https://orcid.org/0000-0003-4343-0118
Figures
Abstract
Objectives
SARS-CoV-2 RNAemia at diagnosis is associated with mortality. The aims were to identify factors associated with the development of RNAemia.
Methods
Multicenter COVID-19 cohort study was conducted between January 2020 and May 2023. Demographics, chronic underlying diseases, symptoms and signs, analytical and radiological variables, cytokines, and neutralizing antibodies were evaluated on admission. RNAemia was the primary endpoint.
Results
We included 1011 patients, 392 (38.8%) immunocompromised and 619 (61.2%) immunocompetent. RNAemia occurred in 49.7% and 18.7% (p < 0.001), respectively, being independently associated with 30-day all-cause mortality. In immunocompromised patients, factors independently associated with RNAemia were Alpha and Omicron VOC periods (OR: 1.95 [1.01–3.79]), pneumonia (OR: 1.96 [1.10–3.50]), LDH > 300 UI/L (OR: 1.64 [1.02–2.63]) and neutralizing antibodies absence (OR: 2.51 [1.57–4.00]). In immunocompetent patients, the factors associated with RNAemia were Delta and Omicron VOC periods (OR: 2.27 [1.46–3.52]), lymphocyte count < 1000/µL (OR: 1.81 [1.16–2.80]) and LDH levels > 300 IU/L (OR: 3.99 [2.51–6.36]).
Conclusions
Immunodeficiency almost tripled SARS-CoV-2 RNAemia. Omicron VOC period, LDH as inflammatory biomarker, and a lower immune response in all patients, neutralizing antibodies absence in immunocompromised and lymphopenia in immunocompetent, and pneumonia in immunocompromised patients were associated with RNAemia.
Citation: Martín-Escolano J, Ruiz-Molina A, Rodríguez-Urbistondo C, Infante-Domínguez C, Abelenda-Alonso G, Euba G, et al. (2025) Factors associated with SARS-CoV-2 RNAemia development at COVID-19 diagnosis. PLoS One 20(8): e0330495. https://doi.org/10.1371/journal.pone.0330495
Editor: Benjamin M. Liu, Children's National Hospital, George Washington University, UNITED STATES OF AMERICA
Received: April 10, 2025; Accepted: August 1, 2025; Published: August 21, 2025
Copyright: © 2025 Martín-Escolano et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This study was supported by Plan Nacional de I+D+i 2013-2016 and Instituto de Salud Carlos III, Subdirección General de Redes y Centros de Investigación Cooperativa, Ministerio de Ciencia, Innovación y Universidades, Spanish Network for Research in Infectious Diseases (REIPI, RD16/0016/0001 [JR-B, BG-G], RD16/0016/0005 [NS], and RD16/0016/0009 [JP, EC, JSC]), co-financed by European Development Regional Fund “A way to achieve Europe”, Operative Program Intelligence Growth 2014-2020. EC, JS-C, JR-B and MA-G received grants from the Instituto de Salud Carlos III, Ministerio de Ciencia e Innovación, Proyectos de Investigación sobre el SARS-CoV-2 y la enfermedad COVID-19 (COV20/00370, COV20/00580, COV20/01031) and Acción Estratégica en Salud (PI21/01569). EC and JSC also were supported by the grant IM22/INF/13 from the CIBERINFEC, Instituto de Salud Carlos III, Spain. This study was also supported by CIBERINFEC - Consorcio Centro de Investigación Biomédica en Red, Instituto de Salud Carlos III, Ministerio de Ciencia e Innovación and Unión Europea – NextGenerationEU (JS-C, EC, CI-D, RA-M, MA-G, SS-A, and JMC, CB21/13/00006; BG-G and JRB, CB/21/13/00012; JC, CB21/13/00009). JME is supported by a grant from the ISCIII (FI22/00025). The funders have not role nor any influence on the design, data analysis or interpretation.
Competing interests: The authors have declared that no competing interests exist.
