 66, 68, 69, 71, 93]1 [84, 87]1,2,
5 M [132, 140, 145]1 [139, 144]1,2)
0.9 (89)
48.3 (48)
 PTSS
7 (6 GP [526671]1 [598492]1,2, 1 M [132]1)
7.0 (51)
53.8 (55)
 Sleep-related symptoms
6 (3 GP [7183]1 [84]1,2, 3 M [132]1 [134144]1,2)
0.9 (89)
37.6 (131)
 Stress
5 (4 GP [66687183]1, 1 M [132]1)
0.9 (89)
67.9 (55)
 Psychological distress
7 (5 GP [4145586581]1, 2 M [133136]1)
1.6 (90)
65.2 (112)
Healthcare workers
 Anxiety, worries, fear
22 (14 HCW [9995, 113102103110115120122121]1 [18100105106]1,2,
6 M [130140145]1 [134139144]1,2 )
7.0 (108)
92.0 (144)
 Depressive symptoms
14 (9 HCW [97102110115120121122]1 [18, 106]1,2,
5 M [140, 145]1 [134139, 144]1,2)
0.6 (110)
50.4 (18)
 PTSS
7 (HCW) [102, 110119, 120]1 [18105, 106]1,2
3.8 (82)
73.0 (83)
 Sleep-related symptoms
9 (7 HCW [99, 102, 110, 115, 120]1 [18106]1,2, 2 M [134]1 [144]1,2)
8.27 (127)
38.0 (108)
 Stress
6 (5 HCW [94102110111][108]1,2, 1 M [130]1)
5.2 (102)
56.5 (114)
 Psychological distress
5 (4 HCW [96101112121]1, 1 M [145]1)
11.1 (101)
90.4 (145)
Patients
 Anxiety, worries, fear
6 (5P [123126129131143]1, 1 M [132]1)
19.5 (99)
80.2 (143)
 Depressive symptoms
8 (7 P [123125126128131143]1 [127]1,3, 1 M [132]1)
27.8 (99)
55.3 (88)
 PTSS
2 (1 P [123]1, 1 M [132]1)
31.0 (84)
43.4 (89)
 Sleep-related symptoms
2 (1 P [128]1, 1 M [132]1)
27.6 (89)
66.3 (97)
 Stress
1 (M [132]1)
17.0 (89)
 Psychological distress
1 (M [133]1)
13.1 (90)
Abbreviations: GP general population, HCW healthcare workers, M mixed samples, P patients, PTSS posttraumatic stress symptoms
a reporting prevalence rates for the respective mental health outcome
In pairwise meta-analyses comparing pandemic (early phase) with prepandemic data for the four primary outcomes, however, we found only evidence for a small increase of anxiety (standardized mean difference [SMD] 0.40; 95% CI 0.15–0.65; p = .002) and a moderate increase of depressive symptoms (SMD 0.67; 95% CI 0.07–1.27; p = .03) in the general population. No evidence for a change in stress or sleep-related symptoms was identified (Table 3). For healthcare workers compared with healthcare staff before the pandemic, the meta-analyses showed no evidence of any effect on the primary outcomes (Table 3). The same was found for patients (Table 3); however, prepandemic data in patients were only available for four samples. Forest plots are presented in Figs. 2, 3, and eResults 1 in the Additional file 2.
Table 3
Results of main and sensitivity analyses in three populations
Outcome
Studies (samples)
N (pandemic)
N (comp.)
Standardized mean difference (95% CI)
I2
95% prediction intervala
Main analyses
General population
 Anxiety
23 (26)
49,746
132,145
0.40 (0.15–0.65)
99%
− 0.87–1.67
 Depression
25 (28)
60,213
183,747
0.67 (0.07–1.27)
100%
−2.02–3.36
 Stress
11 (13)
11,600
67,386
0.10 (−0.30–0.50)
100%
−1.39–1.60
 Sleep-related symptoms
4 (4)
3332
7635
0.74 (−1.47–2.96)
100%
−3.68–5.17
Healthcare workers
 Anxiety
13 (14)
5508
22,204
−0.08 (−0.66–0.49)
99%
−1.75–1.58
 Depression
7 (8)
2226
4605
−0.16 (− 0.59–0.26)
97%
−1.41–1.09
 Stress
3 (3)
1570
2454
0.49 (−0.60–1.57)
99%
/
 Sleep-related symptoms
4 (5)
554
20,024
0.83 (−0.14–1.81)
99%
−1.54–3.21
Patients
 Anxiety
6 (6)
1845
12,458
0.31 (−0.07, 0.69)
93%
−1.08–1.69
 Depression
7 (7)
2138
24,444
0.48 (−0.08–1.04)
98%
−1.58–2.53
 Stress
4 (4)
435
10,061
−0.10 (− 0.81–0.61)
98%
−3.54–3.34
 Sleep-related symptoms
2 (2)
127
298
−0.61 (−1.75–0.54)
96%
/
Sensitivity analysis – Quality of included pandemic studies (ie, exclusion of poor-quality studies)
General population
 Anxiety
16 (17)
38,323
81,350
0.53 (0.19–0.86)
100%
−0.90–1.95
 Depression
18 (19)
48,790
136,884
0.83 (0.09–1.57)
100%
−2.17–3.82
 Stress
7 (8)
9110
43,747
0.33 (−0.19–0.84)
100%
−1.20–1.85
 Sleep-related symptoms
3 (3)
2659
6622
0.80 (−1.34–2.94)
100%
/
Healthcare workers
 Anxiety
4 (4)
1655
4124
−0.18 (−0.78–0.41)
97%
−1.30–0.94
 Depression
4 (4)
1655
2356
0.03 (−0.42–0.47)
90%
−0.73–0.79
 Stress
2 (2)
1376
1872
−0.05 (− 0.37–0.26)
95%
/
 Sleep-related symptoms
1 (1)
123
4951
−0.03 (− 0.21–0.15)
/
/
Patients
 Anxiety
3 (3)
1461
11,116
0.45 (−0.10–1.01)
92%
/
 Depression
3 (3)
1461
21,934
0.21 (−1.08–1.49)
99%
/
 Stress
1 (1)
51
51
0.18 (−0.21–0.57)
/
/
 Sleep-related symptoms
1 (1)
51
207
−0.03 (− 0.33–0.28)
/
/
Sensitivity analysis – Level of comparability between included pandemic studies and comparative studies (ie, exclusion of level-3 and level-4 studies)
General population
 Anxiety
12 (13)
38,461
32,698
0.40 (0.06–0.74)
99%
−0.77–1.57
 Depression
14 (15)
38,259
78,619
0.77 (−0.23–1.77)
100%
−2.72–4.25
 Stress
7 (8)
8624
12,739
−0.15 (− 0.76–0.46)
99%
−1.84–1.53
 Sleep-related symptoms
2 (2)
2550
5609
1.54 (−1.18–4.27)
100%
/
Healthcare workers
 Anxiety
7 (8)
3147
9511
−0.54 (−1.23–0.15)
99%
−2.11–1.03
 Depression
4 (5)
546
2576
−0.38 (−1.56–0.79)
98%
−2.60–1.84
 Stress
/
/
/
/
/
/
 Sleep-related symptoms
3 (4)
423
19,804
1.01 (−0.17–2.18)
99%
−1.61–3.63
Patients
 Anxiety
4 (4)
1616
3184
0.23 (−0.33–0.79)
92%
−2.47–2.93
 Depression
4 (4)
1704
3205
0 (−0.56–0.56)
93%
−2.69–2.70
 Stress
2 (2)
127
217
0.15 (−0.08–0.37)
0%
/
 Sleep-related symptoms
2 (2)
127
298
−0.61 (−1.75–0.54)
96%
/
Abbreviations: CI confidence interval, comp. comparative studies, I2 heterogeneity, N sample size, pandemic included pandemic studies
a 95% prediction interval only calculated for meta-analyses with at least k = 4 studies
Of the 104 studies, 38 studies were judged to be of fair quality and 57 studies of poor quality, with main concerns regarding selection bias, the validity of outcome measures, and the description of the sample and the survey period (eTable 12). From nine high-quality studies, four were representative surveys [44, 47, 77, 88]1. From the 85 pairwise comparisons relevant for meta-analyses, 52 comparisons were of level-1 and 33 of level-2 quality (eTable 13). When excluding low-quality pandemic studies (Table 3), the effects on anxiety and depressive symptoms in the general population increased. The effect on anxiety in the general population was stable in the sensitivity analysis when only best comparable data sets (ie, level-1 and level-2 comparability) were included, while there was no longer evidence for an effect on depressive symptoms (Table 3 and eResults 2 in Additional file 2).
Heterogeneity was considerable in main and sensitivity analyses, with I2 scores mostly ranging from 90 to 100% and wide prediction intervals (Table 3). We therefore performed subgroup analyses with at least k = 5 studies in the main analyses in attempts to explain this heterogeneity (Table 4; eResults 3 in Additional file 2).
Table 4
Results of subgroup analyses for those populations and outcomes with at least k = 4 studies in main analysis
Subgroup analysis (subgroups)
Outcome
Test for subgroup differencesa
Population
Subgroup difference: elevated effectb
Subgroup difference: reduced effectb
Population characteristics (main studies)
Age
• 30 years
• > 30 ≤ 35 years
• > 35 ≤ 40 years
• > 40 ≤ 45 years
• multiple age groups
• age not specified
Anxiety
Chi2 = 9.5, df = 5 (p = .09)
GP
/
/
Depression
Chi2 = 29.3, df = 5 (p < .001)
GP
≤30 years; > 40 ≤ 45 years
/
Stress
Chi2 = 1043.3, df = 4 (p < .001)
GP
/
> 40 ≤ 45 years
Anxiety
Chi2 = 8.7, df = 4 (p = .07)
HCW
/
/
Depression
Chi2 = 2.2, df = 1 (p = .14)
HCW
/
/
Sleep
Chi2 = 0.3, df = 1 (p = .57)
HCW
/
/
Anxiety
Chi2 = 17.14, df = 4 (p = .002)
P
> 40 ≤ 45 years
 
