CRP and kidney function tests in patients with Covid-19

Omar, Yasmen Mohamed; Elsherif, Ahmed Abdel Samie; Okaily, Nagwa Ismail; Mohamed, Omima Mohamed

doi:10.21608/mjmr.2023.215806.1412

CRP and kidney function tests in patients with Covid-19

Document Type : Original Article

Authors

Department of clinical pathology, faculty of medicine, Minia University, Minia, Egypt

10.21608/mjmr.2023.215806.1412

Abstract

Purpose of study: Coronavirus disease 2019 (COVID-19) is a newly discovered respiratory disorder caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and recently declared as pandemic. Mild to moderate symptoms are the initial presentation in most patients. Kidney damage is a frequent side effect of COVID-19. Acute phase reactants (APRs), are inflammation biomarkers that exhibit marked changes in blood concentrations at the time of inflammation. Important APRs include serum ferritin, C-reactive protein (CRP) and D-dimer. This study aimed to assess the role CRP and kidney function tests in Covid-19 and their impact on disease severity.

Basic procedures: This study was conducted on 80 subjects including 20 apparently healthy individuals (group II) as a control group matched for age and sex and 60 Covid-19 patients diagnosed by PCR (group I) and was subdivided into 2 subgroups, G Ia: 30 (Non- ICU) Covid-19 patients and G Ib: ICU (intensive care unit) admitted COVID-19 patients with respiratory complications. This study was conducted at clinical pathology department, faculty of medicine, Minia University during the period from November 2021 to June 2022.

Main findings: results of this study revealed a significant difference regarding CRP and kidney function tests as covid-19 patients showed higher levels than control group, but there was no significant difference between both patient groups. Principle conclusion: Overall, this study revealed that elevation of both CRP and kidney function tests indicate a poor prognosis in individuals with covid-19, therefore, they may be involved in prediction of clinical course of the infection.

Keywords

Main Subjects

Immune modulation and inflammatory mediators.

Full Text

Introduction

In 2019, millions of people were affected by the worldwide pandemic resulted from Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2) infection. COVID-19 causes numerous symptoms, many of which are complicated, primarily involving the respiratory system, but also multiple organs were affected in many cases leading to major health problems or even death ^[1].

The new (SARS-CoV-2) resulted in COVID-19 outbreak, which had developed into an emerging worldwide health disaster. Recently, numerous risk factors, such as advanced age, male gender, presence of comorbid conditions, and differences in racial and ethnic groups have been recognized as potentially having an effect on rising the morbidity of COVID-19 in adults. Additionally, the progress of COVID-19 to more severe and difficult form may be indicated by variations in laboratory parameters and pro-inflammatory cytokines and also potential consequences. Early in SARS-CoV-2 infection, patients may be present without symptoms, until development of dyspnea, severe pneumonia, organ damage, and eventually death^[2].

Severe COVID-19 is marked by massive inflammatory reaction, involving excessive release of cytokines, that may be recognized in both the lungs and the bloodstream. Multiple immune cells are involved in the response, such as inflammatory mediators are induced by neutrophils and macrophages when they detect pathogens and damaged self-structures ^[3].

Cardiac arrhythmias, rhabdomyolysis, shock, coagulopathy and acute organ damage like liver, cardiac and kidney damage, all may be consequences of severe COVID-19 ^[4].

Clinical and laboratory signs of inflammation, such as high fevers, thrombocytopenia, increased serum ferritin, and elevation of CRP and interleukin-6 (IL-6), may be accompanied with these organ failures ^[5].

CRP is known as a non-specific acute phase reactant which is increased during inflammation or infection. Elevated values point to a more serious infection. Elevated levels of CRP have been utilized to predict the of severity in COVID-19 disease, despite the lack of data supporting its use as a predictive marker ^[6].

When hepatocytes are activated during inflammation, they quickly produce CRP. It binds to numerous prokaryotic and eukaryotic pathogens, enabling activation of complement by classical pathway suggesting immunological activation, lymphocyte invasion, consumption of immune molecules and marked inflammatory response ^[7].

Individuals having serious form of Covid-19 with multiple organs affection and dead people were observed to have elevated values of CRP. CRP causes complement activation resulting in induction of apoptosis and the expression of pro-inflammatory cytokines that, when combined with the inflammatory condition of the disease, may result in worse prognosis ^[8].

Kidney affection in COVID-19 is common, although hypoxaemia and respiratory failure are the characteristic symptoms. Despite significantly decreased kidney function acute tubular damage commonly occurs, although it is frequently mild. Tubular damage is most likely a result of systemic hemodynamic instability. ^[9].

COVID-19 infection directly results in acute kidney injury (AKI) which is frequent in markedly diseased patients and is among the worst clinical outcomes with a poor prognosis for survival. Between 10 and 40 percent of COVID-19 patients who are hospitalized continue to get AKI. From the beginning of the COVID-19 pandemic, AKI has killed a majority of older people with severe comorbidities ^[10].

