Evaluation of serum and salivary C-reactive protein for diagnosis of late-onset neonatal sepsis: A single center cross-sectional study

Tosson, Angie M.S.; Koptan, Dina; Aal, Rabab Abdel; Elhady, Marwa Abd

doi:10.1016/j.jped.2021.01.004

Abstract

Objective:

To evaluate the diagnostic utility of salivary C-reactive protein (CRP) and its potential correlation with serum CRP levels in full-term neonates with late-onset sepsis (LOS).

Methods:

This cross-sectional study included 90 neonates assigned to three equal groups: culture proven LOS, clinical LOS and a control group. Clinical findings and routine laboratory data including complete blood pictures and blood culture results were documented. Highly sensitive serum CRP was measured according to hospital protocol, while salivary CRP levels were measured using enzyme-linked immunosorbent assay.

Results:

The median serum CRP was significantly higher in septic neonates compared to controls (p < 0.001). For serum CRP, the optimum cut-off value for LOS diagnosis was found to be 7.2 mg/L with sensitivity, specificity, positive and negative predictive values of 91, 100, 100, and 85.7%, respectively. No significant difference was observed in levels of salivary CRP among the 3 study groups (p = 0.39). No correlation was found between the levels of salivary and serum CRP (r = 0.074, p = 0.49).

Conclusion:

Serum CRP, at a cut-off value of 7.2 mg/L, exhibited a high specificity and positive predictive value in LOS diagnosis, whereas salivary CRP levels weren’t significantly different between the 3 study groups nor did they predict abnormal serum CRP thresholds in newborns with sepsis.

KEYWORDS
Late-onset neonatal sepsis; Highly sensitive serum CRP; Salivary CRP

Introduction

Sepsis is one of the main causes of morbidity and mortality among newborns. According to its time of onset after birth, neonatal sepsis (NS) is classified into: early-onset sepsis variably defined as occurring within 48-72 hours after birth and late-onset sepsis (LOS) occurring thereafter.¹1 Freitas FT, Araujo AF, Melo MI, Romero GA. Late-onset sepsis and mortality among neonates in a Brazilian Intensive Care Unit: a cohort study and survival analysis. Epidemiol Infect. 2019;147:e208.,²2 Akbarian-Rad Z, Riahi SM, Abdollahi A, Sabbagh P, Ebrahimpour S, Javanian M, et al. Neonatal sepsis in Iran: A systematic review and meta-analysis on national prevalence and causative pathogens. PLoS ONE. 2020;15:e0227570. The clinical findings of NS are often subtle and nonspecific, in view of that, neonates suspected of sepsis are usually prone to empirical administration of broad-spectrum antibiotics until sepsis can be excluded, which favors the emergence of drug resistant strains.³3 Tzialla C, Borghesi A, Serra G, Stronati M, Corsello G. Antimicrobial therapy in neonatal intensive care unit. Ital J Pediatr. 2015;41:27. The diagnosis of NS is often based on clinical assessment in combination with laboratory findings. Blood culture remains the definitive standard for diagnosing NS, despite being time consuming. In addition, a relatively small blood sample or prior exposure to empirical antibiotics may cause false-negative results. Notably, a positive blood culture may reflect asymptomatic bacteremia or contamination.⁴4 Shehab El-Din EM, El-Sokkary MM, Bassiouny MR, Hassan R. Epidemiology of Neonatal Sepsis and Implicated Pathogens: A Study from Egypt. Biomed Res Int. 2015;2015:509484.

Many studies evaluated the sensitivity and specificity of the several markers in NS e.g. interferon-gamma, different interleukins and blood cell parameters, yet results vary extensively between studies.⁵5 Prathyusha, Shreekrishna GN, Bhat S, Sahana P. Mean platelet volume (MPV) as a diagnostic marker in neonatal sepsis. Int J Contemp Pediatr. 2019;6:1036-40.,⁶6 Tosson AM, Glaser K, Weinhage T, Foell D, Aboualam MS, Edris AA, et al. Evaluation of the S100 protein A12 as a biomarker of neonatal sepsis. J Matern Fetal Neonatal Med. 2020;33:2768-74.