Depression
Chi2 = 3.74, df = 4 (p = .44)
P
/
/
Stressor exposure
• General population
• Students
• Others
• Special exposure
Anxiety
Chi2 = 2.8, df = 3 (p = .42)
GP
/
/
Depression
Chi2 = 1.9, df = 3 (p = .60)
GP
/
/
Stress
Chi2 = 0.12, df = 3 (p = .99)
GP
/
/
Covid-19 patient contact
• Low contact risk
• High contact risk
Anxiety
Chi2 = 0, df = 1 (p = .95)
HCW
/
/
Depression
Chi2 = 1.0, df = 1 (p = .31)
HCW
/
/
Sleep
Chi2 = 0.2, df = 1 (p = .69)
HCW
/
/
Subgroup of patients
• COVID-19 patients
• Pregnant women
• Psychiatric patients
Anxiety
Chi2 = 0.3, df = 2 (p = .88)
P
/
/
Depression
Chi2 = 1.3, df = 2 (p = .51)
P
/
/
Pandemic study characteristics
Survey startc
• ≤4 weeks
• > 4 ≤ 6 weeks
• > 6 ≤ 8 weeks
• > 8 weeks
• not specified
Anxiety
Chi2 = 3.55, df = 4 (p = .47)
GP
/
/
Depression
Chi2 = 10.15, df = 4 (p = .04)
GP
> 8 weeks
/
Stress
Chi2 = 0.31, df = 4 (p = .99)
GP
/
/
Anxiety
Chi2 = 7.91, df = 4 (p = .10)
HCW
/
/
Depression
Chi2 = 0.95, df = 2 (p = .62)
HCW
/
/
Sleep
Chi2 = 4.21, df = 2 (p = .12)
HCW
/
/
Anxiety
Chi2 = 4.58, df = 2 (p = .10)
P
/
/
Depression
Chi2 = 3.08, df = 3 (p = .38)
P
/
/
Study conduction China
• China
• Non-China
Anxiety
Chi2 = 0.10, df = 1 (p = .75)
GP
/
/
Depression
Chi2 = 0.60, df = 1 (p = .44)
GP
/
/
Stress
Chi2 = 0.10, df = 1 (p = .76)
GP
/
/
Anxiety
Chi2 = 2.84, df = 1 (p = .09)
HCW
/
/
Depression
Chi2 = 0.08, df = 1 (p = .78)
HCW
/
/
Sleep
Chi2 = 0.32, df = 1 (p = .57)
HCW
/
/
Anxiety
Chi2 = 3.35, df = 1 (p = .07)
P
/
/
Depression
Chi2 = 0.62, df = 1 (p = .43)
P
/
/
Outcome measure
• AIS
• BDI
• DASS-21
• EDPS
• EPDS-3A
• GAD-2; GAD-7
• HADS
• HAMA
• HAMD
• ISI
• PHQ-2; PHQ-9
• PSQI
• PSS
• SAS
• SDS
• SCL-90
• STAI-Y
Anxiety
Chi2 = 10.7, df = 6 (p = .10)
GP
/
/
Depression
Chi2 = 11.46, df = 5 (p = .04)
GP
PHQ-2
/
Stress
Chi2 = 0.16, df = 1 (p = .69)
GP
/
/
Anxiety
Chi2 = 2.80, df = 4 (p = .59)
HCW
/
/
Depression
Chi2 = 2.91, df = 3 (p = .41)
HCW
/
/
Sleep
Chi2 = 0.32, df = 1 (p = .57)
HCW
/
/
Anxiety
Chi2 = 1.18, df = 4 (p = .88)
P
/
/
Depression
Chi2 = 16.95, df = 5 (p = .005)
P
SDS; PHQ-9
/
Sample size
• < 1000
• ≥1000
Anxiety
Chi2 = 1.86, df = 1 (p = .17)
GP
/
/
Depression
Chi2 = 0.03, df = 1 (p = .86)
GP
/
/
Stress
Chi2 = 2.31, df = 1 (p = .13)
GP
/
/
Anxiety
Chi2 = 2.83, df = 1 (p = .09)
HCW
/
/
Depression
Chi2 = 0, df = 1 (p = .96)
HCW
/
/
Sleep
not possible
HCW
/
/
Anxiety
Chi2 = 3.60, df = 1 (p = .06)
P
/
/
Depression
Chi2 = 0.09, df = 1 (p = .77)
P
/
/
Comparative study characteristics
Sample size
• ≤500
• > 1000 ≤ 5000
• > 5000 ≤ 10,000
• > 10,000
Anxiety
Chi2 = 0.9, df = 3 (p = .83)
GP
/
/
Depression
Chi2 = 3.5, df = 4 (p = .48)
GP
/
/
Stress
Chi2 = 8.6, df = 3 (p = .03)
GP
/
> 5000 ≤ 10,000 participants
Anxiety
Chi2 = 9.93, df = 3 (p = .02)
HCW
> 5000 ≤ 10,000 participants
 
Depression
Chi2 = 4.3, df = 2 (p = .12)
HCW
/
/
Sleep
Chi2 = 0.3, df = 1 (p = .57)
HCW
/
/
Anxiety
Chi2 = 0.1, df = 2 (p = .97)
P
/
/
Depression
Chi2 = 3.9, df = 2 (p = .14)
P
/
/
Publication year
• ≤1 year ago
• ≤2 years ago
• > 2 ≤ 5 years ago
• > 5 ≤ 10 years ago
• > 10 years ago
Anxiety
Chi2 = 8.0, df = 5 (p = .16)
GP
/
/
Depression
Chi2 = 12.4, df = 5 (p = .03)
GP
> 10 years ago
/
Stress
Chi2 = 11.6, df = 4 (p = .02)
GP
/
≤1 year ago
Anxiety
Chi2 = 14.5, df = 3 (p = .002)
HCW
> 10 years ago
≤2 years ago
Depression
Chi2 = 4.6, df = 1 (p = .03)
HCW
/
≤2 years ago
Sleep
not possible
HCW
/
/
Anxiety
Chi2 = 0.1, df = 2 (p = .94)
P
/
/
Depression
Chi2 = 17.0, df = 5 (p = .005)
P
≤1 year ago; > 5 ≤ 10 years ago
/
Pandemic and comparative study characteristics
Relationship samples sizesd
• Ratio ≥ 2
• Ratio ≥ 0.5 < 2
• Ratio ≥ 0.1 < 0.5
• Ratio < 0.1
Anxiety
Chi2 = 10.0, df = 3 (p = .02)
GP
Ratio ≥ 0.5 < 2
/
Depression
Chi2 = 4.8, df = 3 (p = .19)
GP
/
/
Stress
Chi2 = 0.4, df = 2 (p = .84)
GP
/
/
Anxiety
Chi2 = 4.2, df = 2 (p = .12)
HCW
/
/
Depression
Chi2 = 3.8, df = 2 (p = .15)
HCW
/
/
Sleep
Chi2 = 0.32, df = 1 (p = .57)
HCW
/
/
Anxiety
Chi2 = 17.7, df = 3 (p < .001)
P
Ratio ≥ 0.5 < 2; Ratio < 0.1
/
Depression
Chi2 = 3.0, df = 3 (p = .39)
P
/
/
Abbreviations: AIS Athens Insomnia Scale, BDI Beck Depression Inventory, DASS-21 Depression Anxiety Stress Scale-21, df degrees of freedom, EPDS Edinburgh Postnatal Depression Scale, EPDS-3A Edinburgh Postnatal Depression Scale-Anxiety subscale, GAD Generalized Anxiety Disorder Scale, GP general population, HADS Hospital Anxiety and Depression Scale, HAMA Hamilton Anxiety Rating Scale, HAMD Hamilton Depression Rating Scale, HCW healthcare workers, p p value, P patients, PHQ Patient Health Questionnaire, PSS Perceived Stress Scale, SAS Self-Rating Anxiety Scale, SCL-90 Symptom Checklist-90, SDS Zung Self-Rating Depression Scale, STAI-Y, State Trait Anxiety Inventory-Y
a Chi2 = test for subgroup differences
b ordered by size of effect estimate (SMD)
c since first COVID-19 cases in the respective country or, in case of China, since January 20, 2020
d ratio of sample size in pandemic study vs comparative study
Regarding population characteristics (pandemic studies), age was no consistent risk or protective factor. Within the general population, we identified no evidence for a subgroup difference according to stressor exposure except for elevated sleep symptoms in isolated individuals [62]1. In healthcare workers, there was no evidence for a moderating effect of COVID-19 patient contact on mental health. In different groups of patients, we identified no evidence of differences in anxiety or depression. Compared with COVID-19 patients [131]1, psychiatric patients reported more stress, with the caveat of few studies [42, 132, 135]1.
Among general characteristics of the pandemic studies, we found no (consistent) evidence of differences depending on when the surveys started, whether they were conducted in China, or the sample size. We found evidence of an elevated level of depressive symptoms in the general population and patients depending on the specific outcome measure employed (eg, Patient Health Questionnaire [PHQ], Zung Self-Rating Depression Scale [SDS]).
In subgroup analyses for comparative study characteristics, there was no evidence of a consistent moderation of comparison sample sizes.
Across the three populations, we identified a higher level of anxiety and depressive symptoms if included studies were compared to prepandemic data published five or more years before versus a smaller burden in comparison to prepandemic data of less than 2 years ago.
The relationship of sample sizes explained the heterogeneity of the psychological impact of the SARS-CoV-2 pandemic in the general population and patients, with evidence for elevated symptoms of anxiety if similar sample sizes were compared.
The risk and protective factors narratively identified for each population are presented in Table 5 and eTables 14 and 15, with most of them being investigated in the general population, and few studies investigating protective factors at all. Most frequently named risk factors across the populations were pre-existing mental disorders, female sex, and concerns about COVID-19 infection, whereas most frequently reported protective factors were older age, good economic situation, and higher education.
Table 5
Risk and protective factors in three populations (mostly frequently reported factors)
 