Tubular damage and noticeable urine analysis abnormalities are characteristic features of typical kidney affection resulting from COVID-19. Also, impairment of glomerular filtration presents, that is typically recognized by high concentration of serum creatinine and blood urea nitrogen. individuals with kidney affection due to COVID-19 may experience mild form of proteinuria ^[11].

A negative impact on the maintenance of the acid-base balance and electrolyte in the human body results from impairment of renal function that may prevent the body from excreting metabolites and toxins. Additionally, uremia will develop when kidney function is markedly affected, and threatening life. Early identification of signs of renal affection and prompt, efficient therapies are of significant value for minimizing worse consequences and improving outcome ^[12].

Aim of the work:

The aim of this study is to assess the role of CRP and kidney function tests in Covid-19 and their impact on the disease severity.

Subjects and methods

This study was done on eighty subjects including 20 apparently healthy individuals (group II) as a control group matched for age and sex and 60 patients diagnosed Covid-19 patients by PCR (group I) and was subdivided into 2 subgroups: group Ia: 30 (Non – ICU) Covid-19 patients and group Ib: 30 ICU (intensive care unit) admitted COVID-19 patients with respiratory complications. This study was conducted at the department of clinical pathology, faculty of medicine, Minia University during the period from November 2021 to June 2022. The diseased subjects were diagnosed as Covid-19 patients by PCR. Molecular methods based on the real-time (quantitative) reverse transcriptase-polymerase chain reaction (RT-PCR) are recently considered as the gold standard method used in COVID-19 diagnosis ^[13]. This study was approved by the hospital ethical committee and a written consent was obtained from each subject (Approval number: 134:11/2021, Date of approval: 29 November 2021).

Inclusion Criteria:

PCR positive RNA of Covid-19

Exclusion Criteria:

Vaccinated patients against Covid-19

All subjects involved in the study were subjected to careful history taking, complete clinical examination and laboratory investi-gations. C-Reactive Protein (CRP) was measured using GENRUI, biotech Inc, kinetic assay,China. Kidney function tests (blood urea & serum creatinine) were measured using auto-analyzer SELECTRA PRO XL, ELITech Group, clinical chemistry automation systems, Netherlands, using the commercially available kits according to the manufaturer’s instructions.

Results

All selected subjects in this study were divided into two groups: Group I: which included 60 Covid-19 patients diagnosed by PCR and was subdivided into 2 subgroups, group Ia: 30 (Non- ICU) Covid-19 patients and group Ib: 30 ICU (intensive care unit) admitted COVID-19 patients with respiratory complications. Group II: 20 apparently healthy individuals as a control group matched for age and sex.

Discussion

Most of individuals with severe Covid-19 develop lymphopenia, and some of them also have thromboembolic complications and problems of either peripheral or central nervous system ^[14]. A long with rhabdomyolysis, coagulopathy, cardiac arrhythmias and shock, additionally severe Covid-19 may lead to acute kidney, cardiac, and liver damage ^[15]. Clinical and laboratory indicators of inflammation, such as high fevers, thrombocytopenia, increased serum ferritin, and elevations in CRP and IL-6, can be linked to these organ failures ^[16].

In this study there was statistically significant elevation in CRP level in patient groups than control group and this was in agreement with stringer and his colleague who showed that increased levels of CRP have been recognized in COVID-19 patients which is used to assist in diagnosis, triage and prognosis. CRP is defined as a non-specific acute phase protein that is synthesized by liver cells and is raised during acute inflammation or infection ^[6].

High levels of CRP have been linked to death due to SARS-CoV-2 infection, regarding to elevation in CRP level during this infection. CRP has been demonstrated as a chemical that can cause damage during infection with SARS-CoV-2 ^[8].

Clinically, elevated CRP levels may serve as early warning signs of hospital-acquired infections in patients with COVID-19 that make slow progress, also it may help physicians to begin empirical antibiotics therapy as early as possible to avoid worsened outcome ^[17].

There was statistically significant difference in renal function tests between the patient groups and control group as both (urea & creatinine) were significantly increased in patient group than control group and this was in agreement with Liakopoulos and his colleague who showed that acute kidney injury (AKI) is among the popular outcomes of COVID-19, making kidney among the target organs of SARS-COV-2 disease. Multiple pathogenic pathways have been recognized, including critical hypoxia, hemodynamic changes, inflammation and sepsis, rhabdomyolysis, mitochondrial injury, acute cardiorenal syndrome, endothelial dysfunction, microembolism, renal infarction and use of nephrotoxic medications ^[18].

Symptoms of the kidneys affection in COVID-19 frequently range from mild proteinuria to advanced AKI that need renal replacement treatment, increased blood urea nitrogen (BUN), serum creatinine (SCr), hematuria, proteinuria are characteristics of this renal impairment ^[19].

Due to immune system suppression, individuals with CKD show higher risk of infection with COVID-19 that could result in worse COVID-19 outcomes. CKD appears to be linked to elevated risk of severe form of COVID-19. As a result, CKD Patients must be warned to do additional precautions for reducing possibility of viral exposure ^[20].

