Basima.doc J Bagh College Dentistry Vol. 26(4), December 2014 Quantitative detection Oral and Maxillo-facial Surgery and Periodontics 133 Quantitative detection and correlation of Epstein - Barr Virus in plasma with gingivitis and severity of chronic periodontitis by using real-time polymerase chain reaction technique Nada K. Imran, B.D.S. (1) Basima Gh. Ali, B.D.S, M.Sc. (2) Duraid Q. Jassim, M.B.Ch.B., F.I.B.M.S. (3) ABSTRACT Background: This study aimed to detect EBV quantitatively in plasma using real-time polymerase chain reaction technique in chronic periodontitis and gingivitis patients and to compare the finding with control subjects (healthy periodontium) and to investigate the relationship between the presence of EBV & the severity of periodontal diseases using the clinical periodontal parameters (PLI ,GI , BOP ,PPD and CAL) between each of (chronic periodontitis and gingivitis) patients and compare with control (healthy periodontium) subjects . Materials and methods: The study sample consisted of (101) individual of both genders, (61) chronic periodontitis patients which were subdivided into (mild, moderate & severe) depending on the scores of clinical attachment level, (20) gingivitis patients and (20) control subjects (healthy periodontium) with age ranged from (30-50) years. All the groups were without any history of systemic diseases. Clinical periodontal parameters used in this study were (PLI ,GI , BOP ,PPD and CAL) .Blood samples were collected from all individuals and examined by Real-Time PCR technique for the detection of EBV. Results: The result of comparison for the occurrence of EBV among study and control groups according to sequential responding of EBV appears to be highly significant at negative level of EBV, significant in (100 - 500 copy/105 cells) level and the results of leftover levels appear non significant difference. The result of correlation between the actual occurrence of EBV and PPD scores in severe chronic periodontitis subgroup appears to be significant at PPD score (1) and non significant at scores (2&3). The correlations between EBV and PPD scores in moderate and mild chronic periodontitis subgroups appear to be non significant with all scores. The results of correlation between EBV and CAL parameter appear to be non significant among all scores of chronic periodontitis subgroup. Concerning plaque index, the correlation appears to be significant in mild chronic periodonttis subgroup and highly significant in control group. In case of gingival index, the correlation appears to be significant in severe chronic periodontitis subgroup and control group .The result of correlation with (B.O.P. score 1) appears to be highly significant in severe subgroup of chronic periodontitis group and significant in gingivitis group, while in case of (B.O.P. score 0), the correlation appears to be significant only in severe chronic periodonttis subgroup. Conclusions: The present findings revealed that there may be an association between EBV infection and the severity of periodontal diseases and thus coinfection with EBV may play a role in increase destruction of periodontal tissues. Keyword: Chronic periodontitis, EBV, Real-Time PCR. (J Bagh Coll Dentistry 2014; 26(4):133-140). INTRODUCTION Periodontal diseases (PD) are group of inflammatory diseases caused by pathogenic microflora organized in biofilms surrounding the teeth (1). The causes of infection may include bacterial plaque and herpes virus (2,3) . There are two major types of periodontal disease: gingivitis and periodontitis. Gingivitis involves a limited inflammation of the unattached gingiva and is a relatively common and reversible condition. In contrast, periodontitis is characterized by general inflammation of the periodontal tissues, which leads to the apical migration of the junctional epithelium along the root surface and progressive destruction of the periodontal ligament and the alveolar bone (4). (1) Master Student, Department of Periodontics, College of Dentistry, Baghdad University. (2) Assistant Professor, Department of Periodontics, College of Dentistry, Baghdad University. (3) Assistant Professor, Baghdad Medical City, Ministry of Health. Bacterial infection alone may not explain the conversion of gingivitis to