Risk factorsa
Protective factorsb
General population
- Mental disorder/or symptoms [4449515258646974788283116132135]1)
- Worries about relatives or oneself [51576466747580898283]1 [48]1,2
- Being female [4952636669727479828393]1 [vs 1x being male]
- Previous (chronic) medical disease [525563646985135]1
- Being a student [52576072146]1
- Personal/social worries about COVID-19 [518586145]1 [48]1,2
- Physical symptoms [52668085132]1
- Reduced perceived health [50578085132]1
- No current relationship [578081146]1
- Current local outbreak severity [578893141]1
- History of stressful situations [525863147]1
- Vulnerability to COVID-19 [5385146]1
- Health profession [66, 81141]1
- Own or close person’s quarantine [576285]1
- Older age [49526365667991140147]1
- Good economic situation [527988140146]1 [48]1,2
- Satisfaction with/level of information on COVID-19 [454952858893]1
- Not being single [ 668088,86]1
- Higher education [505266146]1
- Social support [52, 140]1 [48]1,2
- Being male [546585]1
Healthcare workers
- Mental disorder/or symptoms [97115116119122]1
- Being female [98110119121]1
- Concern about infection with COVID-19 [103109120121]1
- Exposure to COVID-19 patients [94110115119]1
- Current local COVID-19 severity [94118141107]1
- Older age [98110]1
Patients
- (Suspected) COVID-19 [42131143]1
- Inflammatory markers in blood [42131]1
- Physical symptoms [132]1
- Higher education [127]1,3
- Good economic situation [127]1,3
- Higher lymphocyte ratio in blood [42]1
- Concomitant medical diseases [135]1
a most frequently reported risk factors: general population: factor was reported as statistically significant risk factor in at least k = 3 studies; healthcare workers: factor reported in at least k = 4 studies; patients: factor reported in at least k = 2 studies
b most frequently reported protective factors: general population: factor was reported as statistically significant protective factor in at least k = 3 studies; healthcare workers: factor reported in at least k = 2 studies (limited number of studies reporting protective factors in this group); patients: factor reported in k = 1 study (limited number of studies reporting protective factors in this group)

Discussion

To our knowledge, this is the first systematic review and meta-analysis to assess the mental health impact of the SARS-CoV-2 pandemic in the general population, healthcare workers, and patients, by contrasting data from the early phase of the current pandemic with prepandemic data. We identified 104 independent studies, mainly in the general population, that suggest an increased prevalence of mental burden due to the SARS-CoV-2 pandemic. This finding is in line with previous reviews and meta-analyses that merely pooled the prevalence of or calculated the risk for mental burden in either one or several of these groups [20, 24, 29, 32, 33, 36].
On the other hand, the pairwise meta-analyses for 43 studies across the four primary outcomes revealed different results. Compared with prepandemic data, we only found an elevated level of some mental symptoms (anxiety, depression) due to the SARS-CoV-2 pandemic in the general population, but not of stress or sleeping problems.
Although healthcare workers were found to be a group at risk for mental health problems during the SARS-CoV-2 pandemic [18]1,2 [20, 29, 31, 32], we identified no evidence for an increased mental burden during the early phase when comparing them with healthcare staff prior to the pandemic. Because of a (chronic) work-related risk exposure in daily life [194], as a kind of ‘stress inoculation’, healthcare professionals might have learned effective strategies (eg, self-efficacy) helping them to cope more professionally with crises than other groups. In contrast to previous findings [20, 195], the level of COVID-19 patient contact did not affect the mental health impact.
Overall, the results of this review paint a more nuanced picture of the mental health consequences of the SARS-CoV-2 pandemic than previous reviews – an observation in line with stress resilience research that identified different trajectories of psychological adaptation after potentially traumatic events, ranging from no mental burden to severe mental illness [196, 197]. Indeed, a recent analysis of 523 healthy subjects from the German LORA study showed a decrease of perceived stress and stressor load while mental health improved during the eight-week measurement after lockdown, indicating that the pandemic and pandemic response may also have positive effects [198]. The number of studies reporting on protective factors in this review was rather limited, especially in healthcare workers and patients. However, these factors might also partly explain the heterogeneity of findings regarding mental health consequences. This is in line with positive aspects (eg, improved social relationships with close social contacts such as families) that were likewise reported for previous infectious disease outbreaks. The importance of taking a ‘resilience perspective’ in SARS-CoV-2 mental health research and investigating resilience factors has been pointed out previously [19, 22, 197, 199].
Several aspects must be considered when interpreting the results. First, the absence of evidence of effects in healthcare workers and patients in this review does not necessarily mean that there is evidence for the absence of effects of the SARS-CoV-2 pandemic on mental health in these groups. Second, for healthcare workers, the mental burden on individuals probably depends on the location of survey (eg, country, region) and how heavily the respective healthcare systems were burdened in the pandemic timeline (eg, number of hospitalized COVID-19 patients). Among the 13 included studies in meta-analyses for healthcare staff, we could only include a few studies from heavily burdened countries (eg, Italy: k = 2; Spain: k = 0; USA: k = 0). However, nine studies in these meta-analyses had been conducted in China, which, compared internationally, was less affected by the SARS-CoV-2 pandemic [4]. In the subgroup analysis regarding the level of COVID-19 patient contact, we assigned studies to the subgroup ‘high level of contact’ if at least 50% of the sample had close contact to COVID-19 patients (ie, ‘frontline healthcare workers’). However, the nature of contact was insufficiently described in the included studies.
Strengths of this review compared with previous publications include the systematic search for comparative prepandemic data for inclusion in pairwise meta-analyses, the stepwise selection of prepandemic studies to ensure best available comparability, and the population-specific analysis of risk and protective factors. One limitation refers to the search methods for pandemic studies (eg, no preprints; no reference lists of reviews) and comparative data (eg, subgroups in general population only partially searched). We had no restrictions regarding the publication format except for the exclusion of preprints which might be viewed as limitation. This restriction might have affected the evidence found in this review compared to others (eg, Cochrane reviews) where preprint articles are included.
The large between-study heterogeneity, a problem shared by previous meta-analyses [20, 24, 32, 33], could not be fully explained by subgroup analyses. This heterogeneity probably resulted from differences between the pandemic studies (eg, countries, sociocultural differences in the perception of mental burden, pandemic outbreak severity, subpopulations, outcome measures) and variability between the comparative studies (eg, study design, outcome measures), respectively. Among the pandemic studies, especially the specific outcome measures used were an important source of heterogeneity. Furthermore, the pandemic and comparative data were heterogeneous (eg, country, population), which could be partially captured by our self-developed tool for the level of comparability and was controlled for by the corresponding sensitivity analysis. We cannot preclude that moderators of effects are present that we, though our best efforts, did not identify and therefore could not control for. Besides, comparative studies with larger sample sizes were preferred, leading to small 95% CIs and a lack of CI overlap with pandemic study findings. Despite the comprehensiveness of this review compared to previous publications, the small number of studies in certain subgroups potentially limited the statistical power (eg, surveys including students).
Apart from specific outcome measures, less recent comparative data, and homogenous sample sizes, the subgroup analyses indicated no consistent determinants of heterogeneity. An elevated level of depression based on the assessment with the PHQ and SDS might – at least for the PHQ-9 – be explained by the high sensitivity to change of this instrument and its usefulness to monitor treatment outcomes [200, 201]. Given the increased mental burden if pandemic studies were compared to older prepandemic data, cohort effects cannot be excluded.
Discrepancies between subgroup analyses and the narrative synthesis of risk and protective factors (eg, COVID-19 patient contact) might be due to methodological differences. Because of the primary use of screening but not diagnostic tools to determine mental burden in the included pandemic studies, this review does not allow any conclusions concerning a putative increase of diagnoses of mental disorders during the early phase of the SARS-CoV-2 pandemic. Consistent with the synthesis of risk factors, the meta-analyses partly showed an increased level of mental symptoms in young and middle-aged groups, in line with previous studies [12]. However, more studies including elderly would be needed to clearly investigate age differences, and whether the pandemic works as a ‘burning lens’ for the already increased mental burden in young people [202]. Finally, given the pandemic timeline, the evidence is substantially based on Chinese studies thus potentially limiting the transferability of findings to other contexts.
Further research in other countries (eg, USA), that started later on during the pandemic, could change the findings. The latter is also supported by the wide prediction intervals identified in this review, which indicate uncertainty in our conclusions about whether the pandemic and related stressors do affect mental health [203].
The review has several implications for research and practice. There is an urgent need for representative surveys, in order to allow fair comparisons between the mental burden caused by SARS-CoV-2 in different countries and to examine other risk and protective factors (eg, cultural context). Representative surveys in the general population might also serve to identify specific subgroups at risk for which further studies would be needed. From a public mental health perspective, a stronger focus on (psychosocial) protective factors for mental health would be desirable to derive appropriate contents for preventive measures (eg, pandemic preparedness plans) or health-promoting interventions (eg, resilience training) prior to, during, and after a pandemic [199]. By further investigating the mental health impact of specific stressors – in line with Brooks and colleagues [13] – researchers and practitioners might gain further knowledge about when (eg, in pandemic timeline) and for whom (eg, after exposure to which stressors) interventions should be implemented to buffer negative mental health effects of SARS-CoV-2.