The clinical use of C-reactive protein (CRP) as a biomarker for sepsis in neonates has been well validated. Nevertheless, a limitation to its serial monitoring in newborns currently is its reliance on repeated blood draws putting this susceptible population at medical risk.⁷7 Omran A, Maaroof A, Saleh MH, Abdelwahab A. Salivary C-reactive protein, mean platelet volume and neutrophil lymphocyte ratio as diagnostic markers for neonatal sepsis. J Pediatr (Rio J). 2018;94:82-7. Establishing a non-invasive method for its quantification could reduce side-effects and improve its clinical utility in newborns. Saliva contains systemic proteins, immunoglobulins, electrolytes, nucleic acids, microorganisms, toxins, and drugs, being an important reservoir of them. Therefore, it represents an ideal non-invasive alternative to serum screening for a variety of infectious processes.⁸8 Iyengar A, Paulus JK, Gerlanc DJ, Maron JL. Detection and potential utility of C-reactive protein in saliva of neonates. Front Pediatr. 2014;2:131. Several studies investigated the use of saliva as a substitute biofluid for serum CRP, yet results are inconsistent.⁸8 Iyengar A, Paulus JK, Gerlanc DJ, Maron JL. Detection and potential utility of C-reactive protein in saliva of neonates. Front Pediatr. 2014;2:131.

9 Dillon MC, Opris DC, Kopanczyk R, Lickliter J, Cornwell HN, Bridges EG, et al. Detection of homocysteine and C-reactive protein in the saliva of healthy adults: comparison with blood levels. Biomark Insights. 2010;5:57-61.-¹⁰10 Pay JB, Shaw AM. Towards salivary C-reactive protein as a viable biomarker of systemic inflammation. Clin Biochem. 2019;68:1-8. The objective of the current study was to measure the levels of salivary CRP and to explore its potential correlation with serum CRP for LOS diagnosis in a cohort of full-term neonates.

Methods

Study population

This cross-sectional study included ninety full-term neonates who were admitted in the neonatal intensive care unit (NICUs) of Cairo University, Cairo, Egypt, between October 2018 and March 2019. The exclusion criteria from this study were pre-term neonates, neonates with early onset sepsis, respiratory distress syndrome, hypoxia, major congenital anomalies, metabolic disease, mechanical ventilation and neonates that underwent major surgical procedures. The patients were divided into three equal groups. Demographic and clinical data were collected and recorded. Newborns in the clinical LOS group were diagnosed on the basis of clinical suspicion, but their blood cultures were negative. Neonates in the culture proven LOS group were diagnosed clinically and had a positive blood culture. The controls were age and sex matched newborns with no clinical or laboratory findings of sepsis. The study protocol ethics was approved by the scientific committee of the Pediatrics department, Faculty of Medicine, Cairo University and followed the tenets of the Helsinki declaration. Informed consent was obtained from the parents.

Laboratory investigations

Laboratory investigations performed routinely on appearance of any signs suggestive of sepsis included CBC, serum CRP and blood culture. CBC was analyzed by the automated blood cell counter Sysmx xs-800i (Roche diagnostics) using 2 mL peripheral blood samples, anticoagulated with Ethylenediaminetetraacetic acid. For accurate mean platelet volume (MPV) calculation, samples were analyzed within 60 min after collection to avoid platelet swelling and false increase of MPV value. Differential count was analyzed by pathologists blinded to the infection status of these infants. Immature to total (I/T) neutrophils ratio was calculated by dividing the total number of immature neutrophils by the total neutrophilic count. Degenerative changes in neutrophils included vacuolization, toxic granulations and Dohle bodies. For blood culture, a 1 mL blood sample was withdrawn under strict aseptic measures and inoculated into a blood culture bottle. Bactec microbial detection system (Bactec 9050, Becton-Dickinson, New Jersey, USA) was used for blood culture. According to standard microbiological methods, positive cases were subjected to subculture. This was considered positive if the isolated organism was known to cause bacteremia or if the organisms isolated consecutively in 2 cultures within 7 days were known as skin contaminants. For determination of serum high sensitivity CRP (hs-CRP), 1 mL blood was collected into a plain vacutainer tube. Serum was separated as soon as possible to prevent hemolysis and measured on cobas automated analyzer (Roche diagnostics). Samples of saliva were collected within 4-12 h of clinically indicated serum CRP levels using a previously established protocol.¹¹11 Dietz JA, Johnson KL, Wick HC, Bianchi DW, Maron JL. Optimal techniques for mRNA extraction from neonatal salivary supernatant. Neonatology. 2012;101:55-60. Collection of samples occurred nearly 1 h before feeding to avoid milk or formula contamination by tilting the head forward to pool saliva in the floor of the mouth. Samples were obtained by using a 1-mL syringe, wings removed, attached to low wall suction (< 20 mmHg) maintained for 10-15 seconds, collecting around 0.5 mL. Samples were then placed in polypropylene tubes and stored in-20^◦C until use. Estimation of salivary CRP level was performed using a quantitative enzyme linked Immunosorbent assay kit (Bioassay technology laboratory). Samples were plotted against standard curve for CRP quantification.