periodontitis(5) ,rapid tissue destruction around teeth exhibiting little plaque, the propensity of periodontitis to proceed with periods of exacerbation, remission and the tendency of periodontal tissue breakdown to advance in a localized and bilaterally symmetrical pattern (6) . However, it has been difficult to unravel the precise role of various putative pathogens and host responses in the pathogenesis of periodontitis. Recent finding have showed herpes viruses especially Epstein-Barr virus (EBV) can infect or alter structural cells and host defense cells of the periodontium (7). It’s obvious that others factors beyond biofilm are important in the pathogenesis of periodontitis like tobacco smoking and genetically determined variations in inflammatory response patterns and recently, it was suggested that certain viruses might also influence the development and severity of periodontal diseases, though the cause of gingivitis and periodontitis is J Bagh College Dentistry Vol. 26(4), December 2014 Quantitative detection Oral and Maxillo-facial Surgery and Periodontics 134 credited to bacteria colonizing tooth surfaces and initiating the major mechanisms of periodontal destruction (8). Viruses can also interfere on immune responses though immune modulators encoded within viral genomes, which include proteins that regulate antigen presentation, function as cytokines or cytokine antagonists, inhibit apoptosis and interrupt the complement cascade (9). Viral infections may facilitate the destruction of periodontal tissue by lytic activity against periodontal cells, immune mediated tissue destruction and immune suppression, which increase the susceptibility of the host to bacterial attacks (10,11) .Thus, a situation of viral-bacterial interaction could occur in the oral cavity without a denial of the argument for a major etiological role of bacteria in human periodontal disease. Human Cytomegalovirus (HCMV) and EBV-1 assume a particularly close relationship with human periodontitis while herpes simplex virus (HSV) , human herpesvirus-6 (HHV-6) and Epstein-Barr virus type-2 seem to exhibit little or no association with most types of periodontitis disease (12) . Various systems for the detection of oral pathogens have been reported, but most are qualitative (13,14). Because periodontal pathogens exist not only in infected pockets but also in the healthy sulcus, qualitative detection is not suitable for the diagnosis of periodontitis. For this purpose, the present study used a quantitative detection system that uses real-time polymerase chain reaction (real-time PCR) methodology. MATERIALS AND METHODS Human Sample The sample in this study consisted of one- hundred & one subjects with an age ranged from (30-50) years, males (73) & females (28), sample collection was started at 16th February 2013 till 20 March 2013. Patients participating in the present study with chronic periodontitis (no=61), which were subdivided according to the severity of disease into (mild, moderate & severe) depending on the scores of clinical attachment level, gingivitis patients (No.=20) with limited inflammation of the gingiva , no probing pocket depth & no clinical attachment loss and control subjects (healthy periodontium) (No.=20) where there was no signs of periodontal disease with clinically healthy gingiva, no pockets, no bleeding on probing and no evidence of bone loss. The sample collected from patients recruited from the Clinic of the Department of Periodontics/ College of Dentistry/ Baghdad University. Clinical examination Periodontal examination consisted of plaque index (PLI) (15) ,gingival index (GI) (16), bleeding on probing (BOP) (17), probing pocket depth (PPD) and finally clinical attachment level (CAL) (18) measured at 4 sites for all teeth except 3rd molar on (mesial, vestibular, distal, lingual) using a calibrated periodontal probe (Michigan O probe). Patients with chronic periodontitis had periodontal pockets equal or greater than 3mm with clinical attachment loss (19). All subjects participated in this study without any systemic diseases, had not received previous periodontal treatment and had not used antibiotics in the past 3 months. Patients were excluded if pregnant, smokers, menapaused women, female under contraceptive pills and patients with history of herpetic infection (self-reported) during the last six months. In the present study the laboratory results will be divided into 5 levels according to the quantity of EBV with cutoff point will be (100-500 copy/105 cell) level, these levels are: 1. Negative level (score-1). 