COVID-19 Patients: A Systematic Review and Meta-Analysis of Laboratory Findings, Comorbidities, and Clinical Outcomes Comparing Medical Staff versus the General Population
Article information
Abstract
This review compared coronavirus disease 2019 (COVID-19) laboratory findings, comorbidities, and clinical outcomes in patients from the general population versus medical staff to aid diagnosis of COVID-19 in a more timely, efficient, and accurate way. Electronic databases were searched up to 23rd March, 2020. The initial search yielded 6,527 studies. Following screening, 24 studies were included [18 studies (11,564 cases) of confirmed COVID-19 cases in the general public, and 6 studies (394 cases) in medical staff] in this review. Significant differences were observed in white blood cell counts (p < 0.001), lymphocyte counts (p < 0.001), platelet counts (p = 0.04), procalcitonin levels (p < 0.001), lactate dehydrogenase levels (p < 0.001), and creatinine levels (p = 0.03) when comparing infected medical staff with the general public. The mortality rate was higher in the general population than in medical staff (8% versus 2%). This review showed that during the early stages of COVID-19, laboratory findings alone may not be significant predictors of infection and may just accompany increasing C-reactive protein levels, erythrocyte sedimentation rates, and lactate dehydrogenase levels. In the symptomatic stage, the lymphocyte and platelet counts tended to decrease. Elevated D-dimer fibrin degradation product was associated with poor prognosis.
Introduction
Coronavirus disease 2019 (COVID-19) was first detected in Wuhan, China, before rapidly affecting 199 countries and territories around the world. According to the World Health Organization, as of the 24th March, 2020, the total number of patients with COVID-19 was 537,881 with 24,293 deaths [1]. USA, China, Italy, Spain, Germany, and Iran have the most reported laboratory-confirmed COVID-19 cases and deaths [2]. Genetic studies revealed that Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), the virus has an 88% similarity with severe acute respiratory syndrome (SARS), and 50% similarity with Middle East respiratory syndrome (MERS) [3]. Compared with SARS, MERS, and pneumonia, SARS-CoV-2 has a longer incubation time, greater pathogenicity and rapid transmission [4]. Currently there is no vaccine or specific treatment for COVID-19. SARS-CoV-2 infects people of all ages and may cause the respiratory system to rapidly develop acute respiratory distress syndrome (ARDS), cardiovascular complications, and acute kidney injury [5–7]. A fever, cough, dyspnea, fatigue, normal or decreased white blood cells (WBC), and radiographic abnormality in the lungs, are considered as the most frequent clinical manifestation of COVID-19 diagnosis [8]. However, in a study that was conducted by Hu et al [9] only 20.8% of COVID-19 diagnosed patients had typical symptoms, but radiological abnormalities in the lungs was observed in 50% of COVID-19 patients.
Currently, reverse real-time PCR is considered an accurate technique for the diagnosis of COVID-19 however, false-negative results may occur especially in the early stages of the disease. Studies have reported different laboratory findings [10,11]. Nevertheless, a specific laboratory diagnosis, along with other clinical characteristics and their association with the severity of the disease, are necessary. This current review of studies aimed to collect and analyze laboratory findings, comorbidities, and clinical outcomes of infected patients to identify patterns to accurately diagnose COVID-19 more timely and efficiently in infected medical staff compared with the general public.
Materials and Methods
1. Search strategy
Electronic databases including Scopus, Medline/PubMed, EMBASE, Web of Sciences (WOS), and Cochrane library were systematically searched until April 8th, 2020 using MeSH keywords/terms, such as “COVID-19,” “2019 novel coronavirus,” “2019 nCoV,” “COVID-19,” “SARS-CoV-2,” “laboratory findings,” “clinical characteristics,” “medical staff,” “hospital staff,” “medical cares,” and all possible combinations. There was no date and language restriction applied. The present review was performed base on Preferred Reporting Items for the Systematic Review and Meta-Analysis (PRISMA) statement [12]. The search was updated on the 12th April, 2020.
2. Study selection
Two reviewers independently performed title-abstract screening on all selected studies, then the full-text of the selected articles were reviewed. In cases of duplicate information from the same patient, the data were checked and combined, but only considered as a single case.
3. Inclusion criteria
Studies reporting hematological, coagulation, biochemistry, and serological laboratory tests, as well as COVID-19 related comorbidities and clinical outcomes were selected.
4. Exclusion criteria
Studies which were just molecular reports, studies that reported laboratory results as percentages, case reports, and commentaries were excluded.
5. Data extraction
Two reviewers separately extracted the data from included studies, considering key characteristics including author, publication year, country, type of study, sample size, laboratory findings, comorbidities, and final clinical outcomes.
6. The assessment of methodological quality and risk of bias
Quality appraisal checklist and the critical appraisal methodological index for non-randomized studies were used as tools for bias risk assessment [13]. The funnel-plot and Egger’s regression test were used to assess publication bias [14].