Statistical methods

Sample size calculation was based on the sensitivity of measuring salivary CRP level in predicting neonatal sepsis among neonatal ICU cases. Prior data indicated that the sensitivity of salivary CRP in predicting neonatal sepsis ranged from 54% to 94%.⁷7 Omran A, Maaroof A, Saleh MH, Abdelwahab A. Salivary C-reactive protein, mean platelet volume and neutrophil lymphocyte ratio as diagnostic markers for neonatal sepsis. J Pediatr (Rio J). 2018;94:82-7.,⁸8 Iyengar A, Paulus JK, Gerlanc DJ, Maron JL. Detection and potential utility of C-reactive protein in saliva of neonates. Front Pediatr. 2014;2:131.,¹²12 Omran A, Ali M, Saleh MH, Zekry O. Salivary C-reactive protein and mean platelet volume in diagnosis of late-onset neonatal pneumonia. Clin Respir J. 2018;12:1644-50. A minimum of 24 neonates in each group was needed to reject the null hypothesis with 80% power setting type I error probability to 0.05. Data were described in terms of mean standard deviation (SD), median and range, or frequencies (number of cases) and percentages when appropriate. Comparison of numerical variables between the study groups was done using one-way analysis of variance (ANOVA) test with posthoc multiple 2-group comparisons. For comparing categorical data, Chi-square (X²2 Akbarian-Rad Z, Riahi SM, Abdollahi A, Sabbagh P, Ebrahimpour S, Javanian M, et al. Neonatal sepsis in Iran: A systematic review and meta-analysis on national prevalence and causative pathogens. PLoS ONE. 2020;15:e0227570.) test was performed. Exact test was used instead when the expected frequency is less than 5. Correlation between quantitative variables was done using the Spearman-rho method. Receiver operator characteristic (ROC) analysis was used to define the optimum cut-off value for the studied diagnostic markers. P values less than 0.05 was considered statistically significant. Statistical calculations were performed using computer program IBM SPSS (Statistical Package for the Social Science; IBM Corp, Armonk, NY, USA) release 22 for Microsoft Windows.

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Table 1
Demographic characteristics of the neonates under study.^a a Unless indicated, data is presented as mean ± SD. .

Results

Demographic features and clinical characteristics

The current study included 90 full-term admitted neonates. There was no difference between the septic and control groups in regards to gender, weight or postnatal age (p > 0.05 for all) (Table 1). Among the recorded clinical features, poor suckling, impaired Moro reflex, feeding intolerance, abdominal distention and respiratory distress were significantly more frequent among septic as compared to the control group (p < 0.001).

Laboratory parameters

Positive blood cultures were obtained in 30 neonates. Methicillin-resistant Staphylococcus aureus was the most common isolate in the septic group (45%) followed by Klebsiella spp. (36%), coagulase-negative Staphylococci (10%) and other organisms including Acinetobacter, Pseudomonas and Candida spp. (3% each).

The median serum CRP was significantly higher in septic neonates compared to the aseptic group (p < 0.001) being 31.9 mg/L (IQR = 0.9-154.2) in the clinically septic, and 47.1 mg/L (IQR = 0.9-152) in culture proven septic neonates; while being 1.65 mg/L (IQR = 0.9-6.9) in controls. Though the median salivary CRP was 0.42 mg/L (IQR = 0.1-11.3) in clinically septic and 1.17 mg/L (IQR = 0.02-12.1) in culture proven septic neonates compared to 0.23 mg/L (IQR = 0.01-3.8) in the control group, yet, it didn’t reach statistical significance (p = 0.39). Furthermore, there was a no statistically significant correlation between serum and raw salivary CRP concentrations (r = 0.074, p = 0.49). Levels of serum and salivary CRP are listed in Table 2.

Figure 1
ROC curve for prediction of sepsis using hs-CRP.

The noted findings in the complete blood picture which were mostly significantly higher in the septic groups that are listed in Table 2. There were no statistically significant differences between culture proven septic and clinical septic groups as regards noted findings in the complete blood picture, serum or salivary CRP. Their optimal cut-off values identified by ROC curves of culture proven and clinical sepsis versus controls, as well as their predictive abilities are presented in Table 3. The optimum cut-off value of serum CRP for LOS diagnosis was 7.2 mg/L with sensitivity, specificity, positive predictive value (PPV) and negative predictive value (NPV) of 91, 100, 100, and 85.7%, respectively (Table 3; Fig. 1).