Introduction
As of early June 2025, COVID-19 has caused hundreds of millions of infections and millions of deaths worldwide [1]. This pandemic has triggered an unprecedented global response from all health systems to advance epidemiological, virological, pathophysiological, clinical, and prognostic knowledge of severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) infection. Additionally, the availability of resources has allowed the development of new vaccines and antivirals in record time [2]. Currently, a high percentage of the world’s population is vaccinated against SARS-CoV-2 (67%) with a complete primary series, although there is high variability depending on the country [1]. In Spain, at the time this study was conducted, 79% of the population had been vaccinated using a complete primary series. COVID-19 shows great clinical variability mainly depending on the patient’s baseline condition, ranging from mild cases to critical illness with multiorgan failure and high mortality. Thus, much effort has been put into identifying quick and easy biomarkers of severity at the COVID-19 diagnosis, especially in patients requiring hospital-admission, to implement measures to improve patient management.
SARS-CoV-2 RNAemia, defined as the presence of viral RNA in the bloodstream, has emerged as an independent predictor of severe outcomes in COVID-19 patients [3], and support its role as a valid biomarker. Several reports with large cohorts have found a robust association between SARS-CoV-2 RNAemia and adverse clinical outcomes, including mortality [4–9]. Some of these studies, besides addressing the association of RNAemia with mortality, have also found an association among the presence of RNAemia and plasma viral load with underlying conditions, such as older age and comorbidities, CURB-65 score, or laboratory data such as baseline PaO2/FiO2, LDH, lymphopenia, C-reactive protein, D-dimer, ferritin, and cytokine (IL-6, IL-10, and IL-15) levels [4–6]. A study has showed an association of RNAemia at COVID-19 diagnosis with unfavorable outcome, defined as death and/or intensive care admission, in solid organ transplant recipients, besides with mortality in immunocompetent patients [9].
Other studies have shown an association between severe COVID-19 and immunological factors such as a lack of production of neutralizing antibodies [10–12] and low levels of IgG [13]. Some studies concluded that hospitalized patients have higher titers of neutralizing antibodies (NAb) than non-hospitalized patients [10,11], but the assayed samples were drawn at heterogeneous times after hospital admission; this may explain the discordant results with other studies evaluating the association of lack of NAb response with fatal outcomes, in which NAb and IgG levels remained in the recovered patients, irrespective of disease severity [12]. Additionally, an inverse association between RNAemia and a specific IgG antibody response has been shown in a cohort of patients with COVID-19 with diverse inclusion criteria, suggesting control of SARS-CoV-2 dissemination by the humoral immune response [13].
As vaccination rates have increased worldwide, the dynamics of SARS-CoV-2 transmission have undergone a profound shift [14]. The wide-scale deployment of vaccines, mainly mRNA-based formulations and vector vaccines, has demonstrated remarkable efficacy in preventing severe COVID-19 [2,14]; it has also raised questions about the mechanisms for the presence of SARS-CoV-2 RNAemia and its persistence, seen even in vaccinated patients, and its clinical impact. Unravelling the complexities of this association is essential, given the potential implications for the clinical management of these patients.
Previous studies have provided information on the association of RNAemia with the COVID-19 clinical outcome, mostly in immunocompetent patients, and contradictory information on the specific immune response and its association with RNAemia and COVID-19 severity. As other important issue, from the pandemic onset in 2020, SARS-CoV-2 has evolved to different variants of concern (VOC), showing genetic conservation and diversity, and with changes in virulence and pathogenicity [15]. In this context, the present study aimed to gain valuable insights into the association of host and virological factors, specific immune response and previous vaccination with the development of SARS-CoV-2 RNAemia at the onset of SARS-CoV-2 disease, both in immunocompromised and immunocompetent patients. The data obtained could generate the necessary knowledge to implement interventions aimed at preventing SARS-CoV-2 RNAemia and improving patient prognosis, especially in more vulnerable populations.