7. Statistical analysis
Cochran, Chi-square test, and I2 were used to assess heterogeneity amongst studies. A fixed-effects model was used when I2 < 50%, and when I2 > 50%, a random-effects model was selected. The fixed-model assumed that the population effect sizes were the same for all studies [15]. In contrast the random-effects model attempted to generalize findings beyond the included studies by assuming that the selected studies were random samples from a larger population [16]. If there was statistical heterogeneity amongst the results, a further sensitivity analysis was conducted to determine the source of heterogeneity. After significant clinical heterogeneity was excluded, the randomized effects model was used for meta-analysis. When p < 0.05 the result was considered statistically significant (2-sided). All data were analyzed using the STAT 15 software (IBM, NY, USA).
Results
The initial search yielded 6,527 studies, with duplicate studies removed resulting in 1,759 studies remaining. Following the inclusion exclusion criteria 24 studies were selected. This included 11,950 confirmed cases of COVID-19 and comprised of 18 studies (11,556 cases) of patients from the general population, and 6 studies (394 cases) where medical staff were the patients (Figure 1).
1. Study characteristics and methodological quality assessment
The 24 selected studies obtained from the systematic review are presented in Table 1. Of these, 41.7% [17] were case-control studies [6,8,9,18–23], and 58.3% [20] were cross-sectional design studies [5,18,24–28]. There was 1 study that investigated the association between coagulation abnormalities and prognosis in COVID-19 patients [20]. Just 2 studies had a sample size greater than 1,000 [25,29] (Table 1).
All eligible studies that evaluated medical staff who had contracted COVID-19 were selected. Of these 6 studies there were 394 infected medical staff [19,24,26] (Table 1). Other details of the data are available in Table S1.
2. Laboratory findings analysis
The result of laboratory finding analysis in the general public showed, lymphocytopenia (0.93×109/L; 95% CI: 0.84–1.02), hypoalbuminemia (34.05 g/L; 95% CI: 32.07–36.04) significantly lower, C-reactive protein (CRP) (14.92 mg/L; 95% CI: 4.68–25.16) significantly higher compared with the effects of COVID-19 in medical staff (Table 2).
Further statistical tests revealed that the laboratory variables in infected medical staff were significantly different to the general public who were infected. A lower WBC (p < 0.001), a higher lymphocyte count (p < 0.001), platelet count (p = 0.04 ), and PCT (p < 0.001), a lower LDH (p < 0.001), and creatinine (p = 0.03) were observed in infected medical staff (Table 2). The detailed data are available in Table S2 and S3.
3. Clinical characteristics, comorbid conditions, and clinical outcome analysis
The most reported clinical findings for all cases in this review were a fever 77% (95% CI: 63–89%), a cough 60% (95% CI: 53–68%), and fatigue 38% (95% CI: 28–48%). Further analysis revealed the frequency of clinical manifestations in infected medical staff were similar to patients in the general public (Table 3). Egger test results revealed there was no publication bias in the studies (Table 3).
After investigating comorbidities, it was revealed that patients with hypertension 17% (95% CI: 12–23%), cardiovascular disease (CVD) 0.8% (95% CI: 0.4–12%), or diabetes 10% (95% CI: 0.7–13%) were more susceptible to COVID-19 (Table 4). As shown in Table 5, these frequencies were lower amongst infected medical staff. The clinical outcome showed that the mortality rate was higher in patients from the general population [8% (95% CI: 4–13%)] than patients who were medical staff [2% (95% CI: 0–10%)]. There were 51% (95% CI: 27–75%) of patients from the general population who required hospitalization. Medical staffs had shorter number of days in hospital than patients with relative frequency of 73% (95% CI: 38–97%) (Table S4).
Discussion
The absence of specific laboratory findings and clinical manifestations during the early stages of COVID-19 in patients complicated early diagnosis of the disease. Additional to the rapid progression in late-stage COVID-19, development of ARDS was more severe than ARDS observed with other virus infections which occur routinely [30]. There are several systematic and meta-analysis studies of COVID-19 which mainly discussed comorbidities, clinical manifestations, and treatments [31–35]. In this current review, laboratory abnormality interpretations in early and late stage disease were considered. In this regard, 24 studies, including 11,556 general patients and 394 infected medical staff were evaluated.
Like other viral infections, a fever, a cough, and fatigue were the most commonly observed clinical findings in COVID-19 patients, but the absence of these clinical characteristics cannot rule out infection. In this regard, Hu et al [9] reported just 20.8% of infected patients developed these symptoms during hospitalization. Despite the typical symptom of SARS and MERS infections being diarrhea, it has a low prevalence in COVID-19 [36]. It has been reported in a case without typical COVID-19 clinical characteristics and laboratory results, that the virus was detected in the stool sample suggesting that suspected cases of COVID-19 where diarrhea was present but no laboratory abnormalities are observed should be considered for follow up COVID-19 testing [37]. Additionally, this review supports other data to show that COVID-19 in patients with underlying disease, mainly hypertension, diabetes, and CVD, results in these patients being hospitalized Wang et al [8] showed that patients admitted to the intensive care unit (ICU) had more comorbidities compared with patients not treated in the ICU.