Discussion

Neonatal sepsis (NS) contributes substantially to neonatal morbidity and mortality globally, despite recent health care advances¹³13 Sorsa A. Epidemiology of Neonatal Sepsis and Associated Factors Implicated: Observational Study at Neonatal Intensive Care Unit of Arsi University Teaching and Referral Hospital, South East Ethiopia. Ethiop J Health Sci. 2019;29:333-42. reaching an incidence of 17.5% among term neonates in some Arab states in the Gulf region.¹⁴14 Hammoud MS, Al-Taiar A, Al-Abdi SY, Bozaid H, Khan A, AlMuhairi LM, et al. Late-onset neonatal sepsis in Arab states in the Gulf region: two-year prospective study. Int J Infect Dis. 2017;55:125-30. Common clinical manifestations of LOS recorded in this work were poor suckling, impaired Moro reflex, feeding intolerance, abdominal distention and respiratory distress. Similarly, feeding intolerance, fever, hypotonia, neonatal jaundice and abdominal distension were also the most common manifestations of LOS in the work by Li et al.¹⁵15 Li X, Ding X, Shi P, Zhu Y, Huang Y, Li Q, et al. Clinical features and antimicrobial susceptibility profiles of culture-proven neonatal sepsis in a tertiary children’s hospital, 2013 to 2017. Medicine (Baltimore). 2019;98:e14686.

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Table 2
Laboratory parameters of the neonates under study.^a a Unless indicated, data is presented as mean SD. .

As non-specific signs/symptoms make it very challenging to formulate a timely diagnosis, blood culture is still considered the gold standard for diagnosis. The causative organisms vary in different countries.⁴4 Shehab El-Din EM, El-Sokkary MM, Bassiouny MR, Hassan R. Epidemiology of Neonatal Sepsis and Implicated Pathogens: A Study from Egypt. Biomed Res Int. 2015;2015:509484. In the current study, Gram positive organisms accounted for 55% of culture proven sepsis which is in line with the study by Sorsa¹³13 Sorsa A. Epidemiology of Neonatal Sepsis and Associated Factors Implicated: Observational Study at Neonatal Intensive Care Unit of Arsi University Teaching and Referral Hospital, South East Ethiopia. Ethiop J Health Sci. 2019;29:333-42. in which nearly 60% of LOS was caused by Gram + ve bacteria. Our results demonstrate that MRSA was the commonest isolate followed by Klebsiella and CoNS. Notably, a previous report showed that Staphylococci accounted for 59.4% of isolates in LOS followed by Klebsiella (17.5%).¹⁶16 Al-Matary A, Humariya H, AlSarheed AS, Ouda W, AlShahrani DA, Wani TA, et al. Characteristics of neonatal Sepsis at a tertiary care hospital in Saudi Arabia. J Infect Public Health. 2019;12:666-72. On the contrary, other investigators found that CoNS was the most common pathogen in LOS.¹⁴14 Hammoud MS, Al-Taiar A, Al-Abdi SY, Bozaid H, Khan A, AlMuhairi LM, et al. Late-onset neonatal sepsis in Arab states in the Gulf region: two-year prospective study. Int J Infect Dis. 2017;55:125-30. A previous Egyptian study in the same hospital reported that gram-ve pathogens comprised 74 % of isolates in LOS, and that 41.9% of cases were caused by Klebsiella and only 6% were caused by MRSA.¹⁷17 Mohsen L, Ramy N, Saied D, Akmal D, Salama N, Abdel Haleim MM, et al. Emerging antimicrobial resistance in early and late-onset neonatal sepsis. Antimicrob Resist Infect Control. 2017;6:63. However, their study enrolled neonates of various gestational ages, which might account for the difference between their results and ours. It is of note that the distribution pattern of causative pathogens varies across regions and may even change over time within the same hospital.¹⁸18 Hasibuan BS. Comparison of microbial pattern in early and late onset neonatal sepsis in referral center Haji Adam Malik hospital Medan Indonesia 2018. IOP Conf. Ser.: Earth Environ. Sci. 125-012053.

As the early detection of neonates susceptible to have sepsis may augment the therapeutic range and lead to better outcomes, different hematologic parameters and acute phase reactants have been previously explored to determine their utility for early recognition of sepsis.¹⁹19 Celik IH, Demirel FG, Uras N, Oguz SS, Erdeve O, Biyikli Z, et al. What are the cut-off levels for IL-6 and CRP in neonatal sepsis? J Clin Lab Anal. 2010;24:407-12.