Materials and methods
Research design and participants
We conducted a prospective, multicenter, and non-interventional study, carried out in six Spanish hospitals, including both immunocompromised, from March 2020 to May 2023, and immunocompetent, from January 2020 to May 2022, patients. Inclusion criteria were: adult age (≥ 18 years), acute COVID-19 confirmed by a positive SARS-CoV-2 reverse transcription-PCR (RT-PCR) test from nasopharyngeal (NP) swabs, availability of blood samples to determine the presence of SARS-CoV-2 RNAemia in the first 24 h after diagnosis, and signed informed consent. Exclusion criteria included: asymptomatic patients, a life expectancy of less than one month, assessed by the physician judgment following the McCabe-Jackson criteria [16], and patients who declined to sign the informed consent form. This study was approved by the Ethics Committees of Virgen Rocío and Virgen del Macarena University Hospital (C.I. 0771-N-20 and 1683-N-21) and adhered to the Helsinki Declaration.
Clinical data and sample acquisition
Immediately after enrolment, blood samples to determine the presence of SARS-CoV-2 RNAemia, cytokines, and specific immune response were obtained. Demographics, specific clinical signs and symptoms, and complementary data from standard microbiological, biochemical, and hematological studies were recorded for each patient using a protocol case report form. Disease duration was defined as the number of days from symptom onset to death or hospital discharge. Patients were attended following the decisions of the clinician teams in charge, based on local policies and standard clinical management practices, and were followed up until 30 days after COVID-19 diagnosis or until discharge or death, whichever occurred first. Disease severity at the time of COVID-19 diagnosis and the end of the episode was evaluated using the World Health Organization (WHO) Clinical Progression Scale [17].
SARS-CoV-2 detection in NP swabs and blood
For SARS-CoV-2 RNA extraction from plasma samples (collected in EDTA tubes) and NP swabs, a MagNA Pure Compact Nucleic Acid Isolation Kit I (Roche Diagnostics GmbH, Mannheim, Germany) was used according to the manufacturer’s instructions. The RT-PCR assays employed the 2019-nCoV ValuPanel Reagents (LGC Genomics GmbH, Berlin, Germany) in addition to the GoTaq® Probe 1-Step RT-qPCR System (Promega Biotech Ibérica S.L, Madrid, Spain) and were run in a LightCycler 96 Instrument (Roche Diagnostics GmbH, Mannheim, Germany) following the manufacturer’s protocols, with a Ct detection limit of 42. The kit includes internal controls targeting two SARS-CoV-2 nucleocapsid genes and human RNase. SARS-CoV-2 RNAemia quantification was not performed because of it´s not different in immunocompromised vs. immunocompetent patients and its lack of association with unfavorable clinical outcome and/or mortality [9].
Plasma levels of IFN-α and IFN-γ
Plasma samples were collected and stored at −80 °C before analysis. IFN-α (USCN Life Science & Technology Company, Missouri, TX, USA) and IFN-γ (RayBiotech, Norcross, GA, USA) levels were quantified using ELISA kits following the manufacturer’s instructions as described previously [18]. A Multiskan™ GO Microplate Spectrophotometre (Thermo Fisher Scientific, Inc., Waltham, MA, USA) was used to quantify optical density. Relative levels of IFN-α and IFN-γ were analysed using a log/log fit curve with GraphPad Prism 6. These assays, with limits of detection of 3 pg/mL for IFN-α and 2 pg/mL for IFN-γ, were performed in duplicate for each sample. The values used as a reference for healthy, uninfected adults are described in our previous article [9].
Quantification of neutralizing antibodies
Neutralizing antibodies were evaluated using the viral microneutralization assay. Serum samples were collected from blood tubes with separator gel after centrifugation for 10 minutes at 3000 rpm and 4 °C. In a 96-well polystyrene microplate (Corning, New York, USA), serial dilutions of serum samples were prepared and 1.3 x 104 TCID50/mL SARS-CoV-2 (Wuhan-Hu-1) spike pseudotyped lentivirus with a Green Fluorescent Protein reporter of infection (ATCC, Manassas, USA) was added. The mixture was added to microplates containing HEK293T cells expressing human ACE2 and TMPRSS2 (GeneCopoeia, Rockville, MD, USA) that were previously seeded. After incubation at 37 °C for 72 hours, microneutralization by serum was confirmed and quantified. The detection limit for the neutralizing antibodies titer was a 1/3 dilution.