Conclusions

In conclusion, compared with prepandemic data, this review shows different adverse mental health consequences of the early phase of the SARS-CoV-2 pandemic in the examined population groups in contrast to previous research, with healthcare workers being more resilient than expected. The quality of studies varies. High-quality, representative surveys in the general population and specific subpopulations, longitudinal studies, and further research efforts on protective factors are needed to better understand the psychological impacts of the SARS-CoV-2 pandemic and to help design effective preventive measures and interventions that are tailored to the needs of specific population groups.

Acknowledgements

We appreciate the contributions of Prof Raffael Kalisch PhD to the discussion of the findings of our review.
Not applicable.
Not applicable.

Competing interests

LG, JSW, and GS have no conflicts of interest to disclose. AMK, NR, OT, MC, ER, HB, CS, JJM, and KL report grants from the Federal Ministry of Education and Research (BMBF), Germany, during the conduct of the study. JJM reports grants from the Federal Ministry of Health (BMG), Germany, outside of the submitted work.
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Supplementary Information

Fußnoten
1
included pandemic studies.
 
2
studies already considered in previous systematic review (Gilan, Röthke and colleagues) [19].
 
3
prepandemic comparative studies.
 
Literatur
1.
Lu R, Zhao X, Li J, et al. Genomic characterisation and epidemiology of 2019 novel coronavirus: implications for virus origins and receptor binding. Lancet. 2020;395(10224):565–74.PubMedPubMedCentralCrossRef
2.
3.
Sohrabi C, Alsafi Z, O’Neill N, et al. World Health Organization declares global emergency: a review of the 2019 novel coronavirus (COVID-19). Int J Surg. 2020;76:71–6.PubMedPubMedCentralCrossRef
4.
5.
6.
7.
White House. The President’s coronavirus guidelines for America. 2020. Accessed 30 June 2020.
8.
9.
Phua J, Weng L, Ling L, et al. Intensive care management of coronavirus disease 2019 (COVID-19): challenges and recommendations. Lancet Respir Med. 2020;8(5):506–17.PubMedPubMedCentralCrossRef
10.
Pak A, Adegboye OA, Adekunle AI, Rahman KM, McBryde ES, Eisen DP. Economic consequences of the COVID-19 outbreak: the need for epidemic preparedness. Front Public Health. 2020;8:241.PubMedPubMedCentralCrossRef
11.
Nicola M, Alsafi Z, Sohrabi C, et al. The socio-economic implications of the coronavirus pandemic (COVID-19): a review. Int J Surg. 2020;78:185–93.PubMedPubMedCentralCrossRef
12.
Pierce M, Hope H, Ford T, et al. Mental health before and during the COVID-19 pandemic: a longitudinal probability sample survey of the UK population. Lancet Psychiatry. 2020;7(10):883–92.PubMedPubMedCentralCrossRef
13.
Brooks SK, Webster RK, Smith LE, et al. The psychological impact of quarantine and how to reduce it: rapid review of the evidence. Lancet. 2020;395(10227):912–20.PubMedPubMedCentralCrossRef
14.
Pfefferbaum B, North CS. Mental health and the Covid-19 pandemic. N Engl J Med. 2020;383(6):510–2.PubMedCrossRef
15.
Holmes EA, O'Connor RC, Perry VH, et al. Multidisciplinary research priorities for the COVID-19 pandemic: a call for action for mental health science. Lancet Psychiatry. 2020;7(6):547–60.PubMedPubMedCentralCrossRef
16.
17.
18.
Lai J, Ma S, Wang Y, et al. Factors associated with mental health outcomes among health care workers exposed to Coronavirus Disease. JAMA Netw Open. 2020;3:e203976.PubMedPubMedCentralCrossRef
19.
Gilan D, Röthke N, Blessin M, et al. Psychomorbidity, resilience, and exacerbating and protective factors during the SARS-CoV-2-pandemic. A systematic literature review and results from the German COSMO-PANEL. Dtsch Arztebl Int. 2020;117(38):625–32.PubMedPubMedCentral
20.
Kisely S, Warren N, McMahon L, Dalais C, Henry I, Siskind D. Occurrence, prevention, and management of the psychological effects of emerging virus outbreaks on healthcare workers: rapid review and meta-analysis. BMJ. 2020;369:m1642.PubMedPubMedCentralCrossRef
21.
Robertson E, Hershenfield K, Grace SL, Stewart DE. The psychosocial effects of being quarantined following exposure to SARS: a qualitative study of Toronto health care workers. Can J Psychiatr. 2004;49(6):403–7.CrossRef
22.
23.
24.
Rogers JP, Chesney E, Oliver D, et al. Psychiatric and neuropsychiatric presentations associated with severe coronavirus infections: a systematic review and meta-analysis with comparison to the COVID-19 pandemic. Lancet Psychiatry. 2020;7(7):611–27.PubMedPubMedCentralCrossRef
25.
Chan E, Gobat N, Kim JH, et al. Informal home care providers: the forgotten health-care workers during the COVID-19 pandemic. Lancet. 2020;395(10242):1957–9.PubMedPubMedCentralCrossRef
26.
27.
28.
29.
da Silva FCT, Neto MLR. Psychological effects caused by the COVID-19 pandemic in health professionals: a systematic review with meta-analysis. Prog Neuro-Psychopharmacol Biol Psychiatry. 2020;104:110062.CrossRef
30.
Xiong J, Lipsitz O, Nasri F, et al. Impact of COVID-19 pandemic on mental health in the general population: a systematic review. J Affect Disord. 2020;277:55–64.PubMedPubMedCentralCrossRef
31.
Vindegaard N, Benros ME. COVID-19 pandemic and mental health consequences: systematic review of the current evidence. Brain Behav Immun. 2020;S0889–1591(20):30954–5.
32.
Krishnamoorthy Y, Nagarajan R, Saya GK, Menon V. Prevalence of psychological morbidities among general population, healthcare workers and COVID-19 patients amidst the COVID-19 pandemic: a systematic review and meta-analysis. Psychiatry Res. 2020;293:113382.PubMedPubMedCentralCrossRef
33.
Luo M, Guo L, Yu M, Jiang W, Wang H. The psychological and mental impact of coronavirus disease 2019 (COVID-19) on medical staff and general public - a systematic review and meta-analysis. Psychiatry Res. 2020;291:113190.PubMedPubMedCentralCrossRef
34.
Preti E, Di Mattei V, Perego G, et al. The psychological impact of epidemic and pandemic outbreaks on healthcare workers: rapid review of the evidence. Curr Psychiatry Reports. 2020;22(8):43.CrossRef
35.
Cénat JM, Felix N, Blais-Rochette C, et al. Prevalence of mental health problems in populations affected by the Ebola virus disease: a systematic review and meta-analysis. Psychiatry Res. 2020;289:113033.PubMedCrossRef
36.
Salari N, Hosseinian-Far A, Jalali R, et al. Prevalence of stress, anxiety, depression among the general population during the COVID-19 pandemic: a systematic review and meta-analysis. Global Health. 2020;16(1):57.PubMedPubMedCentralCrossRef
37.
Moher D, Liberati A, Tetzlaff J, Altman DG. Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. BMJ. 2009;339:b2535.PubMedPubMedCentralCrossRef
38.
39.
Van den Noortgate W, López-López JA, Marín-Martínez F, Sánchez-Meca J. Three-level meta-analysis of dependent effect sizes. Behav Res. 2013;45(2):576–94.CrossRef
40.
Higgins JPT, Thompson SG, Spiegelhalter DJ. A re-evaluation of random-effects meta-analysis. J R Stat Soc Ser A (Statistics in Society). 2009;172(1):137–59.CrossRef
41.
Qiu J, Shen B, Zhao M, Wang Z, Xie B, Xu Y. A nationwide survey of psychological distress among Chinese people in the COVID-19 epidemic: implications and policy recommendations. Gen Psychiatr. 2020;33(2):e100213.PubMedPubMedCentralCrossRef
42.
Liu X, Lin H, Jiang H, et al. Clinical characteristics of hospitalised patients with schizophrenia who were suspected to have coronavirus disease (COVID-19) in Hubei Province, China. Gen Psychiatr. 2020;33(2):e100222.PubMedPubMedCentralCrossRef
43.
Ahmad AR, Murad HR. The impact of social media on panic during the COVID-19 pandemic in Iraqi Kurdistan: online questionnaire study. J Med Internet Res. 2020;22(5):e19556.PubMedPubMedCentralCrossRef
44.
Bacon AM, Corr PJ. Coronavirus (COVID-19) in the United Kingdom: a personality-based perspective on concerns and intention to self-isolate. Br J Health Psychol. 2020;25(4):839–48.PubMedCrossRef
45.
Bäuerle A, Teufel M, Musche V, et al. Increased generalized anxiety, depression and distress during the COVID-19 pandemic: a cross-sectional study in Germany. J Public Health (Oxf). 2020;42(4):672–78.
46.