The main mechanism for inflammation and organ damage associated with COVID-19 appears to be attributable to cytokines, especially in pulmonary vascular endothelial cells. SARS-CoV-2 enters the alveolar epithelial cells through angiotensin-converting enzyme 2 receptors [38,39]. Hung et al [16] showed increasing inflammatory cytokines (IL-1β, IL-6, IL-12, IL-10, IFN-γ, and MCP-1) were higher in patients admitted to ICU [6]. Due to the elevated levels of inflammatory cytokines, there was an increasing neutrophil count and infiltration into lung cells, promoting development of ARDS. This indicated that an elevated neutrophil count should be considered protective for lung injury. The elevated levels of CRP and eosinophils (ESR) are the result of these inflammatory cytokines. Hung et al [37] showed that an increase in inhibitory cytokines like IL-4 and IL-10 were associated with COVID-19, which lead to erythropoiesis inhibition and lymphocytopenia. Additionally, there are reports that SARS-CoV-2 infection of immune cells and damage to T lymphocytes leads to lymphocytopenia [5,40,41]. This review of 24 studies is in line with this observation and indicated lymphocytopenia, increasing CRP, and ESR to consider in the diagnosis of COVID-19. It is worth noting that eosinophil count decreases in COVID-19, and the correlation between eosinopenia and lymphocytopenia was observed which could be a useful diagnostic marker for COVID-19 [22].
No significant abnormality was observed in liver function laboratory findings (e.g. AST, ALT, LDH, and bilirubin). SARS-CoV-2 has receptors on the surface of the bile duct, and abnormalities in liver tests can be a result of collateral damage to this organ [21,39,42]. This could be an explanation of normal laboratory findings related to the liver in the early stages of COVID-19. Hypoxia is another pathogenesis associated with COVID-19, which is one of the main causes of sudden death in patients, hence increasing creatine kinase may be due to hypoxia and must be causally interpreted [22].
A critical issue not discussed in earlier systematic and meta-analysis studies are coagulation parameters. Inflammatory cytokine activation of monocytes and endothelial cells, tissue factor expression, and secretion of Von Willebrand clotting factor protein causes the development of and dissemination of intravascular coagulation [21]. It was demonstrated that SARS infection is accompanied by dysregulation of the urokinase pathway, activation of fibrinolysis, increasing fibrin degradation products (FDP), and is associated with poor prognosis [20,43]. The findings of this review indicated that elevated D-dimer was associated with COVID-19. It was demonstrated that disease progression was accompanied by coagulation parameters increasing thus, increasing D-dimer and FDP were observed in patients admitted to ICU [8,20,22].
In the present study, SARS-CoV-2 infected medical staff were compared with SARS-CoV-2 infected patients from the general public and the mean laboratory results showed that medical staff had milder symptoms with slightly less disease severity than the patients from the general population. The clinical outcome analysis revealed 51% of patients from the general population required hospitalization, and the mortality rate was 8%. Whereas in patients who were medical staff, mortality and hospitalization rates were lower, and the discharge rate was higher. This could be due to a lower rate of comorbidities, as well as timely access to diagnostic tools and care [9,19,26]. Amongst the included 24 studies, only Hu et al [44] evaluated asymptomatic patients, hence in the other studies, the clinical outcome was reported among symptomatic and severely affected patients. In this regard, in the study of McMichael et al [45], mortality was reported as high thus, the possible reason could be that the mean age and comorbidities were higher than in the other studies.
Conclusion
The findings of this COVID-19 meta-analysis review revealed that the normal or abnormal outcome of a patient’s laboratory results may shed light on the stage of the disease and its progression. In asymptomatic patients, in the early stages of COVID-19, misdiagnosis may occur due to lack of abnormal laboratory findings, or increasing CRP, ESR, and LDH. In the symptomatic stage, the lymphocyte and platelet counts tended to decrease. In later stages of the disease, inflammatory markers and liver enzymes increased, whereas reduced lymphocyte and platelet counts were associated with a poor prognosis in COVID-19. Though COVID-19 was associated with a reduced mortality rate in medical staff compared to the general public, the use of appropriate personal protective equipment and hand hygiene may help to reduce infection rates. Elevating D-dimer FDP were associated with a poor prognosis, and most of these patients were admitted to the ICU. However, there is a need for longer follow-up time points to evaluate which laboratory parameters return to the normal range.
There are several limitations of this study. Inaccessibility to the full text of articles, lack of reporting laboratory findings, and reporting of results as decreasing or increasing laboratory results by percentage limited this current study. Patients with different stages of COVID-19 were included, and this is one of the main reasons for heterogenicity. In several studies, due to the incomplete treatment periods, the clinical outcome was not reported. The lack of laboratory results in the medical staff studies was another limitation.
Acknowledgments
We wish to thank all our colleagues in the Allied Health Sciences School, Ahvaz Jundishapur University of Medical Sciences. This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
Notes
Conflicts of Interest
The authors have no conflicts of interest to declare.
Supplementary Materials
Supplementary data is available at http://www.kcdcphrp.org.