Saliva is a potential non-invasive alternative to assess microbial, immunologic, and molecular biomarkers²⁰20 Yoshizawa JM, Schafer CA, Schafer JJ, Farrell JJ, Paster BJ, Wong DT. Salivary biomarkers: toward future clinical and diagnostic utilities. Clin Microbiol Rev. 2013;26:781-91. with previous reports demonstrating its potential use as a marker of systemic inflammation including LOS,⁷7 Omran A, Maaroof A, Saleh MH, Abdelwahab A. Salivary C-reactive protein, mean platelet volume and neutrophil lymphocyte ratio as diagnostic markers for neonatal sepsis. J Pediatr (Rio J). 2018;94:82-7.,⁸8 Iyengar A, Paulus JK, Gerlanc DJ, Maron JL. Detection and potential utility of C-reactive protein in saliva of neonates. Front Pediatr. 2014;2:131.,¹²12 Omran A, Ali M, Saleh MH, Zekry O. Salivary C-reactive protein and mean platelet volume in diagnosis of late-onset neonatal pneumonia. Clin Respir J. 2018;12:1644-50. we aimed to investigate the role of salivary CRP as a diagnostic marker in septic neonates. We found no significant difference in salivary CRP levels between the septic and control groups (p = 0.39). As for serum hs-CRP, in the present work, we found significant difference in its levels between the sepsis groups and the control group (p < 0.001). The sensitivity and specificity of serum CRP cut-off level of 7.2 mg/L in diagnosis of LOS were 91 and 100 %, respectively while it had a PPV of 100 % and NPV of 85.7 %. Interestingly, the role of serum CRP in diagnosis of late-onset infection is debatable. Earlier studies demonstrate the usefulness of serum CRP to diagnose LOS.²¹21 Kumar R, Musoke R, Macharia WM, Revathi G. Validation of creactive protein in the early diagnosis of neonatal sepsis in a tertiary care hospital in Kenya. East Afr Med J. 2010;87:255-61.,²²22 Loni R, Sengupta A, Jaganathan G, Singh PK. The evaluation of C-reactive protein as a screening tool for neonatal sepsis. Int J Contemp Pediatr. 2016;3:1329-33. On the contrary, Brown et al.²³23 Brown JV, Meader N, Cleminson J, McGuire W. C-reactive protein for diagnosing late-onset infection in newborn infants. Cochrane Database Syst Rev. 2019;1:CD012126. suggested that serum CRP may be insufficiently accurate to aid early diagnosis of LOS or select infants to undergo further investigations or antimicrobial therapy treatment.

In agreement with previous studies, salivary CRP levels in the present work didn’t correlate with serum CRP measurements.⁹9 Dillon MC, Opris DC, Kopanczyk R, Lickliter J, Cornwell HN, Bridges EG, et al. Detection of homocysteine and C-reactive protein in the saliva of healthy adults: comparison with blood levels. Biomark Insights. 2010;5:57-61.,²⁴24 Gustafsson A, Ajeti V, Ljunggren L. Detection of suPaR in the saliva of healthy young adults: comparison with plasma levels. Biomark Insights. 2011;6:119-25. Remarkably, Pay and Shaw¹⁰10 Pay JB, Shaw AM. Towards salivary C-reactive protein as a viable biomarker of systemic inflammation. Clin Biochem. 2019;68:1-8. recently demonstrated that currently salivary CRP poorly reflects systemic inflammation and does not consistently and strongly correlate with serum CRP. It is of note that Iyengar et al.⁸8 Iyengar A, Paulus JK, Gerlanc DJ, Maron JL. Detection and potential utility of C-reactive protein in saliva of neonates. Front Pediatr. 2014;2:131. suggested that salivary CRP could predict abnormal serum CRP thresholds; nevertheless, their study enrolled all neonates with gestational ages 23-42 weeks who required serial CRP levels as part of their routine care in the NICU. In disagreement with our findings, a study in 2018⁷ demonstrated significant differences in salivary CRP between full-term neonates with sepsis and controls. Another study proposed salivary CRP as a diagnostic marker of lateonset neonatal pneumonia.¹²12 Omran A, Ali M, Saleh MH, Zekry O. Salivary C-reactive protein and mean platelet volume in diagnosis of late-onset neonatal pneumonia. Clin Respir J. 2018;12:1644-50. The discrepancy between our results and the aforementioned studies may be explained as suggested by Pay and Shaw,¹⁰10 Pay JB, Shaw AM. Towards salivary C-reactive protein as a viable biomarker of systemic inflammation. Clin Biochem. 2019;68:1-8. by changes in the CRP concentration caused by the influence of the oral environment including localized inflammation in the mouth, as well as lack of a standardized method for collecting a consistent salivary sample given the patient-dependent salivary flow rates.