Statistical analysis
The primary endpoint was SARS-CoV-2 RNAemia at the time of COVID-19 diagnosis in both immunocompromised and immunocompetent patients. The associations between SARS-CoV-2 RNAemia and clinical conditions, initial symptoms, and immune and inflammatory variables were also evaluated. Descriptive statistics were presented as frequencies (%) or medians with interquartile ranges (IQRs). Continuous variables such as age, Charlson comorbidity index, oxygen saturation (SpO2), CURB-65, WHO clinical progression scale, lymphocytes, platelets, creatinine, C-reactive protein, D-dimer, and LDH were dichotomized based on their association with mortality [19]. The study was categorized into three periods depending on the predominant SARS-CoV-2 variant of concern (VOC) in Spain [20]: i) Alpha from January 2020 to June 27th, 2021; ii) Delta from June 28th to December 19th, 2021; and iii) Omicron from December 20th, 2021 to May 2023. Univariate analysis was conducted to assess the association between the variables and SARS-CoV-2 RNAemia at the time of COVID-19 diagnosis. Statistical tests for between-group comparisons included χ2 or Fisher’s tests, Student’s t-test, Mann-Whitney U test, and Kruskal-Wallis test. Interactions, confusion, and collinearity were thoroughly explored.
The impact of clinical and laboratory variables on 30-day all-cause mortality was first assessed using Cox regression analysis to confirm that SARS-CoV-2 RNAemia was independently associated with mortality in the whole cohort and the immunocompromised and immunocompetent sub-cohorts. Subsequently, the variables associated with the primary endpoint, SARS-CoV-2 RNAemia at COVID-19 diagnosis, and those considered clinically relevant were incorporated into a multiple logistic regression analysis. The variables in the models were selected manually using a backward stepwise process. Sensitivity analyses were performed, including changes in covariates and specific categorizations. The models of variables identified as associated with SARS-CoV-2 RNAemia in the multiple logistic regression analysis were evaluated using the area under the receiver-operating characteristic curve (AUC-ROC), its standard error (under the non-parametric assumption), and the asymptotic significance (being the null hypothesis a true area of 0.5). An AUC-ROC ≥ 0.70 was considered as evidence of good discrimination ability [21]. Missing data values (Supplementary S1 Table) were not imputed in our analysis given to their low number in the variables included in the multivariate analyses. Statistical analyses were performed using SPSS (version 26.0; IBM Corp., Armonk, New York, USA).
Results
A whole cohort of 1011 patients with acute COVID-19 were included, consisting of 392 (38.8%) immunocompromised and 619 (61.2%) immunocompetent patient’s sub-cohorts (Table 1). In the Omicron period were included 377 (37.3%) patients, 78.1% of them immunocompromised, vs. in the Alpha and Delta periods in which were included 438 (43.3%) and 196 (19.4%) patients, 88.6% and 81.6% of them immunocompetent.
Regarding the characteristics of COVID-19 at diagnosis in the whole cohort, 96.6% patients were hospital-admitted, 82.0% had pneumonia, 7.9% a WHO clinical progression scale score of 6–9, 30.8% SARS-CoV-2 RNAemia, and the 30-day all-cause mortality was 7.8%. Comparing both sub-cohorts, immunocompromised had been vaccinated against SARS-CoV-2 more frequently than immunocompetent patients (86.2% and 35.5%, p < 0.001). SARS-CoV-2 RNAemia was more frequent in immunocompromised than in immunocompetent (49.7% and 18.7%, p < 0.001) sub-cohorts, as well as immunocompromised patients had higher 30-day all-cause mortality (12.0% and 5.2%, p < 0.001).