Teufel M, Schweda A, Dörrie N, et al. Not all world leaders use twitter in response to the COVID-19 pandemic: impact of the way of Angela Merkel on psychological distress, behaviour and risk perception. J Public Health. 2020;42(3):644–6.CrossRef
47.
Buzzi C, Tucci M, Ciprandi R, et al. The psycho-social effects of COVID-19 on Italian adolescents' attitudes and behaviors. Ital J Pediatr. 2020;46(1):69.PubMedPubMedCentralCrossRef
48.
49.
Chang J, Yuan Y, Wang D. Mental health status and its influencing factors among college students during the epidemic of COVID-19. Nan Fang Yi Ke Da Xue Xue Bao. 2020;40(2):171–6.PubMed
50.
51.
Germani A, Buratta L, Delvecchio E, Mazzeschi C. Emerging adults and COVID-19: the role of individualism-collectivism on perceived risks and psychological maladjustment. Int J Environ Res Public Health. 2020;17(10):3497.PubMedCentralCrossRef
52.
González-Sanguino C, Ausín B, Castellanos MÁ, et al. Mental health consequences during the initial stage of the 2020 coronavirus pandemic (COVID-19) in Spain. Brain Behav Immun. 2020;87:172–6.PubMedPubMedCentralCrossRef
53.
54.
Jahanshahi AA, Dinani MM, Madavani AN, Li J, Zhang SX. The distress of Iranian adults during the Covid-19 pandemic - more distressed than the Chinese and with different predictors. Brain Behav Immun. 2020;87:124–5.PubMedPubMedCentralCrossRef
55.
56.
Lee SA, Mathis AA, Jobe MC, Pappalardo EA. Clinically significant fear and anxiety of COVID-19: a psychometric examination of the coronavirus anxiety scale. Psychiatry Res. 2020;290:113112.PubMedPubMedCentralCrossRef
57.
Lei L, Huang X, Zhang S, Yang J, Yang L, Xu M. Comparison of prevalence and associated factors of anxiety and depression among people affected by versus people unaffected by quarantine during the COVID-19 epidemic in southwestern China. Med Sci Monit. 2020;26:e924609.PubMedPubMedCentral
58.
59.
Liu N, Zhang F, Wei C, et al. Prevalence and predictors of PTSS during COVID-19 outbreak in China hardest-hit areas: Gender differences matter. Psychiatry Res. 2020;287:112921.PubMedPubMedCentralCrossRef
60.
Liu S, Liu Y, Liu Y. Somatic symptoms and concern regarding COVID-19 among Chinese college and primary school students: a cross-sectional survey. Psychiatry Res. 2020;289:113070.PubMedPubMedCentralCrossRef
61.
López J, Perez-Rojo G, Noriega C, et al. Psychological well-being among older adults during the COVID-19 outbreak: a comparative study of the young-old and the old-old adults. Int Psychogeriatr. 2020;32(11):1365–70.
62.
Ma K, Zhang Y, Hou T, Wu M, Cai W, Wen T. Investigation of physical and mental health in isolated people during the outbreak of novel coronavirus pneumonia. Chin J Clin Med. 2020;27(1):36–40.
63.
Mazza C, Ricci E, Biondi S, et al. A nationwide survey of psychological distress among Italian Ppople during the COVID-19 pandemic: immediate psychological responses and associated factors. Int J Environ Res Public Health. 2020;17(9):3165.
64.
McKay D, Yang H, Elhai J, Asmundson GJG. Anxiety regarding contracting COVID-19 related to interoceptive anxiety sensations: the moderating role of disgust propensity and sensitivity. J Anxiety Disord. 2020;73:102233.PubMedPubMedCentralCrossRef
65.
Moccia L, Janiri D, Pepe M, et al. Affective temperament, attachment style, and the psychological impact of the COVID-19 outbreak: an early report on the Italian general population. Brain Behav Immun. 2020;87:75–9.PubMedPubMedCentralCrossRef
66.
Odriozola-González P, Planchuelo-Gómez Á, Irurtia MJ, de Luis-García R. Psychological effects of the COVID-19 outbreak and lockdown among students and workers of a Spanish university. Psychiatry Res. 2020;290:113108.PubMedPubMedCentralCrossRef
67.
Sanchez TH, Zlotorzynska M, Rai M, Baral SD. Characterizing the impact of COVID-19 on men who have sex with men across the United States in April, 2020. AIDS Behav. 2020;24(7):2024–32.PubMedCrossRef
68.
Ozamiz-Etxebarria N, Dosil-Santamaria M, Picaza-Gorrochategui M, Idoiaga-Mondragon N. Niveles de estrés, ansiedad y depresión en la primera fase del brote del COVID-19 en una muestra recogida en el norte de España [stress, anxiety, and depression levels in the initial stage of the COVID-19 outbreak in a population sample in the northern Spain]. Cad Saude Publica. 2020;36(4):e00054020.PubMedCrossRef
69.
Özdin S, Bayrak ÖŞ. Levels and predictors of anxiety, depression and health anxiety during COVID-19 pandemic in Turkish society: the importance of gender. Int J Soc Psychiatry. 2020;66(5):504–11.PubMedPubMedCentralCrossRef
70.
Pérez-Fuentes MDC, Molero Jurado MDM, Oropesa Ruiz NF, et al. Questionnaire on perception of threat from COVID-19. J Clin Med. 2020;9(4):1196.PubMedCentralCrossRef
71.
Ren Y, Zhou Y, Qian W, et al. Letter to the editor "a longitudinal study on the mental health of general population during the COVID-19 epidemic in China". Brain Behav Immun. 2020;87:132–3.PubMedPubMedCentralCrossRef
72.
73.
Roy D, Tripathy S, Kar SK, Sharma N, Verma SK, Kaushal V. Study of knowledge, attitude, anxiety & perceived mental healthcare need in Indian population during COVID-19 pandemic. Asian J Psychiatr. 2020;51:102083.PubMedPubMedCentralCrossRef
74.
Sakib N, Bhuiyan AKMI, Hossain S, et al. Psychometric validation of the Bangla fear of COVID-19 scale: confirmatory factor analysis and Rasch analysis [published online ahead of print, 2020 May 11]. Int J Ment Heal Addict. 2020:1–12. https://​doi.​org/​10.​1007/​s11469-020-00289-x.
75.
Satici B, Gocet-Tekin E, Deniz ME, Satici SA. Adaptation of the fear of COVID-19 scale: its association with psychological distress and life satisfaction in Turkey [published online ahead of print, 2020 May 8]. Int J Ment Heal Addict. 2020:1–9. https://​doi.​org/​10.​1007/​s11469-020-00294-0.
76.
Shammi M, Bodrud-Doza M, Towfiqul Islam ARM, Rahman MM. COVID-19 pandemic, socioeconomic crisis and human stress in resource-limited settings: a case from Bangladesh. Heliyon. 2020;6(5):e04063.PubMedPubMedCentralCrossRef
77.
Shevlin M, Nolan E, Owczarek M, et al. COVID-19-related anxiety predicts somatic symptoms in the UK population. Br J Health Psychol. 2020;25(4):875–82.PubMedCrossRef
78.
79.
Tull MT, Edmonds KA, Scamaldo KM, Richmond JR, Rose JP, Gratz KL. Psychological outcomes associated with stay-at-home orders and the perceived impact of COVID-19 on daily life. Psychiatry Res. 2020;289:113098.PubMedPubMedCentralCrossRef
80.
Tan W, Hao F, McIntyre RS, et al. Is returning to work during the COVID-19 pandemic stressful? A study on immediate mental health status and psychoneuroimmunity prevention measures of Chinese workforce. Brain Behav Immun. 2020;87:84–92.PubMedPubMedCentralCrossRef
81.
Tian F, Li H, Tian S, Yang J, Shao J, Tian C. Psychological symptoms of ordinary Chinese citizens based on SCL-90 during the level I emergency response to COVID-19. Psychiatry Res. 2020;288:112992.PubMedPubMedCentralCrossRef
82.
83.
84.
Wang C, Pan R, Wan X, et al. Immediate psychological responses and associated factors during the initial stage of the 2019 Coronavirus disease (COVID-19) epidemic among the general population in China. Int J Environ Res Public Health. 2020;17(5):1729.PubMedCentralCrossRef
85.
Wang C, Pan R, Wan X, et al. A longitudinal study on the mental health of general population during the COVID-19 epidemic in China. Brain Behav Immun. 2020;87:40–8.PubMedPubMedCentralCrossRef
86.
Wang H, Xia Q, Xiong Z, et al. The psychological distress and coping styles in the early stages of the 2019 coronavirus disease (COVID-19) epidemic in the general mainland Chinese population: a web-based survey. PLoS One. 2020;15(5):e0233410.PubMedPubMedCentralCrossRef
87.
Wang Y, Di Y, Ye J, Wei W. Study on the public psychological states and its related factors during the outbreak of coronavirus disease 2019 (COVID-19) in some regions of China. Psychol Health Med. 2021;26(1):13–22.
88.
Yang H, Ma J. How an epidemic outbreak impacts happiness: factors that worsen (vs. protect) emotional well-being during the coronavirus pandemic. Psychiatry Res. 2020;289:113045.PubMedPubMedCentralCrossRef
89.
Yuan R, Xu Q-H, Xia C-C, et al. Psychological status of parents of hospitalized children during the COVID-19 epidemic in China. Psychiatry Res. 2020;288:112953.PubMedPubMedCentralCrossRef