‏

References

Conclusion

Overall, results of the present study revealed that elevation of both CRP and kidney function tests indicate a poor prognosis in patients with covid-19, therefore, they may be involved in prediction of clinical course of the infection.

References
1. Capone, F., Rossi, M., Cruciani, A., Motolese, F., Pilato, F., & Di Lazzaro, V. (2023): Safety, immunogenicity, efficacy, and acceptability of COVID-19 vaccination in people with multiple sclerosis: a narrative review. Neural Regeneration Research, 18(2), 284.‏
2. Zhang, J. J., Dong, X., Liu, G. H., & Gao, Y. D. (2023): Risk and protective factors for COVID-19 morbidity, severity, and mortality. Clinical Reviews in Allergy & Immunology, 64(1), 90-107.‏
3. Paludan, S. R., & Mogensen, T. H. (2022). Innate immunological pathways in COVID-19 pathogenesis. Science Immunology, 7(67), eabm5505.‏
4. Huang, C., Wang, Y., Li, X., Ren, L., Zhao, J., Hu, Y., et al., (2020): Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. The lancet, 395(10223), 497-506.‏
5. Moore, J. B., & June, C. H. (2020): Cytokine release syndrome in severe COVID-19. Science, 368(6490), 473-474.‏
6. Stringer, D., Braude, P., Myint, P. K., Evans, L., Collins, J. T., Verduri, A., et al., (2021): The role of C-reactive protein as a prognostic marker in COVID-19. International journal of epidemiology, 50(2), 420-429.‏
7. Pepys, M. B., & Hirschfield, G. M. (2003): C-reactive protein: a critical update. The Journal of clinical investigation, 111(12), 1805-1812.‏
8. Mosquera-Sulbaran, J. A., Pedreañez, A., Carrero, Y., & Callejas, D. (2021): C-reactive protein as an effector molecule in Covid‐19 pathogenesis. Reviews in medical virology, 31(6), 2221.‏
9. Legrand, M., Bell, S., Forni, L., Joannidis, M., Koyner, J. L., Liu, K., et al., (2021): Pathophysiology of COVID-19-associated acute kidney injury. Nature Reviews Nephrology, 17(11), 751-764.‏
10. Gutiérrez-Abejón, E., Martín-García, D., Tamayo, E., Álvarez, F. J., & Herrera-Gómez, F. (2021): Clinical profile, pharmacological treatment, and predictors of death among hospitalized COVID-19 patients with acute kidney injury: a population-based registry analysis. Frontiers in Medicine, 8, 657977.‏
11. Han, X., & Ye, Q. (2021): Kidney involvement in COVID‐19 and its treatments. Journal of medical virology, 93(3), 1387-1395.‏
12. Hong, X. W., Chi, Z. P., Liu, G. Y., Huang, H., Guo, S. Q., Fan, J. R., et al., (2020): Characteristics of renal function in patients diagnosed with COVID-19: an observational study. Frontiers in Medicine, 7, 409.‏
13. Park, G. S., Ku, K., Baek, S. H., Kim, S. J., Kim, S. I., Kim, B. T., et al., (2020): Development of reverse transcription loop-mediated isothermal amplification assays targeting severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). The Journal of Molecular Diagnostics, 22(6), 729-735.‏
14. Mao, L., Jin, H., Wang, M., Hu, Y., Chen, S., He, Q., et al., (2020): Neurologic manifestations of hospitalized patients with coronavirus disease 2019 in Wuhan, China. JAMA neurology, 77(6), 683-690.‏
15. Guo, T., Fan, Y., Chen, M., Wu, X., Zhang, L., He, T., et al., (2020): Cardiovascular implications of fatal outcomes of patients with coronavirus disease 2019 (COVID-19). JAMA cardiology, 5(7), 811-818.‏
16. Berlin, D. A., Gulick, R. M., & Martinez, F. J. (2020): Severe covid-19. New England Journal of Medicine, 383(25), 2451-2460.‏
17. Chen, W., Zheng, K. I., Liu, S., Yan, Z., Xu, C., & Qiao, Z. (2020): Plasma CRP level is positively associated with the severity of COVID-19. Annals of clinical microbiology and antimicrobials, 19(1), 1-7.‏
18. Chen, W., Zheng, K. I., Liu, S., Yan, Z., Xu, C., & Qiao, Z. (2020): Plasma CRP level is positively associated with the severity of COVID-19. Annals of clinical microbiology and antimicrobials, 19(1), 1-7.‏
19. Lanari, M., Venturini, E., Pierantoni, L., Stera, G., Castelli Gattinara, G., Esposito, S. M. R., et al., (2022): Eligibility criteria for pediatric patients who may benefit from anti SARS-CoV-2 monoclonal antibody therapy administration: an Italian inter-society consensus statement. Italian Journal of Pediatrics, 48(1), 1-10.‏
20. Gok, M., Cetinkaya, H., Kandemir, T., Karahan, E., Tuncer, İ. B., Bukrek, C., et al., (2021): Chronic kidney disease predicts poor outcomes of COVID-19 patients. International Urology and Nephrology, 53(9), 1891-1898.