2. % <100 copy/105 cells level (score-2). 3. 100-500 copy/105 cells level (cutoff point) (score-3). 4. 600-1000 copy/105 cells level (score-4). 5. % >1000 copy/105 cells level (score-5). Collection of Blood Sample and Plasma Preparation The blood was collected from all participants between (9 am-12 pm), the blood samples were taking from their arms from cubital Fossa (cubital vien) , 5cc of venous blood taken from patients & control healthy individual and put it in [Ethylen Diamine Tetra Acetic acid (EDTA)] tubes as anticoagulant tubes used to preserve collected blood samples and then preserved in a cool box containing ice packs until transferring the samples to the laboratory. Plasma separated from blood samples using centrifuge at speed (1600 R/min) for 20 min according to DNA extraction kit manuals, then plasma samples preserved immediately into other plain tubes and stored in freeze at (- 15 Cº ) until they were assayed. This was done within 4 hours after sample collection. DNA Extraction The kit used is DNA column extraction kit {Sacace-ITALY (Lot number 1306/001)}, for extraction of DNA using column method and J Bagh College Dentistry Vol. 26(4), December 2014 Quantitative detection Oral and Maxillo-facial Surgery and Periodontics 135 samples preserved in freeze thawed in room temperature for extraction. Eppendorf tubes used in first step of extraction prepared & numbered according to the samples and then Ribovirus columns used. After a long series of adding washing solutions, centrifuge and heating, we can get the pure DNA captured at the bottom of each eppendorf tube. Real-Time PCR amplification The kit used is EBV- Real time PCR kit from {Sacace biotechnology (ITALY) (Lot number 23K13K705)}, which contains (Polymerase, mastermix, controls for quantitation, Internal Control). Smart cycler PCR tubes used that numbered according to the samples, then 12.5 µl of extracted DNA and PCR mix (which contain Taq. Polymerase enzyme ) added to each tube and each tube closed well & centrifuged in minispin centrifuge at (8000 R/min) for 20 seconds ,then tubes put in Real-Time PCR for amplification , we notice that Internal control DNA appears in FAM fluorescent signal on PCR ,while DNA samples appear in CY3 fluorescent signal channel on PCR. Quantitation based on formulation of the kit and the results appear as curves of different colors on the monitor of real-time PCR system and the quantitation depends on standard curve. RESULTS The goodness-of-fit test ,which tests the mean value of the studied parameters {PLI & GI, BOP (Score 1) and the Sequential Responding}, which was used to determine the normal and non normal distribution of the data , this test reflects that the results of (mean and standard deviation) for the study group was higher than that of control group as seen in table (1). The descriptive statistics of the clinical periodontal parameters reflect that the results of the study group were higher than that of the control group. According to sequential responding parameter, we notice that the mean values of positive records increase with increase severity of periodontal diseases & EBV levels at different groups and subgroups recorded, the higher mean was at severe subgroup of chronic periodontitis (3.77), while the least appears at control group (1.55) as seen in table (2). By using (LSD test ) ,this test revealed highly significant differences between severe subgroup & other groups and subgroups of the study according to sequential responding and significant difference between moderate subgroup of chronic periodontitis group & control group, while the leftover revealed non significant differences as seen in table (3). The result of comparison between the groups of the study & the levels of EBV appears to be highly significant at the negative level of EBV, non significant positive difference at the (%<100 copies/105 cells), significant positive difference at (100-500 copies/105 cells), non significant positive difference at the (600-1000 copies/105 cells) & non significant positive difference at the (% >1000 copies/105 cells). The result of comparison between the 3 groups of the study and EBV at the cutoff point (100-500 copies/105 cells) level appears to be statistically significant as seen in table (4). Spearman's Correlation Coefficient. Test, that is used for testing the correlation between different periodontitis subgroups & the clinical periodontal parameters {plaque index, gingival index & BOP (score 0& 1)} according to sequential responding of EBV. In case of plaque index, a negative significant correlation appears in mild chronic periodontitis subgroup, while it appears non significant in case of (moderate and severe) chronic periodontitis subgroups. A negative significant correlation appears in case of gingival index in severe chronic periodontitis subgroup, while it is non-significant in (mild and moderate) chronic periodontitis subgroups. In case of BOP score 1, the correlation appears to be highly significant and negative in severe subgroup of chronic periodontitis group and non significant in (mild and moderate) subgroups. The correlation of BOP score 0 appears to be significant & positive in severe chronic periodontitis subgroup , while it appears non significant in case of (mild and moderate) subgroups of chronic periodontitis group as seen in table (5) . The correlation of EBV & { PLI, GI, and BOP (score 0&1)} in gingivitis group, which appears non significant, while the correlation of EBV & BOP score (1) appears to be significant and negative as seen in table (6). The correlation of EBV & clinical periodontal parameters{ PLI, GI, and BOP (score 0&1)} in control group appears to be highly significant and negative (strong correlation) with plaque index, negative significant correlation with gingival index , while it appears non significant in case of BOP score (0 &1) as seen in table (7). The correlation of EBV & PPD scores in severe periodontitis subgroup appears to be significant and negative at PPD score (1), while it appears a non significant correlation at PPD score (2&3). The correlation of EBV & all CAL scores J Bagh College Dentistry Vol. 26(4), December 2014 Quantitative detection Oral and Maxillo-facial Surgery and Periodontics 136 appears to be non-significant and negative as seen in table (8). The correlation of EBV and (PPD & CAL) scores in moderate periodontitis subgroup appears to be non significant with all scores of (PPD & CAL) parameters as seen in table (9). The correlation of EBV and (PPD & CAL) scores in mild periodontitis subgroup appears to be non significant with all scores of (PPD&CAL) parameters as seen in table (10). Table 1: Goodness of Fit test of normal distribution function for the studied parameters (PLI, GI, BOP score 0&1 and sequential responding) in study and control groups Groups Statistical Information P la qu e In de x G in gi va l In de x B .O .P Sc or e 1 Se qu en ti al R es po nd in g Study No. Parameters 81 Mean 1.506 1.452 61.69 2.280 ± SD 0.538 0.452 34.23 1.280 Control No. Parameters 20 Mean 0.110 0.147 4.800 1.550 ± SD 0.057 0.164 2.840 0.690 Table 2: Summary Statistics of (Sequential Responding) Parameter at the different groups and subgroups Parameter Groups and subgroups No. Mean ±Std. Dev. Std. Error Sequential Responding Chronic periodontitis - Severe 13 3.77 0.73 0.2 Chronic periodontitis - Moderate 23 2.26 1.01 0.21 Chronic periodontitis - Mild 25 2.00 1.22 0.24 Gingivitis 20 1.70 1.22 0.27 Control 20 1.55 0.69 0.15 Table 3: Multiple Comparisons (LSD) between all pairs of different groups and subgroups according to sequential responding parameter: Dependent Variable Study Groups & subgroups Mean Difference Sig. C.S. Sequential Responding Chronic periodontitis – Severe Chronic periodontitis –Mod. 1.51 0.001** HS Chronic periodontitis - Mild 1.77 0.001** HS Gingivitis 2.07 0.001** HS Control 2.22 0.001** HS Chronic periodontitis - Moderate Chronic periodontitis - Mild 0.26 0.383 NS Gingivitis 0.56 0.078 NS Control 0.71 0.026* S Chronic periodontitis - Mild Gingivitis 0.30 0.334 NS Control 0.45 0.149 NS Gingivitis Control 0.15 0.646 NS (**) HS: Highly Sig. at P< 0.01; (*) S: Sig. at P<0.05; NS: Non Sig. at P>0.05 J Bagh College Dentistry Vol. 26(4), December 2014 Quantitative detection Oral and Maxillo-facial Surgery and Periodontics 137 Table 4: Distribution of the absent & present responding at each group according to different levels of EBV with Contingency Coefficients Levels Resp. (+& -) No. & Percents Groups C.S. P-value C hr on ic P er io do nt it is G in gi vi ti s C on tr ol Negative ( score -1) 0 No. 45 7 9 C.C.