Our results reveal that serum CRP exhibited the highest overall diagnostic accuracy of 94.4% compared to the recorded hematological parameters which had high specificities but low sensitivities except for MPV which had 85% sensitivity but 50% specificity at a cutoff of 9.9 fl. Interestingly, El-Mashad et al.²⁵25 El-Mashad GM, El-Sayed HM, Rizk MS, El-Hefnawy SM, El-Zayat TW. Mean platelet volume and serum uric acid in neonatal sepsis. Menoufia Med J. 2017;30:581-7. proposed a lower diagnostic cut-off value of 7.9 fl, while another study reported a higher cutoff of 10.8 fl.²⁶26 Mittal A, Arya S, Charan LS, Saluja S, Chellani H. Evaluation of platelet indices as additional diagnostic tool for neonatal sepsis. Astrocyte. 2018;4:205-9. On the contrary, other investigators found no significant difference as regards MPV between their study groups.²⁷27 Aksoy HT, Eras Z, Guzoglu N, Canpolat FE, Dilmen U. Mean platelet volume is not associated with bacterial sepsis in newborns. Int J Infect Dis. 2013;17:e1263. These variations might be explained by the different gestational ages of recruited neonates and the timing of onset of sepsis.

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Table 3
Validity and predictive outcomes of various laboratory parameters to differentiate between septic and control groups.

In conclusion, our study demonstrated that salivary CRP levels were not significantly different between the 3 study groups nor did they predict abnormal serum CRP thresholds in newborns with sepsis. Serum CRP could accurately discriminate between septic and aseptic full-term neonates with LOS at a cutoff value of 7.2 mg/mL. Further studies that include a larger number of neonates with different gestational ages and weights are warranted to confirm our findings.

References

¹
Freitas FT, Araujo AF, Melo MI, Romero GA. Late-onset sepsis and mortality among neonates in a Brazilian Intensive Care Unit: a cohort study and survival analysis. Epidemiol Infect. 2019;147:e208.
²
Akbarian-Rad Z, Riahi SM, Abdollahi A, Sabbagh P, Ebrahimpour S, Javanian M, et al. Neonatal sepsis in Iran: A systematic review and meta-analysis on national prevalence and causative pathogens. PLoS ONE. 2020;15:e0227570.
³
Tzialla C, Borghesi A, Serra G, Stronati M, Corsello G. Antimicrobial therapy in neonatal intensive care unit. Ital J Pediatr. 2015;41:27.
⁴
Shehab El-Din EM, El-Sokkary MM, Bassiouny MR, Hassan R. Epidemiology of Neonatal Sepsis and Implicated Pathogens: A Study from Egypt. Biomed Res Int. 2015;2015:509484.
⁵
Prathyusha, Shreekrishna GN, Bhat S, Sahana P. Mean platelet volume (MPV) as a diagnostic marker in neonatal sepsis. Int J Contemp Pediatr. 2019;6:1036-40.
⁶
Tosson AM, Glaser K, Weinhage T, Foell D, Aboualam MS, Edris AA, et al. Evaluation of the S100 protein A12 as a biomarker of neonatal sepsis. J Matern Fetal Neonatal Med. 2020;33:2768-74.
⁷
Omran A, Maaroof A, Saleh MH, Abdelwahab A. Salivary C-reactive protein, mean platelet volume and neutrophil lymphocyte ratio as diagnostic markers for neonatal sepsis. J Pediatr (Rio J). 2018;94:82-7.
⁸
Iyengar A, Paulus JK, Gerlanc DJ, Maron JL. Detection and potential utility of C-reactive protein in saliva of neonates. Front Pediatr. 2014;2:131.
⁹
Dillon MC, Opris DC, Kopanczyk R, Lickliter J, Cornwell HN, Bridges EG, et al. Detection of homocysteine and C-reactive protein in the saliva of healthy adults: comparison with blood levels. Biomark Insights. 2010;5:57-61.
¹⁰
Pay JB, Shaw AM. Towards salivary C-reactive protein as a viable biomarker of systemic inflammation. Clin Biochem. 2019;68:1-8.
¹¹
Dietz JA, Johnson KL, Wick HC, Bianchi DW, Maron JL. Optimal techniques for mRNA extraction from neonatal salivary supernatant. Neonatology. 2012;101:55-60.
¹²
Omran A, Ali M, Saleh MH, Zekry O. Salivary C-reactive protein and mean platelet volume in diagnosis of late-onset neonatal pneumonia. Clin Respir J. 2018;12:1644-50.
¹³
Sorsa A. Epidemiology of Neonatal Sepsis and Associated Factors Implicated: Observational Study at Neonatal Intensive Care Unit of Arsi University Teaching and Referral Hospital, South East Ethiopia. Ethiop J Health Sci. 2019;29:333-42.
¹⁴
Hammoud MS, Al-Taiar A, Al-Abdi SY, Bozaid H, Khan A, AlMuhairi LM, et al. Late-onset neonatal sepsis in Arab states in the Gulf region: two-year prospective study. Int J Infect Dis. 2017;55:125-30.
¹⁵
Li X, Ding X, Shi P, Zhu Y, Huang Y, Li Q, et al. Clinical features and antimicrobial susceptibility profiles of culture-proven neonatal sepsis in a tertiary children’s hospital, 2013 to 2017. Medicine (Baltimore). 2019;98:e14686.
¹⁶
Al-Matary A, Humariya H, AlSarheed AS, Ouda W, AlShahrani DA, Wani TA, et al. Characteristics of neonatal Sepsis at a tertiary care hospital in Saudi Arabia. J Infect Public Health. 2019;12:666-72.
¹⁷
Mohsen L, Ramy N, Saied D, Akmal D, Salama N, Abdel Haleim MM, et al. Emerging antimicrobial resistance in early and late-onset neonatal sepsis. Antimicrob Resist Infect Control. 2017;6:63.
¹⁸
Hasibuan BS. Comparison of microbial pattern in early and late onset neonatal sepsis in referral center Haji Adam Malik hospital Medan Indonesia 2018. IOP Conf. Ser.: Earth Environ. Sci. 125-012053.
¹⁹
Celik IH, Demirel FG, Uras N, Oguz SS, Erdeve O, Biyikli Z, et al. What are the cut-off levels for IL-6 and CRP in neonatal sepsis? J Clin Lab Anal. 2010;24:407-12.
²⁰
Yoshizawa JM, Schafer CA, Schafer JJ, Farrell JJ, Paster BJ, Wong DT. Salivary biomarkers: toward future clinical and diagnostic utilities. Clin Microbiol Rev. 2013;26:781-91.
²¹
Kumar R, Musoke R, Macharia WM, Revathi G. Validation of creactive protein in the early diagnosis of neonatal sepsis in a tertiary care hospital in Kenya. East Afr Med J. 2010;87:255-61.
²²
Loni R, Sengupta A, Jaganathan G, Singh PK. The evaluation of C-reactive protein as a screening tool for neonatal sepsis. Int J Contemp Pediatr. 2016;3:1329-33.
²³
Brown JV, Meader N, Cleminson J, McGuire W. C-reactive protein for diagnosing late-onset infection in newborn infants. Cochrane Database Syst Rev. 2019;1:CD012126.
²⁴
Gustafsson A, Ajeti V, Ljunggren L. Detection of suPaR in the saliva of healthy young adults: comparison with plasma levels. Biomark Insights. 2011;6:119-25.
²⁵
El-Mashad GM, El-Sayed HM, Rizk MS, El-Hefnawy SM, El-Zayat TW. Mean platelet volume and serum uric acid in neonatal sepsis. Menoufia Med J. 2017;30:581-7.
²⁶
Mittal A, Arya S, Charan LS, Saluja S, Chellani H. Evaluation of platelet indices as additional diagnostic tool for neonatal sepsis. Astrocyte. 2018;4:205-9.
²⁷
Aksoy HT, Eras Z, Guzoglu N, Canpolat FE, Dilmen U. Mean platelet volume is not associated with bacterial sepsis in newborns. Int J Infect Dis. 2013;17:e1263.