Variables associated with 30-day all-cause mortality in the whole cohort and immunocompromised and immunocompetent sub-cohorts
The variables associated with 30-day all-cause mortality in the univariate analysis, in the whole cohort and immunocompromised and immunocompetent sub-cohorts, are detailed in Supplementary S2 Tables, S3, and S4. In dead patients, SARS-CoV-2 RNAemia was more frequent in the whole cohort (65.8% vs. 27.8%; p < 0.001) and the immunocompromised (80.9% vs. 45.5%; p = 0.004) and immunocompetent (43.8% vs. 17.4%, respectively; p = 0.051) sub-cohorts. Regarding the SARS-CoV-2 VOC, mortality was lower in immunocompromised patients included in the Omicron period (7.8%) than in Alpha (28%) and Delta (25.0%) periods (p < 0.001), without differences in the immunocompetent patients.
Subsequently, different Cox multiple regression models were generated to identify independent factors associated with 30-day all-cause mortality for the whole cohort and both sub-cohorts (Table 2). For the whole cohort, male sex (hazard ratio [HR]: 0.48 [95% CI 0.30–0.75]), Charlson comorbidity index ≥ 3 (HR: 5.43 [2.19–13.46]), dyspnea (HR: 1.81 [1.13–2.92]), CRP > 100 mg/L (HR: 1.70 [1.08–2.67]) and RNAemia (HR: 2.19 [1.37–3.51]) were selected in the final model. In the immunocompromised sub-cohort, independent variables associated with mortality were male sex (HR: 0.37 [0.20–0.68]), age > 70 years (HR: 2.98 [1.65–5.38]), Alpha and Delta VOVC periods (HR: 3.10 [1.74–5.53]), dyspnea (HR: 1.97 [1.06–3.64]) and RNAemia (HR: 3.30 [1.57–6.93]). Finally, in the immunocompetent sub-cohort selected variables were Charlson comorbidity index ≥ 3 (HR: 22.42 [3.06–164.39]) and RNAemia (HR: 2.35 (1.16–4.75), p = 0.018). The administration of remdesivir, tocilizumab, and dexamethasone were not included in the multivariate Cox regression analysis because of they were prescribed, at the criteria of the attending physicians, more frequently in case with severe disease at diagnosis (Supplementary S5 Table) in the whole cohort and both sub-cohorts.
Variables associated with SARS-CoV-2 RNAemia in the whole cohort and in immunocompromised and immunocompetent sub-cohorts
Variables associated with SARS-CoV-2 RNAemia in the whole cohort and immunocompromised and immunocompetent sub-cohorts are detailed in Table 3 and Supplementary S6 Tables and S8. In the whole cohort (Table 3), patients with SARS-CoV-2 RNAemia had higher frequencies of immunocompromise (p < 0.001) and RNAemia was more frequent in the Omicron than Alpha or Delta VOC periods (p < 0.001). Multiple logistic regression analysis of the whole cohort (Table 4) showed that immunocompromise (odds ratio [OR]: 3.66 [2.47–5.44]), lymphocyte count < 1000/µL (OR: 1.60 [1.16–2.19]) and LDH > 300 UI/L (OR: 2.51 [1.84–3.42]) were independently associated with the presence of SARS-CoV-2 RNAemia at COVID-19 diagnosis. RNAemia seems independently associated with the Omicron VOC period, but this effect was no longer present (OR: 1.44 [0.97–2.15]) when SpO2 was removed from the model. The AUC-ROC were 0.763 (0.731−0795, p < 0.001) and 0.759 (0.726–0.791, p < 0.001) for both models (Supplementary S1 Fig).