=0.32 5 P=0.003 (**) HS %Negative 73.8% 11.5% 14.8% %Groups 73.8% 35% 45% 1 No. 16 13 11 %Negative 40% 32.5% 27.5% %Groups 26.2% 65% 55% <100 copy/105 cells ( score -2) 0 No. 43 16 13 C.C.=0.10 6 P=0.564 NS %< 100 copy/10^5 cells 59.7% 22.2% 18.1% %Groups 70.5% 80% 65% 1 No. 18 4 7 %< 100 copy/10^5 cells 62.1% 13.8% 24.1% %Groups 29.5% 20.0% 35.0% 100 - 500 copy/105 cells ( score - 3) 0 No. 47 20 18 C.C.=0.24 7 P=0.037 (*) S %100 - 500 copy/10^5 cells 55.30% 23.50% 21.20% %Groups 77.00% 100.00 % 90.00% 1 No. 14 0 2 %100 - 500 copy/10^5 cells 87.50% 0.0% 12.50% %Groups 23.00% 0.0% 10.00% 600 -1000 copy/105 cells ( score - 4) 0 No. 53 18 20 C.C.=0.16 7 P=0.234 NS %500 -1000 copy/10^5 cells 58.20 % 19.80% 22.00% %Groups 86.90% 90.00% 100.00 % 1 No. 8 2 0 %500 -1000 copy/10^5 cells 80.00 % 20.00% 0.0% %Groups 13.10% 10.00% 0.0% >1000 copy/105 cells ( score - 5) 0 No. 56 19 20 C.C.=0.13 4 P=0.306 NS %> 1000 copy/10^5 cells 58.90% 20.00% 21.10% %Groups 91.80% 95.00% 100.00 % 1 No. 5 1 0 %> 1000 copy/10^5 cells 83.30% 16.70% 0.0% %Groups 8.20% 5.00% 0.0% (**) HS: Highly Sign. at P<0.01; (*) S: Sign. at P<0.05 ; NS: Non Sign. at P>0.05 C.C.: Contingency Coefficient J Bagh College Dentistry Vol. 26(4), December 2014 Quantitative detection Oral and Maxillo-facial Surgery and Periodontics 138 Table 5: Spearman's Correlation Coeff. For testing the correlation between sequential responding of EBV and (PLI, GI, BOP score 0 & BOP score 1) parameters at each chronic periodontitis subgroups: Clinical Parameters Spearman's Corr. Coeff. Chronic Periodontitis - Severe Chronic Periodontitis - Moderate Chronic Periodontitis - Mild Plaque Index Corr. Coeff. -0.217 -0.324 -0.387* P-value 0.477 0.132 0.05 No. 13 23 25 Gingival Index Corr. Coeff. -0.608* -0.256 -0.119 P-value 0.028 0.239 0.572 No. 13 23 25 B.O.P Score 1 Corr. Coeff. -0.822** -0.253 -0.179 P-value 0.001 0.244 0.392 No. 13 23 25 B.O.P Score 0 Corr. Coeff. 0.583* 0.26 0.179 P-value 0.036 0.231 0.392 No. 13 23 25 (**) HS: Highly Sign. at P<0.01; (*) S: Sign. at P<0.05 ; NS: Non Sign. at P>0.05 Table 6: Correlation Coefficients with their testing of null hypotheses between the actual of virus readings and the studied parameters ( PLI, GI, BOP score 0 & BOP score 1) in Gingivitis group Group Corr. and P-value Plaque Index Gingival Index B.O.P Score 1 B.O.P Score 0 Gingivitis Correlation -0.333 -0.293 -0.383 0.373 P-value 0.076 0.105 0.048 0.053 C.S. NS NS S NS Table 7: Correlation Coefficients with their testing of null hypotheses between the actual of virus readings and the studied parameters ( PLI, GI, BOP score 0 & BOP score 1) in Control group Group Corr. and P-value Plaque Index Gingival Index B.O.P Score 1 B.O.P Score 0 Control Correlation -0.537 -0.476 -0.274 0.274 P-value 0.007 0.017 0.121 0.121 C.S. HS S NS NS Table 8: Correlation Coefficients between the actual virus readings and the studied parameters (PPD and CAL) scores in chronic periodontitis – Severe subgroup: Group Corr. and P-value PPD Score-1 PPD Score-2 PPD Score-3 CAL Score-1 CAL Score-2 CAL Score-3 Chronic Periodontitis –Severe subgroup Correlation -0.496 -0.175 0.214 -0.362 -0.263 -0.018 P-value 0.043 0.284 0.241 0.112 0.193 0.477 C.S. S NS NS NS NS NS Table 9: Correlation Coefficients between the actual virus readings and the studied parameters in Ch. Periodontitis – Moderate subgroup: Group Corr. and P-value PPD Score-1 PPD Score-2 PPD Score-3 CAL Score-1 CAL Score-2 CAL Score-3 Chronic Periodontitis – Moderate subgroup Correlation -0.048 0.312 -0.105 0.102 0.03 0.303 P-value 0.414 0.074 0.317 0.321 0.445 0.08 C.S. NS NS NS NS NS NS Table 10: Correlation Coefficients between the actual virus readings and the studied parameters in Ch. Periodontitis – Mild subgroup: Group Corr. and P-value PPD Score-1 PPD Score-2 PPD Score-3 CAL Score-1 CAL Score-2 CAL Score-3 Chronic Periodontitis –Mild subgroup Correlation 0.161 -0.150 0.049 0.052 -0.143 0.036 P-value 0.221 0.237 0.408 