Publication Dates

Publication in this collection
06 Dec 2021
Date of issue
2021

History

Received
19 Oct 2020
Accepted
04 Jan 2021
Published
11 Feb 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ¹
Freitas FT, Araujo AF, Melo MI, Romero GA. Late-onset sepsis and mortality among neonates in a Brazilian Intensive Care Unit: a cohort study and survival analysis. Epidemiol Infect. 2019;147:e208.

[2] ²
Akbarian-Rad Z, Riahi SM, Abdollahi A, Sabbagh P, Ebrahimpour S, Javanian M, et al. Neonatal sepsis in Iran: A systematic review and meta-analysis on national prevalence and causative pathogens. PLoS ONE. 2020;15:e0227570.

[3] ³
Tzialla C, Borghesi A, Serra G, Stronati M, Corsello G. Antimicrobial therapy in neonatal intensive care unit. Ital J Pediatr. 2015;41:27.

[4] ⁴
Shehab El-Din EM, El-Sokkary MM, Bassiouny MR, Hassan R. Epidemiology of Neonatal Sepsis and Implicated Pathogens: A Study from Egypt. Biomed Res Int. 2015;2015:509484.

[5] ⁵
Prathyusha, Shreekrishna GN, Bhat S, Sahana P. Mean platelet volume (MPV) as a diagnostic marker in neonatal sepsis. Int J Contemp Pediatr. 2019;6:1036-40.

[6] ⁶
Tosson AM, Glaser K, Weinhage T, Foell D, Aboualam MS, Edris AA, et al. Evaluation of the S100 protein A12 as a biomarker of neonatal sepsis. J Matern Fetal Neonatal Med. 2020;33:2768-74.