In the immunocompromised sub-cohort (Supplementary S6 Table), SARS-CoV-2 RNAemia was more frequent in the Alpha or Omicron than in Delta VOC periods (p = 0.05). Multiple logistic regression analysis (Table 4) identified the Alpha and Omicron VOC periods (OR: 1.95 [1.01–3.79]), pneumonia (OR: 1.96 [1.10–3.50]), LDH > 300 UI/L (OR: 1.64 [1.02–2.63]) and the absence of neutralizing antibodies (OR: 2.51 [1.57–4.00]) as independent factors associated with the presence of SARS-CoV-2 RNAemia at COVID-19 diagnosis, with an AUC-ROC of 0.678 (0.619–0.737, p < 0.001) (Supplementary S1 Fig).
The immunocompromised sub-cohort includes different types of immunocompromise (Supplementary S3 Table) without difference in mortality rates (p = 0.429). However, RNAemia was more frequent (p = 0.045) in hematological malignancies (HM) and solid organ transplant recipients (SOT) than in solid neoplasia (SN) and other causes of immunocompromise (Supplementary S6 Table). As a sensitivity analysis, we next analyzed factors associated with the presence of RNAemia in these different immunocompromised patients (Supplementary S7 Table). Pneumonia (OR: 2.53 [1.18–5.40]) in HM, pneumonia (OR: 2.50 [1.15–5.47]) and neutralizing antibodies absence (OR: 2.81 [1.48–5.35]) in SOT, and neutralizing antibodies absence (OR: 5.37 [1.32–21.87]) in SN were factors independently associated with RNAemia.
SARS-CoV-2 RNAemia in the immunocompetent sub-cohort (Supplementary S8 Table) was more frequent in the Delta and Omicron than in Alpha VOC periods (p = 0.003). Factors independently associated with RNAemia were Delta and Omicron VOC periods (OR: 2.27 [1.46–3.52]), lymphocyte count < 1000/µL (OR: 1.81 [1.16–2.80]) and LDH levels > 300 IU/L (OR: 3.99 [2.51–6.36]) (Table 4). The model has an AUC-ROC of 0.720 (0.670–0.770, p < 0.001) (Supplementary S1 Fig).
Discussion
The present study identifies factors associated with the SARS-CoV-2 RNAemia at the COVID-19 diagnosis. Regarding the host underlying condition, diseases causing immunocompromise are the most prominent ones in the whole cohort. Among the virologic factors, patients included in the Omicron VOC period have more RNAemia, both in immunocompromised and immunocompetent patients. Pneumonia in immunocompromised patients, high serum LDH levels in all patients, and markers of lower immune response, neutralizing antibodies absence in immunocompromised and lymphopenia in immunocompetent patients, were also associated with RNAemia.
In the present study, as a first analysis, we confirmed that SARS-CoV-2 RNAemia was an independent risk factor for 30-day all-cause mortality in both immunocompromised and immunocompetent individuals. Our group and others have previously evaluated the relevance of RNAemia in monitoring COVID-19 patients. The rate of SARS-CoV-2 RNAemia is highly variable in the literature, ranging from 10% to over 60% [3–9,18,22–30], which could be explained by the differences found among the demographic characteristics, underlying conditions, and time from symptom onset. The rate of RNAemia in this study was in line with previous reports by our group and colleagues in both immunocompetent [9,22,23] and immunocompromised patients [9,18]. In addition, despite most patients being fully vaccinated since June 2021, especially in the immunocompromised group, the incidence of RNAemia remained elevated at close to four out of ten cases. The mortality rate in our study was lower than that in previous studies conducted by our group in non-vaccinated immunocompromised and immunocompetent patients [9,22], which is in line with other studies in pre-vaccination cohorts [6,31]. As previously observed in a cohort of 408 immunocompetent individuals and 47 solid organ transplant recipients [9], RNAemia was independently associated with mortality in all immunocompetent or immunocompromised patients.