90.
Zhang SX, Huang H, Wei F. Geographical distance to the epicenter of Covid-19 predicts the burnout of the working population: ripple effect or typhoon eye effect? Psychiatry Res. 2020;288:112998.PubMedPubMedCentralCrossRef
91.
Zhang SX, Wang Y, Rauch A, Wei F. Unprecedented disruption of lives and work: health, distress and life satisfaction of working adults in China one month into the COVID-19 outbreak. Psychiatry Res. 2020;288:112958.PubMedPubMedCentralCrossRef
92.
Zhang Y, Ma ZF. Impact of the COVID-19 pandemic on mental health and quality of life among local residents in Liaoning Province, China: a cross-sectional study. Int J Environ Res Public Health. 2020;17(7):2381.PubMedCentralCrossRef
93.
Zhou SJ, Zhang LG, Wang LL, et al. Prevalence and socio-demographic correlates of psychological health problems in Chinese adolescents during the outbreak of COVID-19. Eur Child Adolesc Psychiatry. 2020;29(6):749–58.PubMedCrossRef
94.
Abdessater M, Rouprêt M, Misrai V, et al. COVID19 pandemic impacts on anxiety of French urologist in training: outcomes from a national survey. Prog Urol. 2020;30(8–9):448–55.PubMedPubMedCentralCrossRef
95.
Ahmed MA, Jouhar R, Ahmed N, et al. Fear and practice modifications among dentists to combat novel coronavirus disease (COVID-19) outbreak. Int J Environ Res Public Health. 2020;17(8):2821.PubMedCentralCrossRef
96.
Alhaj AK, Al-Saadi T, Mohammad F, Alabri S. Neurosurgery residents' perspective on COVID-19: knowledge, readiness, and impact of this pandemic. World Neurosurg. 2020;139:e848–58.PubMedPubMedCentralCrossRef
97.
Amerio A, Bianchi D, Santi F, et al. Covid-19 pandemic impact on mental health: a web-based cross-sectional survey on a sample of Italian general practitioners. Acta Biomed. 2020;91(2):83–8.PubMedPubMedCentral
98.
Badahdah AM, Khamis F, Mahyijari NA. The psychological well-being of physicians during COVID-19 outbreak in Oman. Psychiatry Res. 2020;289:113053.PubMedPubMedCentralCrossRef
99.
Bohlken J, Schömig F, Seehagen T, et al. Erfahrungen und Belastungserleben niedergelassener Neurologen und Psychiater während der COVID-19-Pandemie [experience of practice-based psychiatrists and neurologists during the COVID-19 pandemic]. Psychiatr Prax. 2020;47(4):214–7.PubMedCrossRef
100.
Cai H, Tu B, Ma J, et al. Psychological impact and coping strategies of frontline medical staff in hunan between January and March 2020 during the outbreak of coronavirus disease 2019 (COVID-19) in Hubei, China. Med Sci Monit. 2020;26:e924171.PubMedPubMedCentral
101.
Cai W, Lian B, Song X, Hou T, Deng G, Li H. A cross-sectional study on mental health among health care workers during the outbreak of Corona virus disease 2019. Asian J Psychiatr. 2020;51:102111.PubMedPubMedCentralCrossRef
102.
Chew NWS, Lee GKH, Tan BYQ, et al. A multinational, multicentre study on the psychological outcomes and associated physical symptoms amongst healthcare workers during COVID-19 outbreak. Brain Behav Immun. 2020;88:559–65.PubMedPubMedCentralCrossRef
103.
Consolo U, Bellini P, Bencivenni D, Iani C, Checchi V. Epidemiological aspects and psychological reactions to COVID-19 of dental practitioners in the northern Italy districts of Modena and Reggio Emilia. Int J Environ Res Public Health. 2020;17(10):3459.PubMedCentralCrossRef
104.
Gan X, Shi Z, Chair SY, Cao X, Wang Q. Willingness of Chinese nurses to practice in Hubei combating the coronavirus disease 2019 epidemic: a cross-sectional study. J Adv Nurs. 2020;76(8):2137–50.
105.
Huang JZ, Han MF, Luo TD, Ren AK, Zhou XP. Mental health survey of medical staff in a tertiary infectious disease hospital for COVID-19. Zhonghua Lao Dong Wei Sheng Zhi Ye Bing Za Zhi. 2020;38(3):192–5.PubMed
106.
Kang L, Ma S, Chen M, et al. Impact on mental health and perceptions of psychological care among medical and nursing staff in Wuhan during the 2019 novel coronavirus disease outbreak: a cross-sectional study. Brain Behav Immun. 2020;87:11–7.PubMedPubMedCentralCrossRef
107.
Khusid JA, Weinstein CS, Becerra AZ, et al. Well-being and education of urology residents during the COVID-19 pandemic: results of an American National Survey. Int J Clin Pract. 2020;74(9):e13559.PubMedCrossRef
108.
Mo Y, Deng L, Zhang L, et al. Work stress among Chinese nurses to support Wuhan in fighting against COVID-19 epidemic. J Nurs Manag. 2020;28(5):1002–9.PubMedCrossRef
109.
Pu J, Li G, Cao L, Wu Y, Xu L. Investigation and analysis of the psychological status of the clinical nurses in a class. A hospital facing the novel coronavirus pneumonia. Chongqing Med. 2020;36:E015.
110.
Rossi R, Socci V, Pacitti F, et al. Mental health outcomes among frontline and second-line health care workers during the coronavirus disease 2019 (COVID-19) pandemic in Italy. JAMA Netw Open. 2020;3(5):e2010185.PubMedPubMedCentralCrossRef
111.
Sahu D, Agrawal T, Rathod V, Bagaria V. Impact of COVID 19 lockdown on orthopaedic surgeons in India: a survey. J Clin Orthop Trauma. 2020;11(Suppl 3):S283–90.PubMedPubMedCentralCrossRef
112.
Shacham M, Hamama-Raz Y, Kolerman R, Mijiritsky O, Ben-Ezra M, Mijiritsky E. COVID-19 factors and psychological factors associated with elevated psychological distress among dentists and dental hygienists in Israel. Int J Environ Res Public Health. 2020;17(8):2900.PubMedCentralCrossRef
113.
Suleiman A, Bsisu I, Guzu H, et al. Preparedness of frontline doctors in Jordan healthcare facilities to COVID-19 outbreak. Int J Environ Res Public Health. 2020;17(9):3181.PubMedCentralCrossRef
114.
Tan BYQ, Chew NWS, Lee GKH, et al. Psychological impact of the COVID-19 pandemic on health care workers in Singapore. Ann Intern Med. 2020;173(4):317–20.PubMedCrossRef
115.
Wang S, Xie L, Xu Y, Yu S, Yao B, Xiang D. Sleep disturbances among medical workers during the outbreak of COVID-2019. Occup Med. 2020;70(5):364–9.CrossRef
116.
Wu K, Wei X. Analysis of psychological and sleep status and exercise rehabilitation of front-line clinical staff in the fight against COVID-19 in China. Med Sci Monit Basic Res. 2020;26:e924085.PubMedPubMedCentralCrossRef
117.
Xiao H, Zhang Y, Kong D, Li S, Yang N. The effects of social support on sleep quality of medical staff treating patients with coronavirus disease 2019 (COVID-19) in January and February 2020 in China. Med Sci Monit. 2020;26:e923549.PubMedPubMedCentral
118.
119.
Yin Q, Sun Z, Liu T, et al. Posttraumatic stress symptoms of health care workers during the corona virus disease 2019. Clin Psychol Psychother. 2020;27(3):384–95.PubMedCrossRef
120.
Zhang C, Yang L, Liu S, et al. Survey of insomnia and related social psychological factors among medical staff involved in the 2019 novel coronavirus disease outbreak. Front Psychiatry. 2020;11:306.PubMedPubMedCentralCrossRef
121.
Zhang SX, Liu J, Afshar Jahanshahi A, et al. At the height of the storm: healthcare staff's health conditions and job satisfaction and their associated predictors during the epidemic peak of COVID-19. Brain Behav Immun. 2020;87:144–6.PubMedPubMedCentralCrossRef
122.
Zhu J, Sun L, Zhang L, et al. Prevalence and influencing factors of anxiety and depression symptoms in the first-line medical staff fighting against COVID-19 in Gansu. Front Psychiatry. 2020;11:386.PubMedPubMedCentralCrossRef
123.
Cai X, Hu X, Ekumi IO, et al. Psychological distress and its correlates among COVID-19 survivors during early convalescence across age groups. Am J Geriatr Psychiatry. 2020;28(10):1030–9.PubMedPubMedCentralCrossRef
124.
Yuan B, Li W, Liu H, et al. Correlation between immune response and self-reported depression during convalescence from COVID-19. Brain Behav Immun. 2020;88:39–43.PubMedPubMedCentralCrossRef
125.
126.
Li X, Dai T, Wang H, et al. Clinical analysis of suspected COVID-19 patients with anxiety and depression. Zhejiang Da Xue Xue Bao Yi Xue Ban. 2020;49(2):203–8.PubMedPubMedCentral
127.
Wu Y, Zhang C, Liu H, et al. Perinatal depressive and anxiety symptoms of pregnant women during the coronavirus disease 2019 outbreak in China. Am J Obstet Gynecol. 2020;223(2):240.e1–9.CrossRef
128.