[7] ⁷
Omran A, Maaroof A, Saleh MH, Abdelwahab A. Salivary C-reactive protein, mean platelet volume and neutrophil lymphocyte ratio as diagnostic markers for neonatal sepsis. J Pediatr (Rio J). 2018;94:82-7.

[8] ⁸
Iyengar A, Paulus JK, Gerlanc DJ, Maron JL. Detection and potential utility of C-reactive protein in saliva of neonates. Front Pediatr. 2014;2:131.

[9] ⁹
Dillon MC, Opris DC, Kopanczyk R, Lickliter J, Cornwell HN, Bridges EG, et al. Detection of homocysteine and C-reactive protein in the saliva of healthy adults: comparison with blood levels. Biomark Insights. 2010;5:57-61.

[10] ¹⁰
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	Culture proven LOS(n = 30)	Clinical LOS(n = 30)	Control(n = 30)	p value^b b p value ≤ 0.05 is considered significant.
Female/Male	6/24	10/20	10/20	0.4
Admission weight (kg)	2.89 ± 0.52	3.05 ± 0.56	2.95 ± 0.58	0.21
Postnatal age (days)	12.68 ± 6.07	12.65 ± 6.48	10.27 ± 5.58	0.21

	Culture proven LOS(n = 30)	Clinical LOS (n = 30)	Controls (n = 30)	p value^b b p value 0.05 is considered significant.
*CRP*
Median serum hs-CRP (mg/L)	47.1 (IQR = 0.9-152)	31.9(IQR = 0.9-154.2)	1.65 (IQR = 0.9-6.9)	< 0.001^c c Significant p value between the 3 study groups as well as between culture proven group and controls. ,^d d Significant p value between the 3 study groups as well as between clinically septic and control groups.
Median salivary CRP(mg/L)	1.17 (IQR = 0.02-12.1)	0.42 (IQR = 0.1-11.3)	0.23(IQR = 0.01-3.8)	0.39
*Complete blood picture parameters*
TLC (x10 ³ /cm ³ )	14.29 ± 6.4	13.67 ± 4.35	14.35 ± 5.36	0.87
PMN (x10 ³ /mm ³ )	7.14 ± 3.69	6.96 ± 3.51	5.95 ± 2.20	0.31
Immature PMN (%)	12.26 ± 7.40	10.68 ± 7.20	2.6 ± 2.73	< 0.001^c d Significant p value between the 3 study groups as well as between clinically septic and control groups. ,^d d Significant p value between the 3 study groups as well as between clinically septic and control groups.
I:T	0.22 ± 0.10	0.20 ± 0.12	0.06 ± 0.06	< 0.001^c d Significant p value between the 3 study groups as well as between clinically septic and control groups. ,^d d Significant p value between the 3 study groups as well as between clinically septic and control groups.
I:M	0.32 ± 0.20	0.29 ± 0.23	0.06 ± 0.09	< 0.001^c d Significant p value between the 3 study groups as well as between clinically septic and control groups. ,^d d Significant p value between the 3 study groups as well as between clinically septic and control groups.
Platelets (x10 ³ / μl)	207.5 ± 144.2	190.2 ± 125.4	228.83 ± 90.9	0.47
MPV (fl)	10.8 ± 0.89	10.6 ± 0.90	10.02 ± 1.56	0.03^c d Significant p value between the 3 study groups as well as between clinically septic and control groups. ,^d d Significant p value between the 3 study groups as well as between clinically septic and control groups.

	Area Under the Curve	p value^a a p value ≤0.05 is considered significant.	95% Confidence Interval		Cut off	Sensitivity %	Specificity %	PPV %	NPV %	Accuracy%
Hs-CRP (mg/L)	0.953	< 0.001	0.906	1	7.15	91%	100%	100%	85.71%	94.44%
Immature PMN (%)	0.89	< 0.001	0.83	0.96	8.5	66.7%	96.7 %	97.56 %	59.18%	76.67 %
I:M ratio	0.896	< 0.001	0.83	0.97	0.21	63.3%	96.7 %	97.44 %	56.86%	74.44 %
I:T ratio	0.898	< 0.001	0.83	0.97	0.19	60%	97.6 %	97.3 %	54.72%	72.22 %
MPV (fl)	0.688	0.004	0.558	0.817	9.85	85%	50 %	77.27 %	62.5%	73.33%

Brasil

Brasil

Evaluation of serum and salivary C-reactive protein for diagnosis of late-onset neonatal sepsis: A single center cross-sectional study

Abstract

Objective:

Methods:

Results:

Conclusion:

Introduction

Methods

Study population

Laboratory investigations

Statistical methods

Results

Demographic features and clinical characteristics

Laboratory parameters

Discussion

References

Publication Dates

History