0.402 0.248 0.432 C.S. NS NS NS NS NS NS J Bagh College Dentistry Vol. 26(4), December 2014 Quantitative detection Oral and Maxillo-facial Surgery and Periodontics 139 DISCUSSION In this study a significant difference appears when comparison was made between 3 groups of the study and the percentage of EBV at the cutoff point of sequential responding parameter. This finding agree with Wu et al (20) , where the higher level of EBV among study group compare to control group represent the role of these pathogens in destructive periodontal lesion where the virus effect on immune response of such patients. The pathogenic mechanisms of herpes viruses cooperate in exacerbating disease and probably for that reason, a periodontal dual infection with (HCMV and EBV) tends to occur in severe types of periodontitis (21) . A non significant negative correlation appears when correlation was made between the quantity of EBV and plaque index in case of {chronic periodontitis (severe & moderate) subgroups and in gingivitis group}, while there is a significant negative correlation in case of chronic periodontitis (mild subgroup) and a highly significant strong negative correlation appears in healthy control group. These findings appear to be disagree with Saygun et al (22) where the difference in the measurements of plaque index in viral detected & undetected sites were statistically significant . When the correlation was made between the presence of EBV and gingival index, it's found that there is a non significant negative correlation in all groups and subgroups except in chronic periodontitis (severe subgroup) and healthy control group which showed a statistical significant negative correlation with the quantity of EBV. These findings are agree with the study done by Charu (23) .The reasons of variation in EBV occurrence among studies may include differing EBV detection technique, dissimilar periodontal disease states studies and true geographic variation in EBV prevalence. A significant negative correlation was found between the presence of EBV and bleeding upon probing for (score 1) in chronic periodontitis- severe subgroup and gingivitis group & a non significant correlation was found in case of BOP score (0) with different groups and subgroups except chronic periodontitis-severe subgroup, which showed a significant strong positive correlation. These findings are disagree with Maryam et al (24) , who found that there were no statistically significant differences in mean of BOP among positive and negative patients for EBV-1, EBV-2 and HCMV ,where a higher mean of BOP among patients who were infected with EBV-1 and HCMV did not reach to the level of statistical significance. The coinfection with EBV revealed bleeding upon probing, a clinical sign of elevated risk for disease progression (21) . The result of correlations between the three scores of periodontal pocket depth of chronic periodontitis subgroups & EBV quantity showed a significant correlation in case of severe chronic periodontitis subgroup at score (1), while there were non significant differences at scores (2&3), also non significant correlations were found in case of (moderate & mild) chronic periodontitis subgroups including all scores. These findings are disagree with Ling (25), who found that the prevalence of virus in chronic periodontitis is very low (4%). These differences between studies could be due to differing in EBV detection technique, dissimilar in estimation of (PPD), but the present finding agrees with Saygun et al and Moghim et al (26,27). Saygun et al observed that periodontal pocket depth was positively correlated with salivary EBV-DNA counts. The results agree with Wu et al (28) who found that a higher percentage of EBV associated with a deeper probing pocket depth. The prevalence of EBV-1 found in PD ≥ 6 mm was statistically greater than that in PPD ≤ 3 mm (24) . A study done by Kubar et al (6) showed that a statistical significance difference was found between EBV subgingival counts and periodontal pocket depth at sample sites (Spearman's correlation), where chronic periodontitis patients revealed more than 10,000 copies of (HCMV or EBV) in subgingival or gingival tissue samples (Chi-square test. 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