The increased frequency of RNAemia and its strong association with mortality in immunocompromised patients may reflect impaired viral control and persistent systemic inflammation, which together could facilitate viral dissemination. Weak immune responses may not efficiently eliminate viral replication or bloodstream dissemination. Another associated factor is LDH, an enzyme involved in inflammatory processes, which in turn leads to tissue damage. This could explain the bloodstream release and dissemination of the virus [32,33]. Moreover, higher LDH levels have been associated with severity of COVID-19 pneumonia [34]. In addition, in immunocompetent patients, lymphopenia was independently associated with RNAemia, which is explained by the implication of lymphocytes in the innate immune response, including lymphoid cells type 1 as the first line of defense against viruses. In a previous Spanish nationwide study in a cohort of 4035 patients with COVID-19, lymphopenia was more common in patients who died, being an important predictor of mortality [31] similar to RNAemia, which was also associated with lymphopenia in other studies [4,5,9].
In immunocompromised patients, despite vaccination, the absence of neutralizing antibodies was independently associated with RNAemia. The absence of neutralizing antibodies seems to favor viral dissemination and, in turn, increase tissue damage, which explain the leakage of viral particles and their components from the tissues into the bloodstream [35]. This finding was observed in immunocompromised patients as a whole and, specifically, in both SOT recipients and patients with solid neoplasia. In patients with hematological malignancies, with a vaccination rate similar to the other immunocompromised patients, RNAemia was associated with the presence of pneumonia, as previously reported [18], but not with the absence of neutralizing antibodies; this fact may be explained by the heterogeneity of diseases included in this type on immunocompromised patients.
Our study has several limitations. Although it was a prospective cohort, inclusion was dependent on having blood samples to evaluate RNAemia after obtaining informed consent from patients. Additionally, the number of patients with mild disease not requiring hospital admission was smaller than the number of patients admitted to the hospital, although more patients had moderate rather than severe disease at the time of blood sampling. Another limitation was the different vaccination rates between immunocompromised patients, who were the first scheduled to receive the vaccine, and immunocompetent patients. Despite these limitations, the strength of this study lies in the multicenter design of our cohort, which was recruited from six Spanish hospitals. Each hospital had its own clinical practice and protocols, although the clinical practice was similar because all followed common national and international guidelines, confirmed by comparing the treatments received by patients with severe and mild patients. Immunocompromised and immunocompetent patients with clinically severe COVID-19, which has previously been associated with RNAemia [4,6,9], were treated more frequently with tocilizumab and dexamethasone at the discretion of the physicians in charge. Finally, the present study has not considered the possible viral and bacterial co-infections [36]. However, the accuracy of co-infections diagnosis in the viral community-acquired respiratory infections, including pneumonia, is a difficult issue because of the lack of specificity of many bacterial isolates from respiratory clinical samples. A study on 50,419 upper respiratory samples, positive for SARS-CoV-2, detected 4% and 33% of viral and bacterial co-infections, respectively, but without expressing the method to differentiate Staphylococcus aureus or Haemophilus influenzae detection, as examples, from asymptomatic carriers [37]. In addition, a review of 13 studies disclosed a wide co-infection and secondary infection rates in SARS-CoV-2 infection, from 0.6% to 45.0% [38], which denotes the very different criteria for diagnostic specificity used in the different studies.
Conclusions
The results of this study show that the main factor determining the presence of SARS-CoV-2 RNAemia at COVID-19 diagnosis depends on underlying conditions such as immunodeficiency, with RNAemia rates almost three times higher in this population than those in immunocompetent individuals. Pneumonia and absence of neutralizing antibodies in immunocompromised patients, biomarkers of tissue damage as LDH in all patients, and lymphopenia in immunocompetent patients were also associated with bloodstream dissemination of the virus. These data highlight the need for quick detection of SARS-CoV-2 RNAemia for early initiation of antiviral treatment, especially in the most vulnerable populations, as RNAemia is associated with poor clinical outcomes. The efficacy of antiviral treatments, through clinical studies, must consider the different demographics features and chronic underlying diseases of patients.
Supporting information
S1. Additional supporting information may be found online in the Supporting Information section.
https://doi.org/10.1371/journal.pone.0330495.s001
(DOCX)
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