Xu H, Yang K, Yang G, et al. Explore the optimal resolvent of medical needs and mental health for patients with lung cancer during epidemic novel coronavirus pneumonia. Zhongguo Fei Ai Za Zhi. 2020;23(4):247–54.PubMed
129.
Yassa M, Birol P, Yirmibes C, et al. Near-term pregnant women's attitude toward, concern about and knowledge of the COVID-19 pandemic. J Matern Fetal Neonatal Med. 2020;33(22):3827–34.
130.
Büntzel J, Klein M, Keinki C, Walter S, Büntzel J, Hübner J. Oncology services in corona times: a flash interview among German cancer patients and their physicians. J Cancer Res Clin Oncol. 2020;146(10):2713–5.PubMedCrossRefPubMedCentral
131.
Guo Q, Zheng Y, Shi J, et al. Immediate psychological distress in quarantined patients with COVID-19 and its association with peripheral inflammation: a mixed-method study. Brain Behav Immun. 2020;88:17–27.PubMedPubMedCentralCrossRef
132.
Hao F, Tan W, Jiang L, et al. Do psychiatric patients experience more psychiatric symptoms during COVID-19 pandemic and lockdown? A case-control study with service and research implications for immunopsychiatry. Brain Behav Immun. 2020;87:100–6.PubMedPubMedCentralCrossRef
133.
Hao X, Zhou D, Li Z, et al. Severe psychological distress among patients with epilepsy during the COVID-19 outbreak in Southwest China. Epilepsia. 2020;61(6):11661173.CrossRef
134.
Huang Y, Zhao N. Mental health burden for the public affected by the COVID-19 outbreak in China: Who will be the high-risk group? [retracted in: Psychol Health Med. 2020 Oct 23;:1]. Psychol Health Med. 2021;26(1):23–34.
135.
Iasevoli F, Fornaro M, D'Urso G, et al. Psychological distress in patients with serious mental illness during the COVID-19 outbreak and one-month mass quarantine in Italy [published online ahead of print, 2020 May 19]. Psychol Med. 2020;1-3. https://​doi.​org/​10.​1017/​S003329172000184​1.
136.
Jin YH, Huang Q, Wang YY, et al. Perceived infection transmission routes, infection control practices, psychosocial changes, and management of COVID-19 infected healthcare workers in a tertiary acute care hospital in Wuhan: a cross-sectional survey. Mil Med Res. 2020;7(1):24.PubMedPubMedCentral
137.
Ko N-Y, Lu W-H, Chen Y-L, et al. COVID-19-related information sources and psychological well-being: an online survey study in Taiwan. Brain Behav Immun. 2020;87:153–4.PubMedPubMedCentralCrossRef
138.
Li Z, Ge J, Yang M, et al. Vicarious traumatization in the general public, members, and non-members of medical teams aiding in COVID-19 control. Brain Behav Immun. 2020;88:916–9.PubMedPubMedCentralCrossRef
139.
Lu W, Wang H, Lin Y, Li L. Psychological status of medical workforce during the COVID-19 pandemic: a cross-sectional study. Psychiatry Res. 2020;288:112936.PubMedPubMedCentralCrossRef
140.
Ni MY, Yang L, Leung CMC, et al. Mental health, risk factors, and social media use during the COVID-19 epidemic and cordon sanitaire among the community and health professionals in Wuhan, China: cross-sectional survey. JMIR Mental Health. 2020;7(5):e19009.PubMedPubMedCentralCrossRef
141.
142.
Yuan S, Liao Z, Huang H, et al. Comparison of the indicators of psychological stress in the population of Hubei province and non-endemic provinces in China during two weeks during the coronavirus disease 2019 (COVID-19) outbreak in February 2020. Med Sci Monit. 2020;26:e923767.PubMedPubMedCentral
143.
Zhang J, Lu H, Zeng H, et al. The differential psychological distress of populations affected by the COVID-19 pandemic. Brain Behav Immun. 2020;87:49–50.PubMedPubMedCentralCrossRef
144.
Zhang WR, Wang K, Yin L, et al. Mental health and psychosocial problems of medical health workers during the COVID-19 epidemic in China. Psychother Psychosom. 2020;89(4):242–50.PubMedCrossRef
145.
Zhu S, Wu Y, Zhu C-Y, et al. The immediate mental health impacts of the COVID-19 pandemic among people with or without quarantine managements. Brain Behav Immun. 2020;87:56–8.PubMedPubMedCentralCrossRef
146.
Olagoke AA, Olagoke OO, Hughes AM. Exposure to coronavirus news on mainstream media: the role of risk perceptions and depression. Br J Health Psychol. 2020;25(4):865–74.PubMedCrossRef
147.
Sutin AR, Robinson E, Daly M, et al. BMI, Weight discrimination, and psychological, behavioral, and interpersonal responses to the coronavirus pandemic. Obesity (Silver Spring, Md). 2020;28(9):1590–4.CrossRef
148.
Alosaimi FD, Alawad HS, Alamri AK, et al. Patterns and determinants of stress among consultant physicians working in Saudi Arabia. Adv Med Educ Pract. 2018;9:165–74.PubMedPubMedCentralCrossRef
149.
Balestrieri M, Isola M, Quartaroli M, Roncolato M, Bellantuono C. Assessing mixed anxiety-depressive disorder. A national primary care survey. Psychiatry Res. 2010;176(2–3):197–201.PubMedCrossRef
150.
Basta M, Karakonstantis S, Koutra K, et al. NEET status among young Greeks: association with mental health and substance use. J Affect Disord. 2019;253:210–7.PubMedCrossRef
151.
Bilgel N, Bayram N. Turkish version of the depression anxiety stress scale (DASS-42): psychometric properties. Nöropsikiyatri Arşivi. 2010;47(2):118–26.
152.
Bonfiglio NS, Renati R, Hjemdal O, Friborg O. The resilience scale for adults in Italy: a validation study comparing clinical substance abusers with a nonclinical sample. Psychol Addict Behav. 2016;30(4):509–15.PubMedCrossRef
153.
Bottesi G, Ghisi M, Altoè G, Conforti E, Melli G, Sica C. The Italian version of the Depression Anxiety Stress Scales-21: Factor structure and psychometric properties on community and clinical samples. Compr Psychiatry. 2015;60:170–81.PubMedCrossRef
154.
Cai S, Lin H, Hu X, Cai YX, Chen K, Cai WZ. High fatigue and its associations with health and work related factors among female medical personnel at 54 hospitals in Zhuhai, China. Psychol Health Med. 2017;23(3):304–16.PubMedCrossRef
155.
Carlucci L, Watkins MW, Sergi MR, Cataldi F, Saggino A, Balsamo M. Dimensions of anxiety, age, and gender: assessing dimensionality and measurement invariance of the State-Trait for Cognitive and Somatic Anxiety (STICSA) in an Italian sample. Front Psychol. 2018;9:2345.PubMedPubMedCentralCrossRef
156.
Carta MG, Angermeyer MC, Matschinger H, Holzinger A, Floris F, Moro MF. Perception of depressive symptoms by the Sardinian public: results of a population study. BMC Psychiatry. 2013;13:57.PubMedPubMedCentralCrossRef
157.
Choueiry N, Salamoun T, Jabbour H, El Osta N, Hajj A, Rabbaa Khabbaz L. Insomnia and relationship with anxiety in university students: a cross-sectional designed study. PLoS One. 2016;11(2):e0149643.PubMedPubMedCentralCrossRef
158.
Chung KF, Tso KC. Relationship between insomnia and pain in major depressive disorder: a sleep diary and actigraphy study. Sleep Med. 2010;11(8):752–8.PubMedCrossRef
159.
Dadfar M, Salabifard S, Dadfar T, Roudbari M, Safarabad NM. Validation of the Patient Health Questionnaire-2 with Iranian students. Ment Health Relig Cult. 2019;22(10):1048–56.CrossRef
160.
161.
Ertekin Pinar S, Duran Aksoy O, Daglar G, Yurtsal ZB, Cesur B. Effect of stress management training on depression, stress and coping strategies in pregnant women: a randomised controlled trial. J Psychosom Obstet Gynaecol. 2017;39(3):203–10.PubMedCrossRef
162.
Fleishman JA, Zuvekas SH. Global self-rated mental health: associations with other mental health measures and with role functioning. Med Care. 2007;45(7):602–9.PubMedCrossRef
163.
García-Campayo J, Zamorano E, Ruiz MA, Pérez-Páramo M, López-Gómez V, Rejas J. The assessment of generalized anxiety disorder: psychometric validation of the Spanish version of the self-administered GAD-2 scale in daily medical practice. Health Qual Life Outcomes. 2012;10:114.PubMedPubMedCentralCrossRef
164.
Ho RT, Fong TC, Wan AH, et al. A randomized controlled trial on the psychophysiological effects of physical exercise and tai-chi in patients with chronic schizophrenia. Schizophr Res. 2016;171(1–3):42–9.PubMedCrossRef
165.
Hossain S, Anjum A, Uddin ME, Rahman MA, Hossain MF. Impacts of socio-cultural environment and lifestyle factors on the psychological health of university students in Bangladesh: a longitudinal study. J Affect Disord. 2019;256:393–403.PubMedCrossRef
166.
Huang F, Wang H, Wang Z, et al. Psychometric properties of the perceived stress scale in a community sample of Chinese. BMC Psychiatry. 2020;20(1):130.PubMedPubMedCentralCrossRef
167.
Ivziku D, Clari M, Piredda M, De Marinis MG, Matarese M. Anxiety, depression and quality of life in chronic obstructive pulmonary disease patients and caregivers: an actor-partner interdependence model analysis. Qual Life Res. 2018;28(2):461–72.PubMedCrossRef
168.
Jeyagurunathan A, Sagayadevan V, Abdin E, et al. Psychological status and quality of life among primary caregivers of individuals with mental illness: a hospital based study. Health Qual Life Outcomes. 2017;15(1):106.PubMedPubMedCentralCrossRef
169.
Jin H, Wu W, Zhang M. Preliminary analysis of SCL-90 assessment results of Chinese normal people. Chinese J Nerv Ment Dis. 1986;12:260–3.
170.
Lee KS, Yoo TK, Liao L, et al. Association of lower urinary tract symptoms and OAB severity with quality of life and mental health in China, Taiwan and South Korea: results from a cross-sectional, population-based study. BMC Urol. 2017;17(1):108.PubMedPubMedCentralCrossRef
171.
Lin R-M, Xie S-S, Yan W-J, Yan Y-W. Factor structure and psychometric properties of the insomnia severity index in mainland China. Soc Behav Personal Int J. 2018;46(2):209–18.CrossRef
172.
Liu H, Zhang H, Xiao W, et al. Scales for evaluating depressive symptoms in Chinese patients with schizophrenia. J Nerv Ment Dis. 2009;197(2):140–2.PubMedCrossRef
173.
Liu RQ, Qian Z, Trevathan E, et al. Poor sleep quality associated with high risk of hypertension and elevated blood pressure in China: results from a large population-based study. Hypertens Res. 2016;39(1):54–9.PubMedCrossRef
174.
Liu X, Wang XQ, Zhang WN, Bo QY, Zhu SY. Study on the relationship between quality of nursing professional life and depression tendency of nursing staff. Zhonghua Lao Dong Wei Sheng Zhi Ye Bing Za Zhi. 2020;38(5):365–8.PubMed
175.
Löwe B, Decker O, Müller S, et al. Validation and standardization of the generalized anxiety disorder screener (GAD-7) in the general population. Med Care. 2008;46(3):266–74.PubMedCrossRef
176.
Löwe B, Wahl I, Rose M, et al. A 4-item measure of depression and anxiety: validation and standardization of the patient health Questionnaire-4 (PHQ-4) in the general population. J Affect Disord. 2010;122(1–2):86–95.PubMedCrossRef
177.
Lu S, Hu S, Guan Y, et al. Measurement invariance of the Depression Anxiety Stress Scales-21 across gender in a sample of Chinese university students. Front Psychol. 2018;9:2064.PubMedPubMedCentralCrossRef
178.
Lu W, Bian Q, Wang W, Wu X, Wang Z, Zhao M. Chinese version of the Perceived Stress Scale-10: a psychometric study in Chinese university students. PLoS One. 2017;12(12):e0189543.PubMedPubMedCentralCrossRef
179.
Paparrigopoulos T, Tzavara C, Theleritis C, Psarros C, Soldatos C, Tountas Y. Insomnia and its correlates in a representative sample of the Greek population. BMC Public Health. 2010;10:531.PubMedPubMedCentralCrossRef
180.
Pereira-Lima K, Loureiro SR. Burnout, anxiety, depression, and social skills in medical residents. Psychol Health Med. 2014;20(3):353–62.PubMedCrossRef
181.
Ramón-Arbués E, Martínez Abadía B, Granada López JM, et al. Conducta alimentaria y su relación con el estrés, la ansiedad, la depresión y el insomnio en estudiantes universitarios [Eating behavior and relationships with stress, anxiety, depression and insomnia in university students.]. Nutr Hosp. 2019;36(6):1339–45.PubMed
182.
Sasaki N, Imamura K, Thuy TTT, et al. Validation of the Job Content Questionnaire among hospital nurses in Vietnam. J Occup Health. 2019;62(1):e12086.PubMedPubMedCentral
183.
Schmidt RE, Cullati S, Mostofsky E, et al. Healthcare-related regret among nurses and physicians is associated with self-rated insomnia severity: a cross-sectional study. PLoS One. 2015;10(10):e0139770.PubMedPubMedCentralCrossRef
184.
Sinclair SJ, Siefert CJ, Slavin-Mulford JM, Stein MB, Renna M, Blais MA. Psychometric evaluation and normative data for the depression, anxiety, and stress scales-21 (DASS-21) in a nonclinical sample of U.S. adults. Eval Health Prof. 2012;35(3):259–79.PubMedCrossRef
185.
Wang K, Shi HS, Geng FL, et al. Cross-cultural validation of the depression anxiety stress Scale-21 in China. Psychol Assess. 2016;28(5):e88–100.PubMedCrossRef
186.
Wang W, Bian Q, Zhao Y, et al. Reliability and validity of the Chinese version of the patient health questionnaire (PHQ-9) in the general population. Gen Hosp Psychiatry. 2014;36(5):539–44.PubMedCrossRef
187.
Wang WL, Zhou YQ, Chai NN, Li GH, et al. Sleep disturbance and quality of life in clinically stable inpatients with schizophrenia in rural China. Qual Life Res. 2020;29(10):2759–68.
188.
Wang X, Wang X, Ma H. Handbook of Mental Health Assessment Scale. Chin Ment Health J. 1999;13(1):31–5.
189.
Wang Y, Yang X, Song X, et al. Co-treatment of buspirone with atypical antipsychotic drugs (AAPDs) improved neurocognitive function in chronic schizophrenia. Schizophr Res. 2019;209:135–40.PubMedCrossRef
190.
Yang X, Zhang P, Zhao J, et al. Confucian culture still matters: the benefits of Zhongyong thinking (doctrine of the mean) for mental health. J Cross-Cult Psychol. 2016;47(8):1097–113.CrossRef
191.
Yıldırım A, Boysan M, Kefeli MC. Psychometric properties of the Turkish version of the depression anxiety stress Scale-21 (DASS-21). Br J Guid Couns. 2018;46(5):582–95.CrossRef
192.
Yu B, Gu Y, Bao X, et al. Distinct associations of computer/mobile devices use and TV watching with depressive symptoms in adults: a large population study in China. Depress Anxiety. 2019;36(9):879–86.PubMedCrossRef
193.
Zhou J, Yang Y, Qiu X, et al. Relationship between anxiety and burnout among Chinese physicians: a moderated mediation model. PLoS One. 2016;11(8):e0157013.PubMedPubMedCentralCrossRef
194.
Kunzler AM, Helmreich I, Chmitorz A, et al. Psychological interventions to foster resilience in healthcare professionals. Cochrane Database Syst Rev. 2020;7:CD012527.PubMed
195.
Salazar de Pablo G, Vaquerizo-Serrano J, Catalan A, et al. Impact of coronavirus syndromes on physical and mental health of health care workers: systematic review and meta-analysis. J Affect Disord. 2020;275:48–57.PubMedPubMedCentralCrossRef
196.
Bonanno GA, Mancini AD. Beyond resilience and PTSD: mapping the heterogeneity of responses to potential trauma. Psychol Trauma Theory Res Pract Policy. 2012;4:74–83.CrossRef
197.
Mancini AD. Heterogeneous mental health consequences of COVID-19: costs and benefits. Psychol Trauma Theory Res Pract Policy. 2020;12(S1):S15–6.CrossRef
198.
Ahrens KF, Neumann RJ, Kollmann B, et al. Differential impact of COVID-related lockdown on mental health in Germany. World Psychiatry. 2021;20:1.CrossRef
199.
200.
Löwe B, Kroenke K, Herzog W, Gräfe K. Measuring depression outcome with a brief self-report instrument: sensitivity to change of the patient health questionnaire (PHQ-9). J Affect Disord. 2004;81(1):61–6.PubMedCrossRef
201.
Duffy FF, Chung H, Trivedi M, Rae DS, Regier DA, Katzelnick DJ. Systematic use of patient-rated depression severity monitoring: is it helpful and feasible in clinical psychiatry? Psychiatr Serv. 2008;59(10):1148–54.PubMedCrossRef
202.
Erskine HE, Moffitt TE, Copeland WE, et al. A heavy burden on young minds: the global burden of mental and substance use disorders in children and youth. Psychol Med. 2015;45(7):1551–63.PubMedCrossRef
203.
IntHout J, Ioannidis JPA, Rovers MM, Goeman JJ. Plea for routinely presenting prediction intervals in meta-analysis. BMJ Open. 2016;6(7):e010247.PubMedPubMedCentralCrossRef
Metadaten
Titel
Mental burden and its risk and protective factors during the early phase of the SARS-CoV-2 pandemic: systematic review and meta-analyses
verfasst von
Angela M. Kunzler
Nikolaus Röthke
Lukas Günthner
Jutta Stoffers-Winterling
Oliver Tüscher
Michaela Coenen
Eva Rehfuess
Guido Schwarzer
Harald Binder
Christine Schmucker
Joerg J. Meerpohl
Klaus Lieb
Publikationsdatum
01.12.2021
Verlag
BioMed Central
Schlagwort
COVID-19
Erschienen in
Globalization and Health / Ausgabe 1/2021
Elektronische ISSN: 1744-8603
DOI
https://doi.org/10.1186/s12992-021-00670-y

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